Water Treatment, Metal and Mining Chemicals

Kératine hydrolysée
Coco fatty acid ;coconut acid; fatty acids, coco; coconut fatty acid cas no: 61788-47-4
KOKO YAĞI ASIDI
SYNONYM Fats and Glyceridic oils, fish; Fish Oil is the oil obtained from the head, tail and stomach of various species of fish CAS #8016-13-5
KOLLIPHOR TPGS
Kolliphor TPGS Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS): Solution for insolubility Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) – D-alpha tocopheryl polyethylene glycol 1000 succinate (TPGS) – is a water-soluble derivative of vitamin E that can directly enhance the bioavailability of poorly soluble actives. TPGS is commonly used in pharmaceutical and nutraceutical formulations. Key Features of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) Based on natural-source vitamin E from BASF Conforms to USP-NF monograph “Vitamin E Polyethylene Glycol Succinate” Produced according to IPEC-PQG GMP guidelines No chlorinated solvents used Detailed technical and regulatory information available Enhanced delivery of life-saving drugs Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) directly increases the bioavailability and delivery of poorly soluble drugs. TPGS can be used in oral, topical and parenteral dosage forms. It is also used in dietary supplements, cosmetic applications and food. Key benefits for customers Cognis is a leading supplier of natural-source vitamin E and pharma-grade excipients, and has considerable expertise in solubilizers. Using its own vitamin E feedstocks, BASF guarantees consistent quality and a competitive, reliable supply of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS). In accordance with stringent industry requirements, BASF maintains the highest manufacturing standards, with full supporting documentation. TPGS from BASF offer high solubilisation effectiveness. BASF offers a global sales network plus technical and regulatory support. Applications of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS): -Drug solubilizer -Absorption enhancer -Emulsifier -Vehicle for lipid-based drug delivery -Source of natural vitamin E -Antioxidant BASF will transfer the pharmaceutical production of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) (Speziol TPGS Pharma, vitamin E polyethylene glycol succinate), manufactured at the company’s Kankakee, Illinois (USA), site, to its Minden, Germany, facility. The transition is expected to be completed by the first quarter of 2014. “Expanding the Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) manufacturing capacity at our Minden site is another example of BASF’s commitment to the pharmaceutical and dietary supplement market. The relocation creates a more centralized production facility, reduces complexity in the production setup, and provides room for future expansion,” said Dr. Thorsten Schmeller, Head of Global Marketing New Products at BASF’s Global Business Unit Pharma Ingredients & Services. The Minden site has manufactured active pharmaceutical ingredients (APIs) and excipients under cGMP for more than 70 years and is regularly inspected by the FDA and European health authorities. Schmeller: “Thanks to the ICH Q7 quality management standards at our Minden site, we will be able to offer a Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) grade that fulfills the requirements of an API.” Commitment to a seamless transition Until the production in Minden is fully operational, BASF will continue to manufacture Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) at the Kankakee site, which will fully support pharmaceutical and nutraceutical customers during the transition. “We have scheduled a generous supply overlap that we expect allows for a seamless transition,” added Schmeller. “Our projection also takes into account the appropriate qualification period required to transition products used in pharmaceutical applications.” Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) production at the Minden site is expected to start in the first quarter of 2013. The Kankakee site remains an important production facility for BASF’s nutrition and health business. Besides food ingredients, the company manufactures ingredients for soaps, shampoos, detergents, coatings, inks and adhesives at the site. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) is a water-soluble derivative of vitamin E that can directly enhance the bioavailability of poorly soluble active substances. It is commonly used in pharmaceutical and nutritional formulations, but also in cosmetics. Additionally it has plasticizing effects that are very beneficial for emerging platform technologies in the pharmaceutical industry such as hot melt extrusion (HME). Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) is a water-soluble derivative of vitamin E that can directly improve the bioavailability of poorly soluble active substances. BASF Global Business Unit Pharma Ingredients & Services Global Marketing New Products head Thorsten Schmeller said the relocation creates a centralized production facility, reducing complexity in the production setup, while providing room for future expansion. The company said until the production in Minden is fully operational, it will continue to manufacture Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) at the Kankakee site. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) is commonly used in pharmaceutical and nutritional, as well as in cosmetic formulations. The production of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) at the Minden site is likely to begin in the first quarter of 2013 with the completion scheduled to Q1, 2014. D-ɑ-tocopheryl polyethylene glycol succinate (Vitamin E Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) or Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)) has been approved by FDA as a safe adjuvant and widely used in drug delivery systems. The biological and physicochemical properties of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) provide multiple advantages for its applications in drug delivery like high biocompatibility, enhancement of drug solubility, improvement of drug permeation and selective antitumor activity. Notably, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can inhibit the activity of ATP dependent P-glycoprotein and act as a potent excipient for overcoming multi-drug resistance (MDR) in tumor. In this review, we aim to discuss the recent advances of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) in drug delivery including Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) based prodrugs, nitric oxide donor and polymers, and unmodified Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) based formulations. These potential applications are focused on enhancing delivery efficiency as well as the therapeutic effect of agents, especially on overcoming MDR of tumors. It also demonstrates that the clinical translation of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) based nanomedicines is still faced with many challenges, which requires more detailed study on Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) properties and based delivery system in the future. Vitamin E has been identified as an essential factor for reproduction since 1922 1. With further investigation, it has been found with other functions involving antioxidant, anti-thrombolytic and other therapeutic effects 2, 3. However, the poor water solubility of vitamin E has greatly limited its application 4. Vitamin E d-ɑ-tocopheryl poly(ethylene glycol) 1000 succinate (simply as Vitamin E Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) or Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)), synthesized by esterification of vitamin E succinate with poly(ethylene glycol) (PEG) 1000, is a water-soluble derivative of natural vitamin E 5. It has an amphiphilic structure comprising hydrophilic polar head portion and lipophilic alkyl tail. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can be functionalized as an excellent solubilizer, emulsifier, permeation and bioavailability enhancer of hydrophobic drugs 6. Meanwhile, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can act as an anticancer agent, which has been demonstrated to induce apoptogenic activity against many cancer types. It can target the mitochondria of cancer cells, resulting in the mitochondrial destabilisation for activation of mitochondrial mediators of apoptosis 7. Interestingly, it has been documented that Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can selectively induce apoptosis in tumor cells while exhibited nontoxicity to normal cells and tissues 8. Multi-drug resistance (MDR) remains as a significant impediment to successful chemotherapy in clinical cancer treatment. What's worse, decades of research has identified that this phenomenon exists in nearly every effective drug, even the newest therapeutic agents 9. Therefore, how to effectively reverse drug resistance plays a critical role in achieving satisfied therapeutic effect in cancer treatment. It has been demonstrated that various mechanisms are involved in MDR including decreased drug influx, increased drug efflux, changed drug metabolism and promoted anti-apoptotic mechanism 10. Among them, the drug efflux mediated by ATP-binding cassette transporter P-glycoprotein (ABCB1) is one of the most investigated and characterized mechanisms for MDR. P-glycoprotein (P-gp) has 12 transmembrane regions to bind hydrophobic substrate drugs and two ATP-binding sites to transport drug molecules 11. It can pump out P-gp substrate drugs to the extracellular space and thus decrease the intracellular drug accumulation. Over the past few decades, considerable efforts have been devoted to exploring P-gp inhibitors for overcoming MDR. Several nonionic surfactants such as Pluronic, Tweens, Span and Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) have been found with the ability to inhibit P-gp activity 12, 13. Though the exact mechanism of P-gp inhibition by these surfactants remains unclear, steric blocking of substrate binding 14, alteration of membrane fluidity 15 and inhibition of efflux pump ATPase 16, 17 have been proposed as the potential mechanisms. As a widely used adjuvant in drug delivery, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) has been shown as the most potent and commercially available P-gp inhibitor among these surfactants 18. As a membrane transporter of ATP-binding cassette family, P-gp can pump out the substrate drug via an ATP-dependent mechanism 19. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can target the mitochondria and cause its dysfunction, resulting in the depletion of intracellular ATP. The reduced ATP level can then influence the activity of P-gp and decrease the drug efflux to extracellular space 20. Besides, the hydrolysis of ATP by ATPase is critical for converting the P-gp transporter to an active conformational state for substrate drug efflux 16. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) itself cannot stimulate ATPase activity as it is not a substrate of P-gp, but can inhibit the substrate induced ATPase activity 21. In our previous works, we have demonstrated that Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can significantly enhance the intracellular accumulation and cytotoxicity of chemotherapeutics to drug resistant breast adenocarcinoma cells (MCF-7/ADR) and human ovarian cancer cells (A2780/T) 22-24. Since Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) has been approved by the FDA as a safe pharmaceutical adjuvant, it has been extensively used in drug delivery systems as surfactant, solubilizer, stabilizer and P-gp inhibitor for enhancing bioavailability and reversing MDR. In our previous reviews 5, 6, we discussed Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) as a molecular biomaterial and its original application in drug delivery. In this review, we focused on the progress of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) in drug delivery in recent five years, which took advantages of the P-gp inhibiting ability and other basic properties. We summarized the applications of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) based prodrugs, nitric oxide (NO) donor and polymers for overcoming MDR and delivering therapeutic agents. We also discussed the unmodified Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) based formulations applied in reversing MDR, improving oral availability and enhancing drug permeation. We expect this review will give new inspiration for the application of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) in overcoming MDR and drug delivery. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) as a surfactant Poor water solubility and/or poor permeability remain as the major obstacles for therapeutic drugs to exert maximum activity. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can be applied as solubilizer, absorption and permeation enhancer, emulsifier as well as surface stabilizer in drug delivery. It has been widely used in fabricating nanodrugs or other formulations for many poorly water-soluble or permeable drugs, especially for biopharmaceutics classification system (BCS) class Ⅱ and Ⅳ drugs 5, 6. In addition, it has been reported that Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) exhibited strong enhancement on the secretion of chylomicrons at low concentration and enhanced the intestinal lymphatic transport 25, which would further improve drug absorption ability. As a surfactant, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) shows outstanding capability to increase drug absorption through different biological barriers. For example, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) was used to fabricate repaglinide nanocrystals for enhancing saturation solubility and oral bioavailability up to 25.7-fold and 15.0-fold compared with free drug, respectively 26. In Ussing chambers transport studies, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can enhance drug permeation in colonic tissue 27. In addition, the influence of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) on the intestinal absorption ability of icariside Ⅱ was investigated in Caco-2 monolayer model and a four-site rat intestinal perfusion model. In Caco-2 monolayer model, the apparent permeability coefficients value of icariside Ⅱ was increased and the efflux ratio was remarkably reduced owing to the effect of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS). The four-site rat intestinal perfusion model investigation further showed significantly increased permeability of icariside Ⅱ in ileum and colon 28. Similar results were found in Caco-2 monolayer model with rhodamine123 (Rh123) in the presence of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) 29. Interestingly, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can also act as a pore-forming agent in the fabrication of nanoparticles with high drug encapsulation efficiency, small particle size and fast drug release 30. Besides, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can be used as emulsifier or surface stabilizer for the preparation of drug formulations as the hydrophobic portion can entrap hydrophobic drug and the hydrophilic part can stabilize the formulations. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) as a P-gp inhibitor for overcoming MDR Drug resistance of cancer cells can restrict the therapeutic efficacy in chemotherapeutic treatment. As the ATP dependent membrane transporter, P-gp has been one of primary causes for MDR. It can pump out the P-gp substrate drugs to decrease intracellular drug accumulation, thus reducing the cytotoxic effect of chemotherapeutic drugs in drug resistant cancer treatment. Over the past decades, there have been continuous interests to combine P-gp substrate drugs with inhibitor or some polymer with P-gp inhibiting capability in formulations for overcoming MDR 31. Rh123, a P-gp substrate, is usually used as the model drug to study the intracellular retention of drug in MDR tumor cells. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can significantly increase the intracellular accumulation of Rh123 in drug-resistant tumor cells compared with free Rh123, which was evidenced from the flow cytometry and confocal microscope analysis 32. It seems that Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can effectively inhibit the activity of P-gp to overcome MDR. Since the efflux transporter P-gp is ATP-dependent, the depletion of ATP plays a very important role in overcoming MDR. The MDR reversing effect of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) is mainly attributed to its dual actions, the inhibition of mitochondrial respiratory complex Ⅱ for shorting ATP supply and the suppression of substrate induced P-gp ATPase activity for blocking ATP utilization 20, 21, 33, 34. Mitochondrial respiratory complex Ⅱ, also called succinate dehydrogenase, plays an important role in mitochondrial electron transport, which is an essential part in the tricarboxylic acid cycle as well as the mitochondrial respiratory chain 35. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can bind with mitochondrial respiratory complex Ⅱ and induce subsequent mitochondrial dysfunction, resulting in significant depletion of intracellular energy 20, 36. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can accumulate in mitochondria and inhibit the activity of complex Ⅱ, and consequently disrupt the electron transfer and activate calcium channel, which would result in the overload of calcium and ensuing dysfunction of mitochondria. Mitochondrial dysfunction is characterized by the dissipating effect on mitochondrial membrane potential, decreased ATP level and increased reactive oxygen species (ROS) generation 37. Furthermore, the mitochondrial targeting ability of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) may accelerate the mitochondrial dysfunction 32, 38. Substrate induced P-gp ATPase activity suppression is another mechanism for Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) to decrease drug efflux 21. ATPase activity can be stimulated by the binding of substrate to transmembrane regions of P-gp 39. Subsequently, ATP is transformed into adenosine diphosphate (ADP) for the energy supply of drug efflux. Unlike the classical P-gp inhibitor verapamil, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) is not a substrate of P-gp and shows no competitive inhibition effect of substrate binding. The steric blocking function of the binding site and/or allosteric modulation of P-gp appear to be the ATPase inhibition mechanism. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) as a selective anticancer agent for synergistic antitumor effects Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can induce apoptosis and exhibits selective cytotoxic effects against cancer cells, which can be combined with chemotherapeutic drugs for reducing side effect and increasing treatment efficiency. There is significant different response on normal immortalized breast cells and cancer cells after Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) treatment. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can trigger the apoptotic signaling pathways and induce G1/S cell cycle arrest in breast cancer cells MCF-7 and MDA-MB-231, but no remarkable effect on non-tumorigenic cells MCF-10A and MCF-12F 40. Coincidentally, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can induce apoptosis on T cell acute lymphocytic leukemia Jurkat clone E6-1 cells, but not on human peripheral blood lymphocytes. The apoptosis was evidenced by increased nuclear DNA fragmentation, enhanced cell cycle arrest and reduced mitochondrial membrane potential 41. The selective apoptosis mechanisms of cancer cells mediated by Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) are complicated and can be listed as follows: ROS inducer Similar to α-tocopheryl succinate (α-TOS), Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can induce cancer cell apoptosis through the destruction and inhibition of mitochondrial respiratory complex Ⅱ 33, 41. The subsequent electron transfer chain disruption can promote ROS generation 20. The escalated intracellular ROS, a mediator of apoptosis, can induce DNA damage and the oxidation of lipid, protein and enzyme, leading to cell destruction 42. Besides, it has been demonstrated that ROS-mediated apoptosis mechanism was correlated with the selective anticancer activity as tumor cells could be more sensitive to ROS than normal cells 43-45. Compared with TOS, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) exhibited enhanced ROS generation capability 46. Downregulation of anti-apoptotic proteins Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can inhibit the phosphorylation of protein kinase B (PKB or AKT) and then downregulate the anti-apoptotic proteins Survivin and Bcl-2, which can induce the activation of caspase-3 and -7 for caspase-dependent programmed cell death 40. Concurrently, caspase-independent programmed cell death and G1/S phase cell cycle arrest also occurred 40, 41. Survivin and Bcl-2 are usually overexpressed in most cancer cells while remarkably reduced in normal cells 47. This may be the main reason for the selective cytotoxicity of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS). DNA damage Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can induce both caspase-dependent and caspase-independent DNA damage. This kind of DNA damage was observed in androgen receptor positive (AR+) LNCaP cells but not in AR- DU145 and PC3 cells, which was related to the cellular microenvironment 48. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX conjugate Doxorubicin (DOX) is a P-gp substrate and broad spectrum anticancer drug. However, the acquired drug resistance of DOX is an obstacle to its clinical applications in the progress of cancer therapy. Bao et al. 23 developed a pH-sensitive Schiff base-linked prodrug, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-CH=N-DOX (also called TD), by conjugating DOX with Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) for overcoming MDR. This prodrug can self-assemble into stable micelles in physiological condition and realize in vivo tumor targeting and long blood circulation by introducing a PEGylated lipid. It was the first time to provide a “molecular economical” way to combat tumor as the system combined the tumor targeting from the integrin receptor ligand peptide cyclic RGD (cRGD), long circulation property from PEGylated lipid, overcoming MDR from the material Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) and stimuli-responsive release from Schiff based linker. The formulated hybrid micelles showed pH-sensitive drug release profile and obvious particles size change in pH 5.0 buffer which simulated the endo/lysosomal acidic environment. It also demonstrated increased DOX uptake by flow cytometry and confocal microscope analysis, and enhanced retention through in vivo pharmacokinetics compared with free drug. DOX exhibited good retention in drug sensitive MCF-7 cells during incubation. On the contrary, free drug showed much low DOX content and remarkably reduced retention in MCF-7/ADR cells even with extended incubation time. Both the P-gp inhibitors of verapamil and Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) can increase the drug accumulation in MCF-7/ADR cells. The prodrug micelles achieved the similar drug uptake and retention trend with the admixture of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) and DOX in MCF-7/ADR cells. It seems that the rapidly dissociated Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) from the internalized micelles can inhibit the P-gp activity and retain DOX for subsequent cytotoxicity against MDR tumors. The enhanced cytotoxicity and apoptosis was induced by the hybrid micelles in MCF-7/ADR cells compared with free DOX as the half-maximal inhibitory concentrations (IC50) of hybrid micelles was 95-fold lower than that of free drug after 72 h incubation. The mechanism of antitumor efficacy was further investigated through the analysis of intracellular ROS production, change of mitochondrial membrane potential (ΔΨm) and intracellular ATP level (Figure ​Figure22B). The accumulation of ROS, decreased mitochondrial membrane potential and decreased ATP generation from the hybrid micelles may contribute to the P-gp inhibition by Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) with cutting off the energy supply from the 'cellular power plants' of mitochondria. The prodrug exhibited significant growth inhibition on MCF-7/ADR tumor (Figure ​Figure22C) and also tumor growth/metastasis inhibition on murine melanoma B16F10 and hepatocarcinoma H22 with cRGD decorated on the hybrid micelles. It provided a safe and simple prodrug platform to relieve the burden from delivery system and improve the therapeutic efficiency of nanomedicine through the rational design of prodrug for effective cancer treatment. Some other Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX prodrugs were also designed and constructed 55-57. Feng's group 55 developed Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX prodrug by directly conjugating succinic anhydride modified Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) with DOX. The prodrug showed improved cell uptake and cytotoxicity. Compared with free drug, 4.5- and 24-fold of half-life (t1/2) and area under curve (AUC) were found in Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX prodrug, respectively. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX-folic acid conjugate (Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX-FOL) was further introduced for targeted chemotherapy with higher therapeutic effects and fewer side effects 56. Moreover, the prodrug of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX can also be applied to package drug for combinational therapy. Hou et al. 57 constructed an acid-sensitive Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX prodrug by firstly synthesizing a pH-sensitive cis-aconitic anhydride-modified DOX and then conjugating with Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS). The prodrug can self-assemble into nanoparticles. Photosensitizer chlorin e6 (Ce6) was loaded in this Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-DOX prodrug nanoparticles for near-infrared fluorescence imaging and combination of chemotherapy and photodynamic therapy against tumor. The nanoparticles exhibited pH-responsive DOX and Ce6 release characteristics, which was caused by the acid-sensitive linker between Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) and DOX. It also demonstrated synergistic effects on cell uptake, cancer cell apoptosis and significant growth suppression in non-small cell lung cancer (A549). Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-PTX conjugate Paclitaxel (PTX) is a BCS class Ⅳ drug with poor solubility and permeability as well as a P-gp substrate, which hinders the effective drug delivery and MDR tumor therapy. Zhang's group 58 synthesized a redox-sensitive prodrug Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-SS-PTX, which could be rapidly dissociated in intracellular redox environment (high GSH concentration) to release PTX for cytotoxicity against tumor and Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) active ingredient for P-gp inhibition. The prodrug can self-assemble to stable micelles and realize the passive tumor targeting through the enhanced permeation and retention (EPR) effect. Compared with non-responsive ester bond conjugated PTX prodrug Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-CC-PTX, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-SS-PTX exhibited better stability and in vitro sustained drug release triggered by intracellular reductive environment. The increased stability of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-SS-PTX micelles may be attributed to the soft sulfurs linker between Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) and PTX in comparison to the only two carbon linker of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-CC-PTX. Compared with the clinical formulation of Taxol® and Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-CC-PTX, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-SS-PTX micelles exhibited increased intracellular PTX accumulation for drug-resistant A2780/T cells, which may be caused by the rapid dissociated Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) from the redox-sensitive prodrug. Rh123 was used as a model drug of P-gp substrate to evaluate the drug retention in MDR tumor. When the cells treated with verapamil or prodrugs, Rh123 fluorescence intensity was increased compared with free Rh123. In particular, much higher fluorescence intensity was exhibited in Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-SS-PTX compared with Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-CC-PTX, which further confirmed the P-gp inhibition property from dissociated Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS). As expected, this functional prodrug micelle increased the cytotoxicity of PTX in A2780/T cells. Compared with the uncleavable Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-CC-PTX prodrug and Taxol®, the stimuli-responsive prodrug reduced the IC50 and increased the apoptosis/necrosis of MDR tumor. In vivo evaluation further demonstrated the potential of this prodrug micelle on cancer treatment as the increased AUC, extended t1/2, enhanced drug distribution in tumor and significant tumor growth inhibition with reduced side effects. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-cisplatin conjugate Cisplatin is widely used in testicular, ovarian, cervical, head and neck, and non-small-cell lung cancers. However, the clinical application is limited for low solubility, nephrotoxicity, severe peripheral neurotoxicity, inherent and acquired drug resistance 59. Feng's group 60 developed Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-cisplatin prodrug to improve the water-solubility and reduce the neurotoxicity of cisplatin. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-cisplatin can self-assemble to micelles with high drug loading capability. The higher cell uptake and cytotoxicity against HepG2 hepatocarcinoma cells were found in Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-cisplatin prodrug compared with free drug. The prodrug micelles also showed significant neuroprotective effects with higher IC50 value for the SH-SY5Y neuroblast-like cells in comparison to free cisplatin. In addition, Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) is a powerful anticancer agent when dealing with breast cancer with high level of human epidermal growth factor receptor 2 (HER2) expression 61. It may be related to the inhibition effect of mitochondrial respiratory complex Ⅱ and the ensuing ROS generation, resulting in cell apoptosis via the HER2 receptor tyrosine kinase signaling pathway 33. Mi and coworkers 62 developed a targeted delivery system of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-cisplatin prodrug nanoparticles for the co-delivery of cisplatin, docetaxel (DTX) and Herceptin for good tumor inhibition in HER2 overexpressed breast cancers. Poly(lactic acid) (PLA)-Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS), Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-COOH and Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-cisplatin were mixed to fabricate nanoparticles for the multimodality treatment of breast cancer. The multidrug-loaded nanoparticles exhibited much lower IC50 value for SK-BR-3 cells with high expression of HER2 compared with the admixture of free drugs. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-5-FU conjugate Liu's group 63, 64 developed multifunctional nanoparticles for co-delivery of hydrophobic drug PTX and hydrophilic drug 5-fluorouracil (5-FU) to overcome MDR. Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-5-FU was synthesized by simply conjugating succinoylated Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) with 5-FU. The nanoparticles, composed of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-5-FU prodrug and PTX, showed enhanced cytotoxicity against MDR tumor compared with individual agent treatment 64. They further developed nanoemulsions with PTX-Vitamin E and Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS)-5-FU prodrug. The nanoemulsions with drugs co-delivery exhibited synergistic effect of overcoming PTX resistance in human epidermal carcinoma cell line KB-8-5 63. The effective anticancer activity was resulted from the P-gp inhibition effect of Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) and the synergistic effect of PTX and 5-FU which can simultaneously target diverse signaling pathways for cancer killing. Targeting ligand conjugated Kolliphor TPGS (VITAMIN E TPGS, E vitamini TPGS) RGD has been applied as a potential targeting ligand in cancer treatment for tumors with αvβ3 integrin receptors overexpression. Li's group 112 formulated PTX and Survivin shRNA co-loaded targeted nanoparticles by mixing Pluronic P85-polyethyleneimine, Kolliphor TPGS (VITAMIN E
KORTACID 1299
Kortacid 1299 is a natural fatty acid that can act as a cleanser and surfactant.
Kortacid 1299 is primarily used in the cosmetics industry as an emulsifier in facial creams and lotions.

CAS Number: 209-647-6.
EC Number: 209-647-6



APPLICATIONS


Kortacid 1299 finds applications in various industries, including:

Cosmetics industry - as an emulsifier in facial creams and lotions
Personal care industry - as a cleanser and surfactant in soaps and toiletries
Pharmaceutical industry - as an ingredient in topical formulations for treating skin diseases
Food industry - as a food additive, mainly as a flavoring agent in baked goods, confectionery, and dairy products
Industrial applications - as a raw material for producing surfactants, detergents, and other chemical products


Overall, Kortacid 1299 is a versatile compound that finds use in various industries due to its emulsifying, cleansing, and surfactant properties.


Kortacid 1299 is commonly used as an emulsifier in the production of cosmetic creams and lotions.
Kortacid 1299 is often added to facial products due to its moisturizing and cleansing properties.

Kortacid 1299 can also be used as a surfactant in the production of soaps and toiletries.
Kortacid 1299 can be used in hair care products as a conditioning agent.

Kortacid 1299 is often used in the production of natural and organic cosmetic products.
Kortacid 1299 is commonly used in the production of personal care products due to its biodegradability.

Kortacid 1299 can be used as a foam booster in the production of shaving creams and foams.
Kortacid 1299 can also be used as a thickener in the production of cosmetic products.
Kortacid 1299 is an effective emulsifying agent in the production of oil-in-water emulsions.

Kortacid 1299 can be used as a lubricant in the production of cosmetic products.
Kortacid 1299 is often added to lipsticks to improve their texture and application.

Kortacid 1299 can be used as a surfactant in the production of household cleaning products.
Kortacid 1299 can be added to laundry detergents as a surfactant and cleaning agent.

Kortacid 1299 is often used in the production of industrial lubricants.
Kortacid 1299 is commonly used in the production of food and pharmaceuticals.

Kortacid 1299 can be used in the production of plasticizers and resins.
Kortacid 1299 can be used in the production of metalworking fluids and cutting oils.
Kortacid 1299 is commonly used as a raw material in the production of other chemicals.

Kortacid 1299 can be used as a dispersing agent in the production of pigments and dyes.
Kortacid 1299 is often added to leather processing agents to improve their performance.

Kortacid 1299 can be used in the production of biodegradable lubricants and hydraulic fluids.
Kortacid 1299 can be used in the production of paints and coatings.

Kortacid 1299 can be used as an emulsifying agent in the production of emulsion polymers.
Kortacid 1299 is often added to adhesive formulations to improve their performance.
Kortacid 1299 can be used in the production of candles as a hardening agent.

Kortacid 1299 is used in the formulation of hair care products such as shampoos and conditioners as a foam booster and thickener.
Kortacid 1299 can be used as a lubricant in the production of various products, including rubber and plastics.

Kortacid 1299 can be used as a raw material for the production of various esters.
Kortacid 1299 is used in the manufacture of surfactants and emulsifiers for various applications.

Kortacid 1299 is used in the production of various personal care products such as bath gels and body washes as a foam booster.
Kortacid 1299 is used in the manufacture of detergents as a surfactant.

Kortacid 1299 is used as a wetting agent and emulsifier in the formulation of insecticides and herbicides.
Kortacid 1299 can be used in the manufacture of textile auxiliaries as a softening agent.

Kortacid 1299 is used in the production of metalworking fluids as a lubricant.
Kortacid 1299 is used in the formulation of leather products such as shoe polishes and leather conditioners as a softening agent.
Kortacid 1299 is used in the production of lubricants as a base oil.

Kortacid 1299 can be used as an emollient in the formulation of cosmetics such as creams and lotions.
Kortacid 1299 is used as a raw material for the production of various fragrances and flavors.

Kortacid 1299 can be used in the formulation of adhesives as a tackifier.
Kortacid 1299 is used in the manufacture of agricultural chemicals as a solvent.

Kortacid 1299 is used in the production of plasticizers as a raw material.
Kortacid 1299 is used as a lubricant in the production of various metal products such as wires and cables.
Kortacid 1299 can be used in the production of candles as a raw material.

Kortacid 1299 is used as a corrosion inhibitor in the production of metal products.
Kortacid 1299 is used in the manufacture of paper and pulp products as a sizing agent.

Kortacid 1299 is used as a raw material for the production of various resins and polymers.
Kortacid 1299 can be used as a flotation agent in the mining industry.

Kortacid 1299 is used in the production of rubber products as a plasticizer.
Kortacid 1299 is used as a mold release agent in the production of various products, including rubber and plastics.
Kortacid 1299 can be used in the formulation of lubricating oils as a viscosity modifier.


As a raw material, Kortacid 1299 can be used in a variety of products across industries.
Some examples of products that may use Kortacid 1299 in their production process include:

Cosmetics, such as facial creams and lotions, as an emulsifier and surfactant
Soaps and toiletries, as a surfactant
Detergents and cleaning products, as a surfactant and cleanser
Food products, as an additive in the production of flavors and fragrances
Pharmaceutical products, as a component in certain drug formulations
Textile industry, as an additive in fabric softeners and other textile treatments
Plastic and rubber industry, as a lubricant and release agent in the production process
Metalworking industry, as a lubricant and corrosion inhibitor in metalworking fluids
Paper industry, as a sizing agent to improve paper strength and stability
Adhesive industry, as a component in certain adhesive formulations
Paint and coatings industry, as a component in certain paint and coating formulations
Agricultural industry, as a component in certain pesticide formulations
Automotive industry, as a component in certain lubricants and additives for engine oils
Construction industry, as a component in certain concrete and mortar formulations
Petroleum industry, as a component in certain drilling muds and fluids.



DESCRIPTION


Kortacid 1299 is a natural fatty acid that can act as a cleanser and surfactant.
Kortacid 1299 is primarily used in the cosmetics industry as an emulsifier in facial creams and lotions.

Due to its biodegradable nature, Kortacid 1299 is a preferred ingredient in eco-friendly cosmetic formulations.
Additionally, Kortacid 1299 can also be used as a surfactant in soaps and toiletries.

Kortacid 1299 is a white, waxy, and odorless solid at room temperature.
Kortacid 1299 is a medium-chain fatty acid with a 12-carbon chain length, specifically lauric acid, with a purity of over 99%.

Kortacid 1299 is insoluble in water but soluble in organic solvents such as ethanol, ether, and chloroform.
Kortacid 1299 has a faint odor and a mild taste, and is often used as a flavoring agent in the food industry.
Kortacid 1299 is readily and rapidly biodegradable, making it an environmentally friendly choice for use in various applications.



PROPERTIES


Molecular formula: C12H24O2
Molecular weight: 200.32 g/mol
Melting point: 44.2 °C (111.6 °F)
Boiling point: 298 °C (568 °F)
Density: 0.89 g/cm³ at 25 °C (77 °F)
Solubility: Soluble in ethanol, ether, chloroform, and benzene, but insoluble in water
Biodegradability: Rapidly and readily biodegradable, making it an environmentally friendly ingredient.



FIRST AID


Inhalation:

Move the person to fresh air.
If the person is not breathing, call for emergency medical attention immediately and administer artificial respiration.
If breathing is difficult, give oxygen.
Get medical attention if symptoms persist.


Skin Contact:

Take off contaminated clothing and shoes immediately.
Wash affected areas thoroughly with soap and plenty of water for at least 15 minutes.
Seek medical attention if irritation or symptoms of an allergic reaction occur.


Eye Contact:

Flush eyes with plenty of water for at least 15 minutes, lifting upper and lower eyelids occasionally.
Seek medical attention if irritation or symptoms of an allergic reaction occur.


Ingestion:

Do not induce vomiting.
Rinse mouth with water.
Drink plenty of water.

Seek medical attention immediately.
Never give anything by mouth to an unconscious person.


Note to Physician:

Treat symptomatically.


General Advice:

If you feel unwell, seek medical advice (show the label or SDS where possible).
Ensure that medical personnel are aware of the material(s) involved, and take precautions to protect themselves.
Show this safety data sheet to the doctor in attendance.



HANDLING AND STORAGE


Handling:

Use appropriate protective equipment, such as gloves and safety goggles, when handling Kortacid 1299 to avoid skin and eye contact.
Avoid breathing in the dust or mist of Kortacid 1299, as it may cause respiratory irritation.

Store Kortacid 1299 in a cool, dry, and well-ventilated area away from incompatible substances, such as strong oxidizing agents.
When transferring Kortacid 1299, use closed systems or adequate ventilation to prevent the release of dust or mist.
Avoid generating dust during handling or transfer of Kortacid 1299.


Storage:

Store Kortacid 1299 in a tightly closed container in a cool, dry, and well-ventilated area away from heat, sparks, and flames.
Keep Kortacid 1299 away from sources of ignition, such as open flames and heat sources.
Store Kortacid 1299 separately from strong oxidizing agents and reducing agents.

Do not store Kortacid 1299 near food, feed, or beverages.
Keep Kortacid 1299 in its original container with a tight-fitting lid and store it in a safe location, away from children and pets.



SYNONYMS


Dodecanoic acid
Laurostearic acid
n-Dodecanoic acid
1-Undecanecarboxylic acid
C12:0 (referring to its 12-carbon chain length)
C12 fatty acid (referring to its 12-carbon chain length and fatty acid nature)
Coconut oil acid (since it is a major component of coconut oil)
Dodecanoic acid
Duodecylic acid
C12:0 fatty acid
Coco fatty acid
Cocos nucifera oil
N-dodecanoic acid
Laurostearic acid
Vulvic acid
Lauroic acid, zinc salt
Lauroic acid, lithium salt
Lauroic acid, sodium salt
Lauroic acid, potassium salt
Lauroic acid, magnesium salt
Lauroic acid, calcium salt
1-dodecoic acid
Dodecoic acid
Dodecylenic acid
n-Lauroic acid
Lipoic acid
Laurinsäure (German)
Acide laurique (French)
Acido laurico (Italian, Spanish)
Lauric acid, coconut oil
Lauric acid, palm oil
Lauric acid, animal fats
Univol U-215
Cerasynt L 30
Prifac 2954
Pelemol LA
Cithrol 10MSA
NAA 50
Coco nut oil fatty acid
Coco palm kernel oil fatty acid
Coco butter fatty acid
Coco lauric acid
Decanoic acid
Dodecoic acid
Dodecylic acid
Hydrofol acid 1299
Hydrofol acid 1299P
Kortacid 1299LA
Laurex 1299
Lauric acid, coconut oil fatty acid
NAA C-50
NAA L-50
Lauric acid (natural)
KOSTERAN-S3 G
KOSTERAN-S/3 G IUPAC Name [2-(4-hydroxy-3-octadecanoyloxyoxolan-2-yl)-2-octadecanoyloxyethyl] octadecanoate KOSTERAN-S/3 G InChI=1S/C60H114O8/c1-4-7-10-13-16-19-22-25-28-31-34-37-40-43-46-49-56(62)65-53-55(67-57(63)50-47-44-41-38-35-32-29-26-23-20-17-14-11-8-5-2)60-59(54(61)52-66-60)68-58(64)51-48-45-42-39-36-33-30-27-24-21-18-15-12-9-6-3/h54-55,59-61H,4-53H2,1-3H3 KOSTERAN-S/3 G InChI Key IJCWFDPJFXGQBN-UHFFFAOYSA-N KOSTERAN-S/3 G Canonical SMILES CCCCCCCCCCCCCCCCCC(=O)OCC(C1C(C(CO1)O)OC(=O)CCCCCCCCCCCCCCCCC)OC(=O)CCCCCCCCCCCCCCCCC KOSTERAN-S/3 G Molecular Formula C60H114O8 KOSTERAN-S/3 G CAS 26658-19-5 KOSTERAN-S/3 G EC Number 247-891-4 KOSTERAN-S/3 G E number E492 (thickeners, ...) KOSTERAN-S/3 G Molar mass 963.54 g/mol KOSTERAN-S/3 G Appearance Waxy solid KOSTERAN-S/3 G Physical Description Liquid; OtherSolid KOSTERAN-S/3 G Form Hard, waxy solid KOSTERAN-S/3 G Colour Light cream to Tan KOSTERAN-S/3 G Acid Value Max 7 mgKOH/gm KOSTERAN-S/3 G Saponification Value 176-188 mgKOH/gm KOSTERAN-S/3 G Moisture content Max 1% KOSTERAN-S/3 G Hydroxyl Value 66-80 mgKOH/gm KOSTERAN-S/3 G Heavy Metals (as Pb) Less than 10mg/kg KOSTERAN-S/3 G Arsenic Less than 3 mg/kg KOSTERAN-S/3 G Cadmium Less than 1mg/kg KOSTERAN-S/3 G Mercury Less than 1 mg/kg KOSTERAN-S/3 G Molecular Weight 963.5 g/mol KOSTERAN-S/3 G XLogP3-AA 24.3 KOSTERAN-S/3 G Hydrogen Bond Donor Count 1 KOSTERAN-S/3 G Hydrogen Bond Acceptor Count 8 KOSTERAN-S/3 G Rotatable Bond Count 56 KOSTERAN-S/3 G Exact Mass 962.851371 g/mol KOSTERAN-S/3 G Monoisotopic Mass 962.851371 g/mol KOSTERAN-S/3 G Topological Polar Surface Area 108 Ų KOSTERAN-S/3 G Heavy Atom Count 68 KOSTERAN-S/3 G Formal Charge 0 KOSTERAN-S/3 G Complexity 1100 KOSTERAN-S/3 G Isotope Atom Count 0 KOSTERAN-S/3 G Defined Atom Stereocenter Count 0 KOSTERAN-S/3 G Undefined Atom Stereocenter Count 4 KOSTERAN-S/3 G Defined Bond Stereocenter Count 0 KOSTERAN-S/3 G Undefined Bond Stereocenter Count 0 KOSTERAN-S/3 G Covalently-Bonded Unit Count 1 KOSTERAN-S/3 G Compound Is Canonicalized Yes Kosteran-S/3 G is composed of Sorbitan Tristeareate. It functions as a W/O-emulsifier. This product is suitable for skin care creams and lotions, natural care, and colour cosmetics.KOSTERAN-S/3 G is a nonionic surfactant. It is variously used as a dispersing agent, emulsifier, and stabilizer, in food and in aerosol sprays. As a food additive, it has the E number E492. Brand names for polysorbates include Alkest, Canarcel, and Span. The consistency of KOSTERAN-S/3 G is waxy; its color is light cream to tan.KOSTERAN-S/3 G , also known as E492 or sorbester P38, belongs to the class of organic compounds known as tricarboxylic acids and derivatives. These are carboxylic acids containing exactly three carboxyl groups. KOSTERAN-S/3 G is considered to be a practically insoluble (in water) and relatively neutral molecule. Within the cell, KOSTERAN-S/3 G is primarily located in the membrane (predicted from logP).KOSTERAN-S/3 G is a nonionic surfactant. It is variously used as a dispersing agent, emulsifier, and stabilizer, in food and in aerosol sprays. As a food additive, it has the E number E492. Brand names for polysorbates include Alkest, Canarcel, and Span. The consistency of KOSTERAN-S/3 G is waxy; its color is light cream to tan.Pernetti et al. (2007) showed the structuring of edible oils using a mixture of sunflower lecithin and KOSTERAN-S/3 G (STS). Individually, neither of these components was by itself capable of inducing gelation even at concentrations as high as 20% w/w. However, when a mixture was used, structuring was achieved at concentrations of approximately 4% w/w. The mixture composition that resulted in structuring ranged between 2:3 lecithin:KOSTERAN-S/3 G to 3:2 lecithin:KOSTERAN-S/3 G . Microscopy of the gels showed the presence of needle-like crystals with lengths of approximately 10 μm. Preparations of only KOSTERAN-S/3 G in oil also showed the presence of crystalline particles, although these crystals had a lower aspect ratio (less needle-like) than when lecithin was present in the mixture. Lecithin was surmised to modify the crystal habit of the KOSTERAN-S/3 G crystals such that a more needle-like morphology resulted, which is more efficient at structuring oil. However, these gels melted at a low temperature (approximately 15°C) and were very sensitive to the addition of water, both of which would limit their utility in water-rich foods.Individually both lecithin (Lec) and KOSTERAN-S/3 G (STS) are incapable of forming oil gels at concentration between 6 and 20 %wt in absence of a polar solvent. However, when mixed in specific ratios between 40:60 to 60:40, Lec:KOSTERAN-S/3 G can form firm gels at a total concentration as low as 4 %wt (Pernetti et al., 2007). The crystalline units formed in these systems are based on KOSTERAN-S/3 G , while Lec plays an important role in influencing both the morphology of the crystalline units as well as the network junctions among the formed units. The gel however has limited use as hardstock fat replacer as it starts softening at temperature above 15 °C and undergoes complete collapse at 30 °C (Pernetti et al., 2007).In chocolate formulations surface-active substances are often used, for instance to reduce viscosity. Popular additives are KOSTERAN-S/3 G (STS), sorbitan monoesters, lecithin, mono- and diacylglycerols. Since roughly two-thirds of the chocolate recipe contains non-fat-soluble substances such as sugar and cocoa powder, the lecithin acts as a lubricant. The polar part of the lecithin covers the sugar particles, while the hydrophobic part faces the fat phase. Roughly 0.5 % is needed to cover the sugar and cocoa powder particles. The covered particles reduce the viscosity of the chocolate mass which is favourable. Lecithin itself is known to reduce the crystallization rate of fat indicating that the amount of lecithin should be controlled (Guth et al., 1989). Diacylglycerols also have a negative effect on the crystallization rate and on polymorphic transformation. However, there are several types of diacylglycerols each with different properties (Siew and Ng, 2000). For instance, it has been shown that 1.3-dipalmitin increases the melting point of the palm oil while 1.2-dipalmitin decreases the melting point.KOSTERAN-S/3 G is a component often used in CBR and CBS applications to stabilize β′ crystals (Wilson, 1999). It is shown to be one of the most effective emulsifiers for improving both initial gloss as well as bloom stability (Weyland, 1994). However, KOSTERAN-S/3 G also seems to have a negative effect on crystallization rate in these applications. Sorbitan monoesters and monoacylglycerols improve the crystallization rate in CBR and CBS systems because they are insoluble in the fat phase and act as nucleation agents. However, bloom stability does not seem to improve.In summary, the minor components in a fat play a crucial part in fat crystallization, yet there is inadequate understanding of the mechanisms behind their influence. The reason is that the levels are low and individual components often influence each other.KOSTERAN-S/3 G is a component often used in CBR and CBS applications to stabilize β′ crystals (Wilson, 1999). It is shown to be one of the most effective emulsifiers for improving both initial gloss as well as bloom stability (Weyland, 1994). However, KOSTERAN-S/3 G also seems to have a negative effect on crystallization rate in these applications.Lipophilic emulsifiers in the form of KOSTERAN-S/3 G (STS) are used as crystal-modifying agents in fats, where they prevent the formation of the high-melting β-crystal. The function of KOSTERAN-S/3 G is assumed to be due to its ability to co-crystallise with triacylglycerides in the β'-crystal form, preventing a solid-state crystal transition to the higher-melting β-crystal form during storage.7 Other emulsifiers, such as LACTEM or CITREM, provide a similar crystal-modifying function in cocoa butter substitutes (CBS) or cocoa butter replacers (CBR), but are less efficient than KOSTERAN-S/3 G .In the case of the transition from beta (V) into beta (VI), there are a number of possibilities. KOSTERAN-S/3 G (used to inhibit bloom in CBR and CBS systems as well) and similar emulsifiers reportedly slow the polymorphic transformation (Garti et al., 1986). If the desire is to avoid unnecessary items on the label, TAG solutions exist. Milk fat is well known for its bloom inhibiting effect; dark chocolate often has a small amount of milk fat added for this reason. More effective are bloom retarding fats that incorporate saturated TAG having mixed long (C16, C18) and medium (C10-C14) chain fatty acids (Cain et al., 1995). Thus, they are a specific type of lauric fat. They are stable in the beta′ polymorph.KOSTERAN-S/3 G (abbreviation STS), also known as Span 65, a nonionic surfactant that can be used as an emulsifier and stabilizer in food with the European food additive number E492. Its main functions are to retard fat bloom in chocolates and prevent cloudy appearance in cooking oils.Vegetable sourced stearic acid is the most used in the manufacturing process of KOSTERAN-S/3 G and other sorbitan esters of fatty acids. KOSTERAN-S/3 G is used as a water in oil (W/O) emulsifier and when used in combination with polysorbates they can stabilize oil in water (O/W) emulsions. The formulation of the Span/Polysorbate ratio can produce emulsifying systems with various HLB values. KOSTERAN-S/3 G is mainly used as an anti-bloom agent of fat, and also maintains the color and gloss in chocolates.KOSTERAN-S/3 G and lecithin are often used as surface-active substances to reduce viscosity in chocolate formulations. In chocolate, KOSTERAN-S/3 G adjusts sugar crystallization and appearance, also it can reduce stickiness.KOSTERAN-S/3 G is used as an emulsifier that can be used to retard fat bloom by preventing β’ crystals from converting to β crystals when exposed to excessive heat conditions, which tend to migrate to the chocolate surface and thus cause fat bloom. KOSTERAN-S/3 G can be used as an anti-crystallization agent in cooking oils (e.g. palm oil, coconut oil) to prevent oils cloudy appearance which are formed by harden-fast fractions under colder temperatures. KOSTERAN-S/3 G functions as a surfactant in cosmetics and personal care products. Its concentrations typically range between 0.1% and 5% (up to 10%). KOSTERAN-S/3 G has almost no side effects when used as a food additive. It is approved as an indirect food additive by the FDA.Yes, KOSTERAN-S/3 G would be halal, kosher and vegan if the raw material – stearic acid is from natural vegetable oils. However, some manufacturing processes may use stearic acid from animal fats and oils.KOSTERAN-S/3 G is used as an emulsifier and stabiliser. It is produced by the esterification of sorbitol with commercial stearic acid derived from food fats and oils.It is a mixture of the partial esters of sorbitol and its mono- and dianhydride with edible stearic acid.KOSTERAN-S/3 G is produced by the esterification of Sorbitol with commercial edible fatty acids and consists of approximately 95% of a mixture of the esters of Sorbitol and its mono and di-anhydrides.KOSTERAN-S/3 G is an effective emulsifier to retard fat bloom in chocolate. Fat used in chocolate, particularly cocoa butter, forms as a tightly packed β’ polymorph/crystal which is an unstable crystal but is vital for the functional and aesthetic quality of chocolate. If chocolate is not tempered properly or is exposed to excessive heat, these β’ crystals convert to β crystals which are less tightly packed but are more stable. These β crystals tend to migrate to the surface causing fat bloom to occur and also having a negative impact on the aesthetics of the chocolate.KOSTERAN-S/3 G ’s structure mimics the β’ crystals and bonds with such fat crystals and retards their conversion to the less desirable β crystals.KOSTERAN-S/3 G is used as a crystal inhibitor in oils which contain fractions that harden faster during colder temperatures making the oils look cloudy. This cloudy oil is perceived by many as deteriorated oil which it actually is not. It is just aesthetically unacceptable.The addition of KOSTERAN-S/3 G retards the harder fractions from nucleating at lower temperatures and causing cloudiness in oils.KOSTERAN-S/3 G has a structure more similar to a triglyceride than to an emulsifier.KOSTERAN-S/3 G has a structure more similar to a triglyceride than to an emulsifier.In 1947, Krantzconducted life-span studies with Sorbitan palmitate, Sorbitan stearate, KOSTERAN-S/3 G , and Sorbitan oleate. The study reports were only available as secondary source and therefore very limited in documentation of examinations and results. In each study, 30 male rats were exposed to a dietary concentration of 5% test substance in their daily diet, corresponding to 5000 mg/kg bw/d (calculation based on the assumption of an average body weight of 200 g and a daily average food consumption of 20 g). No treatment-related mortality or clinical signs as well as effects on body weights and histopathology were observed. Therefore, a NOAEL of≥5000 mg/kg bw/day was determined for Sorbitan palmitate, Sorbitan stearate, KOSTERAN-S/3 G , and Sorbitan oleate. Likewise, Sorbitan laurate was tested: male rats were fed the test substance in diet for 20.5 months at 5% and for 2 years at 10%, corresponding to 5000 and 10000 mg/kg bw/day (calculation based on the assumption of an average body weight of 200 g and a daily average food consumption of 20 g) (Barboriak 1970). Diarrhea and retarded growth were observed in the animals of the 10% dose group. No effects were observed at histopathology, therefore, a NOAEL was therefore set at 5000 mg/kg bw/d. The same NOAEL was determined in a second chronic study with rats that were fed 5% of the test substance in diet for 2 years (Krantz 1970). Again, no clinical signs were observed and mortality, body weight gain, haematology and histopathology were unaffected.
KRILL OIL
Krill oil is a substance obtained from the sea creature called "Euphausia superba" that lives in the oceans.
Krill oil contains a high amount of Omega 3 fatty acids, and these fatty acids are in the form of phospholipids.
Additionally, Krill Oil is a dietary supplement containing astaxanthin, vitamin A and vitamin E.


SYNONYMS:
Aceite de Krill, Acide Docosahexaénoïque, Acides Gras Oméga 3, Acides Gras N-3, Acides Gras Polyinsaturés, Acides Gras W3, Antarctic Krill Oil, Concentré de Protéines Marines, DHA, Docosahexanoic Acid, EPA, Euphausia Superba Oil, Euphausiacé, Euphausiids Oil, Huile d' Euphausia Superba, Huile de Krill, Huile de Krill Antarctique, Huile d'Oméga 3, Marine Protein Concentrate, n-3 Fatty Acids, Omega 3, Omega-3 Fatty Acids, Omega-3, Oméga 3, Omega-3 Fatty Acids, Omega-3 Oil, Polyunsaturated Fatty Acids, W-3 Fatty Acids



Astaxanthin is a substance with strong antioxidant properties.
Omega 3 fatty acid supplements; It is known to be important in mental development, hyperlipidemia, premenstrual syndromes, inflammatory and cardiological diseases.


Omega-3 fatty acids, which nourish and support the building blocks of our body, cannot be produced by the body.
Omega-3 deficiency can manifest itself in many different ways, especially in productivity and quality of life .
At this point, you may want to use nutritional supplements for a body whose needs are met from head to toe.


Although most of the nutritional supplements containing omega-3 are produced from fish oil, it is now possible to find different sources of omega-3.
Krill oil comes from krill, tiny shrimp-like creatures that live in very cold ocean waters.
Studies show that krill oil might have health benefits similar to those of fish oil.


Shrimp-like crustaceans from the Euphausiacea family are generally called 'Krill' and consist of 86 species.
Euphausia superba, also known as the “Antarctic Krill,” is the most common Krill species in the pristine oceans surrounding Antarctica.
They are at the bottom of the food chain because they feed many marine creatures.


Krill oil, like fish oil, contains omega-3 acids EPA and DHA.
However, krill oil and fish oil differ in the chemical structures of the fatty acids they contain.
Unlike the bright golden yellow color of fish oil that we are used to, krill oil has a red tone color.


Krill oil owes its unique red color to a natural antioxidant it contains.
Krill oil also fights against free radicals with its natural antioxidant content.
Krill oil is the oil of the shellfish, also known as Antarctic krill.


Krill Oil also contains EPA and DHA fatty acids.
Due to its structure, Krill Oil is red in color.
Krill oil can be taken as a supplement when necessary.


Krill Oil is a source of Omega 3 in phospholipid form.
Krill oil is one of the most powerful antioxidants in nature with its natural astaxanthin content.
In addition, risks such as leakage, explosion and oxidation have been minimized with Licaps (liquid capsule) technology, which is produced using fish gelatin.


Krill oil is an oil obtained from a small, shrimp-like, aquatic sea creature called euphausia superba, which contains omega 3 fatty acids.
Krill oil, which offers many health benefits as it contains omega 3 fatty acids, reduces inflammation and relieves arthritis and joint pain, as well as being a powerful source of antioxidants.


Due to these properties, krill oil is also considered as an alternative to fish oil.
Krill is a shrimp-like crustacean.
Krill oil, unlike fish oil, has a phospholipid structure and contains "astaxanthin"


Krill oil, an alternative to fish oil , is rich in omega 3 fatty acids.
Although krill oil and fish oil both contain two omega 3 fatty acids, docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA), the omega 3 fatty acids found in krill oil are considered to have a higher bioavailability and absorption rate in the body than fish oil.


Krill oil is an extract prepared from a species of Antarctic krill, Euphausia superb.
Processed krill oil is commonly sold as a dietary supplement.
Krill oil, rich in Omega 3 fatty acids, is an oil obtained from a small sea creature called Euphausia superb.


Two components of krill oil are omega-3 fatty acids similar to those in fish oil, and phospholipid-derived fatty acids (PLFA), mainly phosphatidylcholine (alternatively referred to as marine lecithin).
Fishing for krill where previously the focus was on marine life of higher trophic level is an example of fishing down the food web.


While the word krill means “small fish” in Norwegian, the tiny crustaceans pack a big punch with their sources of docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA), two omega-3 fatty acids only found in marine life.


Krill Oil contains high levels of eicospentanoic acid (EPA) and docosahexaenoic acid (DHA) also known as long-chain omega 3 fatty acids which is essential for good health.
Krill Oil contains the beneficial omega-3 fatty acids EPA and DHA, and a good level of the sought after astaxanthin.


The EPA and DHA in krill oil are bound to phospholipids, which means they are rapidly and readily uptaken into cell membranes, more efficiently than EPA and DHA on triglyceride carriers, such as in fish oils.
Krill Oil is a source of fatty acids that helps to maintain normal blood pressure and heart health.


Krill is a small crustacean with an appearance similar to shrimp.
They are found in the colder waters of the ocean.
Krill primarily serve as a food source for other animals in the ocean, for example - whales, seals, penguins, squid and fish.


Krill is found in the oceans off of Antarctica, Canada, and Japan.
Harvesting of krill is controversial.
There is concern that commercial harvesting of Krill for use in Krill Oil supplements could threaten the species that consume it for food, including whales.


All krill oil sold in nutritional supplements is harvested out of the open ocean, upsetting the natural balance of food supplies for larger marine animals.
Commercial uses of Krill include salmon aquaculture farming, harvesting for use in Krill Oil capsules, as food for home aquariums, and as a human food source.


Krill, known as Okiami has been harvested by the Japanese as a human food source since the 19th century, and is also consumed in South Korea and Taiwan.
Krill has a pink or red appearance due to the plankton that they consume as a food source in the ocean.
Krill Oil is derived from Antarctic krill, small shrimp-like creatures that thrive in the frigid waters of the Southern Ocean.


These minuscule crustaceans form a crucial part of the marine food chain, serving as a primary food source for various marine species, including whales, seals, and penguins.
Krill oil, rich in Omega 3 fatty acids, is an oil obtained from a small sea creature called Euphausia superb.



USES and APPLICATIONS of KRILL OIL:
Krill Oil is an astaxanthin-derived supplement containing 1000 mg of krill oil obtained from a small shrimp-like shellfish that lives in the oceans.
Krill Oil offers high bioavailability due to its phospholipid omega 3 structure.
Krill Oil is recommended to consume 2 capsules a day for adults.


A unique formula extracted from Antarctic Krill to deliver essential omega-3 (EPA & DHA), choline, phospholipids and astaxanthin with proven effects to improve human health.
Krill Oil has also been used to treat high blood pressure, stroke, cancer, osteoarthritis, depression and premenstrual syndrome (PMS), although high quality studies with adequately sized populations validating these uses are lacking.


Krill Oil may also be used for purposes not listed in this medication guide.
Krill Oil is obtained through a meticulous extraction process that ensures the preservation of its potent nutritional profile, making it a valuable addition to the realm of dietary supplements.



BENEFITS OF KRILL OIL:
1. Krill Oil provides a Rich Source of Omega-3:
Omega-3 fatty acids, which cannot be produced by our body, are important for individuals of all ages, from 7 to 70.
You can choose fish oil supplements to meet your DHA and EPA needs, with benefits ranging from muscle development to skin beauty.

However, krill oil appears as a unique option for those who cannot consume fish oil due to complaints such as fishy smell and indigestion.
Additionally, research shows that the fatty acids contained in krill oil are more easily absorbed by the body than fish oils.
Krill oil, in phospholipid form, can be easily absorbed by the body and used more effectively.


2. Krill Oil supports the Healing of Inflammatory Diseases:
Compared to marine omega-3 products, krill oil provides higher protection against inflammatory diseases due to its easy absorption.
There are important studies showing that the natural antioxidant called axanthaxin contained in krill oil is a powerful anti-inflammatory.
With this feature, krill oil can help reduce inflammation and have positive effects on rheumatoid arthritis and joint pain.


3. Krill Oil helps Control Cholesterol:
Experts often emphasize the positive effect of omega-3 fatty acids against cardiovascular diseases.
Today, there are studies showing that krill oil is more effective than fish oil in reducing triglycerides and LDL cholesterol, known as bad cholesterol.
Similarly, krill oil may help reduce the risks of heart disease with its positive effects on insulin resistance.


4. Krill Oil supports Anti-Aging Fight with Antioxidant Content:
Supports Anti-Aging Fight with Antioxidant Content:
Antioxidants protect our body by fighting against free radicals that cause cell aging.

Free radicals can cause signs of premature aging, such as loss of elasticity on the skin surface.
Vitamins A and E contained in krill oil help maintain skin beauty and improve its general appearance.


5. Krill Oil helps Reduce PMS (Premenstrual Syndrome) Symptoms:
Research also reveals that omega-3 fatty acids have pain-relieving properties.
Studies on improving PMS symptoms have shown that krill oil may be more effective than other omega-3 sources.
Krill oil can significantly reduce painkiller use in women diagnosed with PMS.


6. Krill Oil supports the Immune System
Regular omega-3 intake is essential for a strong immune system. Krill oil, which can be easily absorbed by the intestine in its phospholipid form, supports the immune system.

Krill oil helps strengthen the immune system against diseases that increase as a result of the slowing down of the body's defense mechanism, especially during seasonal transitions.
In regular use, Krill Oil supports the body in having a more vigorous and healthy immune system.

As with all nutritional supplements, do not forget to consult your doctor before using nutritional supplements containing krill oil.
If you are allergic to any shellfish, do not use supplements containing krill oil without expert advice.



FEATURES OF KRILL OIL:
*Omega 3 in phospholipid form rich in DHA and EPA
*Formula with high bioavailability
*Free of sweeteners, lactose and gluten



ABOUT KRILL OIL:
•Krill is a small, shrimp-like shellfish and is found in all the world's oceans.
They live in flocks and feed on phytoplankton, which is a high source of Omega 3, to survive.

•These creatures feed only on microscopic algae; Due to their small size, short lifespan and diet, they do not accumulate toxins and heavy metals in their bodies.

•Krill Oil contains Superba Boost as a patented raw material and is obtained from Euphausia Superba, also called Antarctic Krill.

•Superba Boost uses Flexitech, a patented technology developed specifically for krill, to obtain high concentrations of active ingredients and to remove any unwanted content.

•Krill oil contains Omega 3 together with choline in phospholipid form.
Phospholipids are the building blocks of our cells and ensure the integrity and flexibility of our cell membranes.

•Krill oil also contains astaxanthin, one of the most powerful antioxidants in the world, in its natural structure.



WHICH DISEASES DOES KRILL OIL BENEFIT?
Research into the potential health benefits of Krill Oil spans a broad spectrum of diseases and conditions, showcasing its versatility as a therapeutic agent.
Some of the notable areas where Krill Oil has shown promise include:


*Cardiovascular Health:
The omega-3 fatty acids EPA and DHA present in Krill Oil have been extensively studied for their cardioprotective effects.

These fatty acids help reduce triglyceride levels, lower blood pressure, improve endothelial function, and decrease the risk of thrombosis, thereby promoting overall cardiovascular health and reducing the incidence of cardiovascular events such as heart attacks and strokes.


*Joint Health:
The anti-inflammatory properties of Krill Oil, attributed to its omega-3 fatty acids and astaxanthin content, make it a promising adjunctive therapy for managing inflammatory joint conditions such as rheumatoid arthritis and osteoarthritis.

By modulating inflammatory pathways and attenuating joint inflammation, Krill Oil may help alleviate pain, improve joint function, and enhance overall quality of life for individuals living with these debilitating conditions.


*Cognitive Function:
Omega-3 fatty acids, particularly DHA, are essential components of brain cell membranes and play crucial roles in neurotransmission, synaptic plasticity, and cognitive function.

Studies suggest that regular consumption of Krill Oil may support brain health and cognitive function, reducing the risk of cognitive decline and age-related neurodegenerative disorders such as Alzheimer's disease.


*Skin Health:
The antioxidant properties of astaxanthin, coupled with the anti-inflammatory effects of omega-3 fatty acids, make Krill Oil a promising agent for promoting skin health and combating various dermatological conditions.

Astaxanthin protects skin cells from oxidative damage induced by UV radiation, while omega-3 fatty acids help maintain skin barrier function, reduce inflammation, and support overall skin hydration and elasticity.


*Women's Health:
Krill Oil may offer unique benefits for women's health, particularly during pregnancy and menopause.
Omega-3 fatty acids play critical roles in fetal development, supporting healthy brain and eye development in the developing fetus.

Additionally, Krill Oil may help alleviate symptoms of menopausal transition, such as hot flashes and mood disturbances, due to its hormonal balancing and anti-inflammatory effects.



BENEFITS OF KRILL OIL:
Krill Oil is also possible to explain the details of the benefits of krill oil as follows:

*Krill oil is a powerful source of antioxidants

*Krill oil, which carries the potential benefits of both fish oil and omega 3, stands out as a powerful source of antioxidants.
These powerful antioxidants play an effective role in fighting free radicals in the body.


*Krill Oil reduces inflammation thanks to Omega 3 and astaxanthin:
Krill oil has a reducing effect on inflammation and inflammation in the body, thanks to the omega 3 and astaxanthin it contains.
Astaxanthin is also considered to have anti-inflammatory and antioxidant benefits that can help combat the negative effects of free radicals on the brain and nervous system.


*Krill oil reduces arthritis and joint pain:
Studies have shown that arthritis and joint pain decrease in people who use krill oil.


*Krill oil supports heart health
Krill oil is a form of oil that supports heart health as it is an effective source of reducing total cholesterol and triglycerides.
At the same time, krill oil can increase levels of good cholesterol, known as HDL .


*Krill Oil lowers bad cholesterol:
Offering many health benefits, krill oil can also prevent some possible diseases, especially heart diseases, by lowering bad cholesterol.


*Krill Oil helps build a healthy immune system
Rich in antioxidants, containing omega 3 fatty acids, reducing inflammation in the body and lowering bad cholesterol levels, krill oil helps create a healthy immune system.


*Krill Oil can reduce anxiety levels
Since it is evaluated that there is a connection between the intake of Omega 3 and the decrease in anxiety level, it is evaluated that krill oil may also be effective in reducing anxiety.


*Krill Oil is a source of vitamins A and E.
Krill oil also offers effective benefit potential, especially for eye health, thanks to the vitamins A and E it contains.



WHAT ARE THE BENEFITS OF KRILL OIL?
The nutritional profile of Krill Oil makes it a veritable treasure trove of health-enhancing compounds.
Krill Oil's most notable constituents include omega-3 fatty acids, specifically eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA), which play pivotal roles in various physiological processes.

These fatty acids are renowned for their anti-inflammatory properties, which can help alleviate symptoms associated with conditions such as arthritis and promote cardiovascular health by reducing the risk of coronary artery disease and supporting optimal lipid profiles.

Additionally, Krill Oil boasts a potent antioxidant arsenal, including astaxanthin, a carotenoid pigment responsible for the vibrant red hue of krill and various marine organisms.

Astaxanthin exhibits exceptional antioxidant activity, scavenging free radicals and combating oxidative stress, thereby protecting cells from damage and promoting overall health and longevity.



HOW IS KRILL OIL CONSUMED?
Krill Oil is predominantly available in the form of softgel capsules, which are encapsulated to preserve the integrity of the oil and enhance its shelf life.
These capsules are designed for oral consumption, offering a convenient and hassle-free way to incorporate Krill Oil into your daily regimen.
The softgel form also ensures easy digestion and absorption, minimizing any potential discomfort often associated with consuming fish oil supplements.



HOW MUCH KRILL OIL SHOULD BE CONSUMED DAILY?
Determining the optimal dosage of Krill Oil is essential to maximize its health benefits while minimizing the risk of adverse effects.
While individual requirements may vary based on factors such as age, gender, and overall health status, a general guideline suggests a daily intake of 1 to 3 grams of Krill Oil.
However, it is crucial to consult with a qualified healthcare professional to assess your specific needs and tailor the dosage accordingly.



KEY BENEFITS OF KRILL OIL:
*Source of the omega-3 fatty acids EPA and DHA
*Supports heart and brain health
*Anti-inflammatory; supports joint health
*Source of the antioxidant astaxanthin



KRILL OIL ALSO CONTAINS:
*Phospholipid-derived fatty acids (PLFA), which may result in better absorption, and marine lethicin
*A carotenoid antioxidant called astaxanthin.
Antioxidants inhibit oxidation and may neutralize the oxidant effect of free radicals and other substances in body tissues that may lead to disease.



BENEFITS OF KRILL OIL:
Studies have shown krill oil may have a variety of health benefits.
Here are some possible ways it can help you.

*Krill Oil may help your heart
Research shows that krill oil may be effective in reducing total cholesterol and triglycerides.
It may also increase HDL (good) cholesterol levels.

*Krill Oil may reduce inflammation
Research shows that omega-3 fatty acids, which are found in krill oil, may decrease blood pressure in some individuals.

Krill oil also contains astaxanthin, a pigment that’s found in carotenoids (it’s also what gives salmon its pink-red color).
Astaxanthin has been shown to also have anti-inflammatory and antioxidant benefits, which may help fight the negative effects of free radicals on your brain and nervous system.

*Krill Oil may reduce arthritis and joint pain
Another study examined how krill oil may reduce the symptoms of rheumatoid arthritis.
Those who took 300 milligrams of krill oil each day for 30 days saw an improvement in symptom reduction and used less rescue medication.

*Krill Oil can also help with pain.
A small study gave participants with mild knee pain krill oil for 30 days.
The results showed a significant reduction in pain while they were standing or sleeping.

*Krill Oil may help with PMS symptoms
For those who deal with PMS, using krill oil may help alleviate period pain and other symptoms.
A study compared fish oil to krill oil and while both supplements improved symptoms for those with PMS, the individuals taking krill oil needed less pain medication.



KRILL OIL CONTAINS:
Krill oil contains a natural combination and concentration of the following four key nutrients: Omega-3 (EPA & DHA), Phospholipids, Choline, Astaxanthin

*Brain:
Phospholipids assist in the transportation of omega-3 DHA across the blood-brain barrier.

*Heart:
Krill oil has been shown to lower fasting triglycerides which are a risk factor for cardiovascular disease.

*Liver:
Choline and omega-3s are important for maintaining healthy liver function and aid fat metabolism.

*Eyes:
Omega-3s are especially important to help keep your eyes healthy, with the highest concentration of DHA in the body found in the retina.

*Skin:
Omega-3s play a role in modulating the hydration and elasticity of the skin.

*Joints:
Omega-3s play an important role in regulating inflammation in the body, which can have a crucial impact in protecting our joints throughout life.



FEATURES OF KRILL OIL:
Krill is a tiny crustacean that is best known as a significant source of omega 3 fatty acids eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA).
These fatty acids contribute to a healthy heart, mind and body.

They have many roles in the body, including:
*Being raw materials for building cell membranes (DHA is particularly important for retina, brain and sperm cells)
*Making eicosanoids - signalling molecules that direct traffic in the world of inflammation, cardiovascular and lung function, and the immune and endocrine systems
*Specifically, helping to lower blood triglycerides and reducing the risk of blockages linked to heart disease
*Providing a source of energy


Krill oil also contains phospholipids.
Phospholipids, like phosphatidylcholine, are an important component of all our cell membranes, and are particularly important in brain cells and cell communication.

When attached to omega 3 fatty acids like in krill oil, phospholipids are responsible for carrying the fatty acids into cells and significantly increase the potency and bioavailability of both EPA and DHA.
This allows us to take less krill oil to get the same benefit as a higher amount of fish oil.

Antarctic krill, like that found in Organika’s Krill Oil, is also rich in the natural antioxidant astaxanthin.
The deep red colour of each capsule is due to this astaxanthin content.

Recognized for the health-promoting suppression of free radicals, astaxanthin helps to keep the oil fresh and protects the omega-3 fatty acids from oxidation and going rancid.
This means no additives are necessary to maintain the long-term stability of the oil.



WHAT ARE THE BENEFITS OF KRILL OIL?
Krill oil contains fatty acids similar to fish oil and is a rich source of omega 3, supports immunity thanks to the antioxidant astaxanthin , can help reduce inflammation as well as arthritis and joint pain, and protects heart health.

Krill oil benefits can be listed as follows:
*Krill oil is a powerful source of antioxidants.
*Krill Oil strengthens immunity and protects the body against free radicals.
*Krill Oil reduces inflammation thanks to Omega 3 and astaxanthin.
*Krill oil may reduce arthritis and joint pain
*Krill Oil supports heart health.
*Krill Oil lowers bad cholesterol.
*Krill Oil helps build a healthy immune system.
*Krill Oil can reduce anxiety levels.
*Krill oil contains vitamins A and E.



HOW MUCH KRILL OIL SHOULD YOU TAKE?
Since krill oil is not an established treatment, there's no standard dose.
Talk to your healthcare provider to see if krill oil is right for you.



CAN YOU GET KRILL OIL NATURALLY FROM FOODS?
The only source of krill oil is krill.



DIFFERENCE BETWEEN KRILL OIL AND FISH OIL:
Krill oil and oceanic fish oil are rich in omega-3 fatty acids, mainly eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA).
While both contain some EPA and DHA as free fatty acids, krill oil contains particularly rich amounts of choline-containing phospholipids and a phosphatidylcholine concentration of 34 grams per 100 grams of oil.

Krill oil also contains appreciable content of astaxanthin at 0.1 to 1.5 mg/ml, depending on processing methods, which is responsible for its red color.
While fish oil is generally golden yellow in colour, krill oil tends to be reddish.
Krill Oil is generally more expensive to buy as compared to fish oil.



WHAT IS IN KRILL OIL?
Krill contains an oil that is similar to the oils found in fish oils, the omega-3 fatty acids.
Omega-3 fatty acids are recommended for use in lowering triglyceride levels.
Krill Oil use as a supplement to lower blood lipids is increasing in popularity.



KRILL OIL CONTAINS:
The omega-3 polyunsaturated fatty acids EPA (Eicosapentaenoic Acid) and DHA (Docosahexaenoic).
Omega-3 polyunsaturated fatty acids are also found in oils from certain types of fish, vegetables, and other plant sources.
Unlike fish oil, the omega-3 fatty acids in Krill oil are absorbed and carried to the body's cells in phospholipid form.

Omega-3 fatty acids, in combination with diet and exercise, work by lowering the body's production of “bad”, low density lipoprotein (LDL) and triglycerides, and may raise high density lipoprotein (HDL) “good” cholesterol.

High levels of cholesterol and triglycerides can lead to coronary artery disease, heart disease, and stroke.
Supportive, but not conclusive research shows that consumption of EPA and DHA omega-3 fatty acids may reduce the risk of coronary heart disease.



WHAT ARE THE BENEFITS OF KRILL OIL?
In the realm of natural supplements, one name has been garnering increasing attention for its myriad health benefits: Krill Oil.

*Extracted from tiny crustaceans found in the icy waters of the Antarctic, Krill Oil has emerged as a powerhouse of essential nutrients, particularly renowned for its omega-3 fatty acid content.

But what exactly is Krill Oil, how does one incorporate it into their daily routine, and what wonders does it hold for our health?
Let's embark on a deep dive into the world of Krill Oil.



HEALTH BENEFITS OF KRILL OIL:
Krill oil's phospholipid-complex of omega-3 and choline provides support to the heart, brain, liver and eyes, with recent research showing benefits in skin and sports segments.



HOW TO USE KRILL OIL:
RECOMMENDED DOSE — (ORAL) ADULTS ONLY:
Take 1 to 2 softgel capsules three times per day.



WHY DO PEOPLE TAKE KRILL OIL?
Krill oil contains EPA and DHA, the same omega-3 fatty acids in fish oil, although usually in smaller amounts.
The effects of krill oil have not been researched as thoroughly as those of fish oil.

But a few preliminary studies suggest that krill oil could be superior in some ways.
Krill oil might be better absorbed in the body than fish oil.

One small study found that krill oil, like omega-3s in general, could improve rheumatoid arthritis and osteoarthritis symptoms such as pain, stiffness, and functional impairment.
It also lowered levels of C-reactive protein, a marker for inflammation in the body that's been linked with heart disease.

In addition, krill oil eased symptoms of premenstrual syndrome in another small study.
Because some studies indicate that the fatty acid DHA may benefit a developing child’s brain, krill oil is sometimes taken by pregnant women or given to children.



6 SCIENCE-BASED HEALTH BENEFITS OF KRILL OIL:
1. Excellent Source of Healthy Fats:
Both krill oil and fish oil contain the omega-3 fats EPA and DHA.

However, some evidence suggests that the fats found in krill oil may be easier for the body to use than those from fish oil, since most omega-3 fats in fish oil are stored in the form of triglycerides.

On the other hand, a large portion of the omega-3 fats in krill oil can be found in the form of molecules called phospholipids, which may be easier to absorb into the bloodstream.

A few studies found that krill oil was more effective than fish oil at raising omega-3 levels, and hypothesized that their differing forms of omega-3 fats might be why.

Another study carefully matched the amounts of EPA and DHA in krill oil and fish oil, and found that the oils were equally effective at raising levels of omega-3s in the blood.
More research is needed to determine whether krill oil is actually a more effective, bioavailable source of omega-3 fats than fish oil.


2. Can Help Fight Inflammation
Omega-3 fatty acids like those found in krill oil have been shown to have important anti-inflammatory functions in the body.
In fact, krill oil may be even more effective at fighting inflammation than other marine omega-3 sources because it appears to be easier for the body to use.

What’s more, krill oil contains a pink-orange pigment called astaxanthin, which has anti-inflammatory and antioxidant effects.
A few studies have begun to explore the specific effects of krill oil on inflammation.
One test-tube study found that it reduced the production of inflammation-causing molecules when harmful bacteria were introduced to human intestinal cells.


3. Might Reduce Arthritis and Joint Pain
Because krill oil seems to help reduce inflammation, it may also improve arthritis symptoms and joint pain, which often result from inflammation.
In fact, a study that found krill oil significantly reduced a marker of inflammation also found that krill oil reduced stiffness, functional impairment and pain in patients with rheumatoid or osteoarthritis.


4. Could Improve Blood Lipids and Heart Health
Omega-3 fats, and DHA and EPA specifically, are considered heart-healthy.

Research has shown that fish oil may improve blood lipid levels, and krill oil appears to be effective as well.
Studies have shown it may be particularly effective at lowering levels of triglycerides and other blood fats.
One study compared the effects of krill oil and purified omega-3s on cholesterol and triglyceride levels.

Only krill oil raised “good” high-density-lipoprotein (HDL) cholesterol.
It was also more effective at decreasing a marker of inflammation, even though the dosage was much lower.
On the other hand, the pure omega-3s were more effective at lowering triglycerides.

A recent review of seven studies concluded that krill oil is effective at lowering “bad” LDL cholesterol and triglycerides, and may increase “good” HDL cholesterol, too.

Another study compared krill oil to olive oil and found that krill oil significantly improved insulin resistance scores, as well as the function of the lining of the blood vessels.
More long-term studies are needed to investigate how krill oil affects the risk of heart disease.


5. Krill Oil may Help Manage PMS Symptoms
In general, consuming omega-3 fats may help decrease pain and inflammation.
Several studies have found that taking omega-3 or fish oil supplements can help decrease period pain and symptoms of premenstrual syndrome (PMS), in some cases enough to decrease the use of pain medication.

It appears that krill oil, which contains the same types of omega-3 fats, may be just as effective.
One study compared the effects of krill oil and fish oil in women diagnosed with PMS.

The study found that while both supplements resulted in statistically significant improvements in symptoms, women taking krill oil took significantly less pain medication than women taking fish oil.
This study suggests that krill oil may be at least as effective as other sources of omega-3 fats at improving PMS symptoms.


6. Krill Oil’s Easy to Add to Your Routine
Taking krill oil is a simple way to increase your EPA and DHA intake.
Krill Oil’s widely available and can be purchased online or at most pharmacies.
The capsules are typically smaller than those of fish oil supplements, and may be less likely to cause belching or a fishy aftertaste.

Krill oil is also typically considered to be a more sustainable choice than fish oil, because krill are so abundant and reproduce quickly.
Unlike fish oil, Krill Oil also contains astaxanthin.



KRILL OIL VS. FISH OIL:
While krill and fish oil both have DHA and EPA, it’s believed that those omega-3 fatty acids found in krill oil have a higher bioavailability — or rate of absorption in your body — than fish oil.

It might have something to do with the DHA and EPA being found as molecules called phospholipids in krill oil.
In fish oil, the DHA and EPA are stored in the form of triglycerides.
More research is needed to determine the exact reason krill oil might be absorbed more easily.


KRONOS 2056
KRONOS 2056 KRONOS 2056 is a versatile pigment with a warm tone recommended for conventional air-drying paints, silicate paints, plasters, silicone resin paints and impregnating baths for paper laminates. It confers good exterior durability. KRONOS 2056 is a versatile pigment with a warm tone recommended for plasticisers and various types of plastics. It confers good exterior durability. Kronos 2056 KRONOS 2056 is titanium dioxide. It is a rutile pigment produced by the sulphate process and surface treated with aluminium and silicon compounds. It disperses readily, provides good opacity and a warm tone, confers good exterior durability. KRONOS 2056 is suitable for use in conventional air drying paints, silicate paints and plasters, silicone resin paints. Product Type Titanium dioxide Chemical Composition Titanium dioxide CAS Number 13463-67-7 Product Description A versatile pigment with a warm tone Applications Conventional air drying paints Silicate paints and plasters Silicone resin paints Plasticisers Various types of plastics Impregnating baths for paper laminates Properties disperses readily provides good opacity and a warm tone confers good exterior durability on coatings and plastics is certified according to DIN EN 12878:2014-07 for the colouring of building materials based on cement and/or lime ABOUT KRONOS INC KRONOS is one of the world‘s leading manufacturers of titanium dioxide (TiO2) and has been operating as an international company for more than 90 years. The group owes its significant market position to the quality of its products, innovation, technical experience and reliable customer service around the world. Titanium dioxide pigments are used in paints and coatings, plastics, paper, building materials, cosmetics, pharmaceuticals, foods and many other commercial products. KRONOS 2056 is a versatile pigment with a warm tone recommended for conventional air-drying paints, silicate paints, plasters, silicone resin paints and impregnating baths for paper laminates. It confers good exterior durability and is certified for the colouring of building materials based on cement and/or lime according to DIN EN 12878 : 2014-07. KRONOS 2056 is a versatile pigment with a warm tone recommended for plasticisers and various types of plastics. It confers good exterior durability.
Ksantan Gum
Potassium Tripolyphosphate; pentapotassium triphosphate; potassium triphosphate; KTPP; triphosphoric acid, potassium salt ; potassium triphosphate; potassium tripolyphosphat cas no:13845-36-8
KTPP (LIKIT/GRANÜL)-(POTASSIUM TRI POLY PHOSPHATE)
L TARTARIC ACID; 2,3-Dihydroxybutanedioic acid; L-(+)-Tartaric acid; Tartaric Acid; (+)-Tartaric acid; (R,R)-(+)-Tartaric acid; (R,R)-Tartaric acid; (2R,3R)-Tartaric acid; 2,3-dihydroxy-Butanedioic acid; L(+)-Tartaric acid; L-Tartaric acid; , 2,3-dihydroxy-Succinic acid; Threaric acid; 1,2-Dihydroxyethane- 1,2-dicarboxylic acid; (2R,3R)-(+)-Tartaric acid; (+)-(2R,3R)-Tartaric acid; d-Tartaric acid; Dextrotartaric acid; 3-hydroxy-Malic acid, ; Tartaric acid, (l); 2,3-Dihydrosuccinic acid; Kyselina 2,3-dihydroxybutandiova; Kyselina vinna; cas no: 87-69-4
L MALIC ACID (CAS 97-67-6)
L Malic Acid (Cas 97-67-6), is a naturally occurring carboxylic acid abundantly present in the human body.
L Malic Acid (Cas 97-67-6) is not only found in the human body but also occurs naturally in a wide range of foods.


CAS Number: 97-67-6
EC Number: 202-601-5
MDL number: MFCD00064213
Linear Formula: HO2CCH2CH(OH)CO2H
Molecular Formula: C4H6O5


L Malic Acid (Cas 97-67-6) is one of the popular food additives and ingredients in most countries.
L Malic Acid (Cas 97-67-6) is a metabolite found in or produced by Escherichia coli.
L Malic Acid (Cas 97-67-6) gives many fruits, particularly apples, their characteristic flavor.


L Malic Acid (Cas 97-67-6) is often referred to as “apple acid”.
The word malic is derived from the Latin mālum, for which Malus, the genus that contains all apple species, is also named.
L Malic Acid (Cas 97-67-6), also known as malate or L-apple acid, belongs to the class of organic compounds known as beta hydroxy acids and derivatives.


Beta hydroxy acids and derivatives are compounds containing a carboxylic acid substituted with a hydroxyl group on the C3 carbon atom.
L Malic Acid (Cas 97-67-6) is an extremely weak basic (essentially neutral) compound (based on its pKa).
L Malic Acid (Cas 97-67-6) exists in all eukaryotes, ranging from yeast to humans.


L Malic Acid (Cas 97-67-6), is a naturally occurring carboxylic acid abundantly present in the human body.
L Malic Acid (Cas 97-67-6) is not only found in the human body but also occurs naturally in a wide range of foods.
Moreover, L Malic Acid (Cas 97-67-6) is produced during the fermentation of carbohydrates.


L Malic Acid (Cas 97-67-6) is soluble in acetone, dioxane, water, methanol and ethanol.
L Malic Acid (Cas 97-67-6) is insoluble in benzene
L Malic Acid (Cas 97-67-6) is incompatible with Bases, Oxidizing agents, Reducing agents, Alkali metals .


L Malic Acid (Cas 97-67-6) is the most typical acid occurring in fruits, it contributes to sour tastes.
L Malic Acid (Cas 97-67-6) is commonly used in beverages, confectionary and personal care products.
L Malic Acid (Cas 97-67-6) is a white crystalline powder.


L Malic Acid (Cas 97-67-6) is slightly sour taste.
L Malic Acid (Cas 97-67-6) is soluble in water.
L Malic Acid (Cas 97-67-6) is soluble in water(363g/L).


Keep L Malic Acid (Cas 97-67-6) container tightly closed.
Store L Malic Acid (Cas 97-67-6) away from oxidizing agents.
Store L Malic Acid (Cas 97-67-6) in cool, dry conditions in well sealed containers.


The most common is the L-isomer, L Malic Acid (Cas 97-67-6), present in the juice of immature hawthorn, apple and grape fruits.
L Malic Acid (Cas 97-67-6) can also be produced from fumaric acid through biological fermentation.
L Malic Acid (Cas 97-67-6) is an important intermediate product of the internal circulation of the human body and is easily absorbed by the human body.


L Malic Acid (Cas 97-67-6) is the naturally occurring isomer of malic acid, found mainly in sour and unripe fruits.
L Malic Acid (Cas 97-67-6), also known as malate or L-apple acid, belongs to the class of organic compounds known as beta hydroxy acids and derivatives.
Beta hydroxy acids and derivatives are compounds containing a carboxylic acid substituted with a hydroxyl group on the C3 carbon atom.


L Malic Acid (Cas 97-67-6) exists in all eukaryotes, ranging from yeast to humans.
L Malic Acid (Cas 97-67-6) is registered under the REACH Regulation and is manufactured in and / or imported to the European Economic Area, for intermediate use only.


L Malic Acid (Cas 97-67-6) is a dicarboxylic acid and organic compound made by all living organisms.
L Malic Acid (Cas 97-67-6) belongs to the class of organic compounds known as beta hydroxy acids and derivatives.
Beta hydroxy acids and derivatives are compounds containing a carboxylic acid substituted with a hydroxyl group on the C3 carbon atom.


L Malic Acid (Cas 97-67-6) is nearly odorless (sometimes a faint, acrid odor) with a tart, acidic taste.
L Malic Acid (Cas 97-67-6) is nonpungent.
L Malic Acid (Cas 97-67-6) may be prepared by hydration of maleic acid; by fermentation from sugars.


L Malic Acid (Cas 97-67-6) is an organic acid that is commonly found in wine.
L Malic Acid (Cas 97-67-6) plays an important role in wine microbiological stability.
L Malic Acid (Cas 97-67-6) is an extremely weak basic (essentially neutral) compound (based on its pKa).


Malic Acid (Cas 97-67-6) is an organic compound, and is a dicarboxylic acid that is made by all living organisms, contributes to the pleasantly sour taste of fruits, and is used as a food additive.
Malic Acid (Cas 97-67-6) has two stereoisomeric forms (L- and D-enantiomers), though only the L-isomer exists naturally. The salts and esters of malic acid are known as malates.


The malate anion is an intermediate in the citric acid cycle.
L Malic Acid (Cas 97-67-6) is the naturally occurring and more bioavailable form of Malic Aid.
Malic acid, also known as 2-hydroxysuccinic acid, has two stereoisomers due to an asymmetric carbon atom in the molecule.


In nature, it exists in three forms, namely D-malic acid, L-malic acid and its mixture DL-malic acid.
Malic Acid is white crystal or crystalline powder with strong hygroscopicity, easily soluble in water and ethanol, and has a special pleasant sour taste.
Analytical standard solution for use as a control sample or calibrator with analytical test kits that measure L Malic Acid (Cas 97-67-6).


Especially for use to generate calibration curves for auto-analyser or microplate assay formats with the following enzymatic tests kits: K-LMALAF, K-LMALQR.
L Malic Acid (Cas 97-67-6) is used as a food additive, Selective α-amino protecting reagent for amino acid derivatives. Versatile synthon for the preparation of chiral compounds including κ-opioid receptor agonists, 1α,25-dihydroxyvitamin D3 analogue, and phoslactomycin B.



USES and APPLICATIONS of L MALIC ACID (CAS 97-67-6):
L Malic Acid (Cas 97-67-6) is used as Selective α-amino protecting reagent for amino acid derivatives.
Versatile synthon for the preparation of chiral compounds including κ-opioid rece.
L Malic Acid (Cas 97-67-6) also acts as active ingredient in many sour or tart foods.


L Malic Acid (Cas 97-67-6) is used as synthesizing disincrustant and fluorescent whitening agent.
L Malic Acid (Cas 97-67-6) aids in the production of polyester and alcohol acid resins.
Beyond its biological significance, L Malic Acid (Cas 97-67-6) finds application in diverse industrial sectors.


L Malic Acid (Cas 97-67-6) contributes to the production of plastics, solvents, and detergents.
However, the precise mechanism of action of L Malic Acid (Cas 97-67-6) remains partially understood.
L Malic Acid (Cas 97-67-6) is hypothesized to be involved in ATP production and the transport of electrons within the electron transport chain.


Furthermore, L Malic Acid (Cas 97-67-6) is believed to partake in the metabolism of carbohydrates, fats, and proteins.
In its stable isotope-labeled form, L Malic Acid (Cas 97-67-6) is commonly used as an authentic standard for metabolite quantification.
Unless specified otherwise, MP Biomedical's products are for research or further manufacturing use only, not for direct human use.


L Malic Acid (Cas 97-67-6) is a dicarboxylic acid in naturally occurring form, contributes to the pleasantly sour taste of fruits and is used as a food additive.
L Malic Acid (Cas 97-67-6) is used for resolution of racemates for synthesis.


L Malic Acid (Cas 97-67-6) is an organic dicarboxylic acid that is present in various foods and is metabolized in humans through the Krebs (or citric acid) cycle.
Therefore, as a food additive and functional food with excellent performance, L Malic Acid (Cas 97-67-6) is widely used in food, cosmetics, medical and health care products and other fields.


The racemate can be prepared from fumaric acid or maleic acid under the action of a catalyst under high temperature and pressure conditions and water vapor.
L Malic Acid (Cas 97-67-6) is used to selectively protect the a-amino group of amino acids.
L Malic Acid (Cas 97-67-6) is the starting material for the preparation of chiral compounds.


L Malic Acid (Cas 97-67-6) may be used to prepare:diethyl (S)-malateethyl (R)-2-hydroxyl-4-phenylbutanoateethyl (S)-2-hydroxyl-4-phenylbutanoateD-homophenylalanine ethyl ester hydrochloridefuro[3,2-i]indolizines.
L Malic Acid (Cas 97-67-6) is a relevant component of the citric acid cycle that is found in animals, plants and microorganisms.


L Malic Acid (Cas 97-67-6) is one of the most important fruit acids found in nature and it is the acid present in highest concentrations in wine.
L Malic Acid (Cas 97-67-6) may be used in food production because it is a stronger acid than citric acid.
Microbial decomposition of L Malic Acid (Cas 97-67-6) leads to the formation of L-lactate; this can be a desirable reaction in the wine industry, where the level of L Malic Acid (Cas 97-67-6) is monitored, along with L-lactic acid, during malolactic fermentation.


L Malic Acid (Cas 97-67-6) may be used as a food preservative (E296) or flavour enhancing additive.
L Malic Acid (Cas 97-67-6) is responsible for the sour taste of most fruits and is utilized as a food additive.
Ungraded products supplied by Spectrum are indicative of a grade suitable for general industrial use or research purposes and typically are not suitable for human consumption or therapeutic use.


L Malic Acid (Cas 97-67-6) is used at industrial sites.
L Malic Acid (Cas 97-67-6) is used in the following products: laboratory chemicals and pharmaceuticals.
L Malic Acid (Cas 97-67-6) is used for the manufacture of: chemicals.


Release to the environment of L Malic Acid (Cas 97-67-6) can occur from industrial use: as an intermediate step in further manufacturing of another substance (use of intermediates).
L Malic Acid (Cas 97-67-6) is used as a food additive, Selective α-amino protecting reagent for amino acid derivatives.


Versatile synthon for the preparation of chiral compounds including κ-opioid receptor agonists, 1α,25-dihydroxyvitamin D3 analogue, and phoslactomycin B.
The naturally occuring isomer is the L-form which has been found in apples and many other fruits and plants.
Selective α-amino protecting reagent for amino acid derivatives. Versatile synthon for the preparation of chiral compounds including κ-opioid rece.


L Malic Acid (Cas 97-67-6) is used intermediate in chemical synthesis.
L Malic Acid (Cas 97-67-6) is used chelating and buffering agent.
L Malic Acid (Cas 97-67-6) is used flavoring agent, flavor enhancer and acidulant in foods.


-Food Industry uses of L Malic Acid (Cas 97-67-6):
L Malic Acid (Cas 97-67-6) is an important component of natural fruit juice.
Compared with citric acid, it has higher acidity (20% stronger acidity than citric acid), but soft taste (higher buffer index).

L Malic Acid (Cas 97-67-6) has a special fragrance, does not damage the mouth and teeth, is beneficial to the absorption of amino acids in metabolism, and does not accumulate fat.
L Malic Acid (Cas 97-67-6) is a new generation of food sour agent.
L Malic Acid (Cas 97-67-6) is praised as "the most ideal food sour agent" by the biological and nutritional circles.



ENZYMATIC METHOD FOR THE DETERMINATION OF L MALIC ACID (CAS 97-67-6):
Based on the spectrophotometric measurement of NADH formed through the combined action of L-malate dehydrogenase (L-LDH) and aspartate aminotransferase (AST).
This rapid and simple stereo-specific enzymatic method is used for the determination of L Malic Acid (Cas 97-67-6) (L-malate) in foodstuffs such as wine, beer, bread, fruit and vegetable products, fruit juice, as well as in cosmetics, pharmaceuticals, and biological samples.



ALTERNATIVE PARENTS OF L MALIC ACID (CAS 97-67-6):
*Short-chain hydroxy acids and derivatives
*Fatty acids and conjugates
*Dicarboxylic acids and derivatives
*Alpha hydroxy acids and derivatives
*Secondary alcohols
*Carboxylic acids
*Organic oxides
*Hydrocarbon derivatives
*Carbonyl compounds



SUBSTITUENTS OF L MALIC ACID (CAS 97-67-6):
*Short-chain hydroxy acid
*Beta-hydroxy acid
*Fatty acid
*Dicarboxylic acid or derivatives
*Alpha-hydroxy acid
*Secondary alcohol
*Carboxylic acid
*Carboxylic acid derivative
*Organic oxygen compound
*Organic oxide
*Hydrocarbon derivative
*Organooxygen compound
*Carbonyl group
*Alcohol
*Aliphatic acyclic compound



CHEMICAL PROPERTIES OF L MALIC ACID (CAS 97-67-6):
L Malic Acid (Cas 97-67-6) is nearly odorless (sometimes a faint, acrid odor).
L Malic Acid (Cas 97-67-6) has a tart, acidic, nonpungent taste.
L Malic Acid (Cas 97-67-6) is a clear colourless solution
L Malic Acid (Cas 97-67-6) occurs in maple sap, apple, melon, papaya, beer, grape wine, cocoa, sake, kiwifruit and chicory root.
L Malic Acid (Cas 97-67-6) is an optically active form of malic acid having (S)-configuration.



PREPARATION OF L MALIC ACID (CAS 97-67-6):
L Malic Acid (Cas 97-67-6) can be prepared by hydration of maleic acid; by fermentation from sugar.



BIOCHEM/PHYSIOL ACTIONS OF L MALIC ACID (CAS 97-67-6):
L Malic Acid (Cas 97-67-6) is a part of cellular metabolism.
L Malic Acid (Cas 97-67-6)'s application is recognized in pharmaceutics.
L Malic Acid (Cas 97-67-6) is useful in the treatment of hepatic malfunctioning, effective against hyper-ammonemia.

L Malic Acid (Cas 97-67-6) is used as a part of amino acid infusion.
L Malic Acid (Cas 97-67-6) also serves as a nanomedicine in the treatment of brain neurological disorders.
A TCA (Krebs cycle) intermediate and partner in the malic acid aspartate shuttle.



PURIFICATION METHOD OF L MALIC ACID (CAS 97-67-6):
Crystallise S-malic acid (charcoal) from ethyl acetate/pet ether (b 55-56o), keeping the temperature below 65o.
Or dissolve it by refluxing in fifteen parts of anhydrous diethyl ether, decant, concentrate to one-third volume and crystallise it at 0o, repeatedly to constant melting point.



SUPPORTS HEALTH & WELLNESS OF L MALIC ACID (CAS 97-67-6)::
L Malic Acid (Cas 97-67-6) supports energy production, supports an active lifestyle, and aids in absorption of iron in the body.
Alpha-hydroxy acids are also known to support healthy skin and oral health.



CONVENIENT RESEALABLE POUCH OF L MALIC ACID (CAS 97-67-6)::
Prescribed for Life L Malic Acid (Cas 97-67-6) Powder comes in a durable, resealable pouch.
It’s easy to store and keeps your L Malic Acid (Cas 97-67-6) Powder fresh for maximum long shelf life.



PHYSICAL and CHEMICAL PROPERTIES of L MALIC ACID (CAS 97-67-6):
Molecular Weight: 134.09 g/mol
XLogP3: -1.3
Hydrogen Bond Donor Count: 3
Hydrogen Bond Acceptor Count: 5
Rotatable Bond Count: 3
Exact Mass: 134.02152329 g/mol
Monoisotopic Mass: 134.02152329 g/mol
Topological Polar Surface Area: 94.8Ų
Heavy Atom Count: 9
Formal Charge: 0
Complexity: 129
Isotope Atom Count: 0
Defined Atom Stereocenter Count: 1
Undefined Atom Stereocenter Count: 0
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes
CAS Number: 97-67-6
Molecular Weight: 134.09
Beilstein: 1723541

EC Number: 202-601-5
MDL number: MFCD00064213
CAS Number: 97-67-6
Purity: ≥98%
Molecular Weight: 134.1
Molecular Formula: C4H6O5
Physical state: powder
Color: white
Odor: No data available
Melting point/freezing point:
Melting point/range: 101 - 103 °C - lit.
Initial boiling point and boiling range: No data available
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits: No data available
Flash point: Not applicable
Autoignition temperature: No data available
Decomposition temperature: No data available
pH: No data available
Viscosity
Viscosity, kinematic: No data available
Viscosity, dynamic: No data available
Water solubility: No data available
Partition coefficient: n-octanol/water: No data available

Vapor pressure: No data available
Density: 1,595 g/cm3 at 20 °C
Relative density: No data available
Relative vapor density: No data available
Particle characteristics: No data available
Explosive properties: No data available
Oxidizing properties: none
Other safety information: No data available
CAS number: 97-67-6
EC number: 202-601-5
Hill Formula: C₄H₆O₅
Chemical formula: HOOCCH(OH)CH₂COOH
Molar Mass: 134.08 g/mol
HS Code: 2918 19 98
Boiling point: 140 °C (decomposition)
Density: 1.60 g/cm3 (20 °C)
Melting Point: 98 - 103 °C
pH value: 2.2 (10 g/l, H₂O, 20 °C)
Bulk density: 600 kg/m3
Solubility: 160 g/l
CAS NUMBER: 97-67-6
MOLECULAR FORMULA:C4H6O5
MOLECULAR WEIGHT: 134.1

BEILSTEIN REGISTRY NUMBER: 1723541
EC NUMBER: 202-601-5
MDL NUMBER: MFCD00064213
CAS #: 97-67-6
EC Number: 202-601-5
Grade: Cell Culture Grade
Hazard Statements: H315-H319-H335
Melting Point: 101-103 °C(lit.)
Molecular Formula: C4H6O5
Molecular Weight: 134.1
CAS: 97-67-6
Molecular Formula: C4H6O5
Molecular Weight (g/mol): 134.087
MDL Number: MFCD00064213
InChI Key: BJEPYKJPYRNKOW-REOHCLBHSA-N
PubChem CID: 222656
ChEBI: CHEBI:30797
IUPAC Name: (2S)-2-hydroxybutanedioic acid
SMILES: C(C(C(=O)O)O)C(=O)O
Melting Point: 100°C to 106°C
Color: White
Density: 1.6
Flash Point: 220°C (428°F)

Beilstein: 1723541
Merck Index: 14,5707
Solubility Information: Soluble in water(363g/L).
Optical Rotation: −26° (c=5.5 in pyridine)
Formula Weight: 134.09
Percent Purity: 99%
Physical Form: Crystalline Powder
Chemical Name or Material: L-(-)-Malic acid
Density: 1.6±0.1 g/cm3
Boiling Point: 306.4±27.0 °C at 760 mmHg
Melting Point: 101-103 °C(lit.)
Molecular Formula: C4H6O5
Molecular Weight: 134.087
Flash Point: 153.4±20.2 °C
Exact Mass: 134.021530
PSA: 94.83000
LogP: -1.26
Vapour Pressure: 0.0±1.5 mmHg at 25°C
Index of Refraction: 1.529
Water Solubility: soluble
Molecular Formula / Molecular Weight: C4H6O5 = 134.09
Physical State (20 deg.C): Solid
Store Under Inert Gas: Store under inert gas

Condition to Avoid: Air Sensitive
CAS RN: 97-67-6
Reaxys Registry Number: 1723541
PubChem Substance ID: 87572140
SDBS (AIST Spectral DB): 1069
Merck Index (14): 5707
MDL Number: MFCD00064213
CAS number: 97-67-6
Weight Average: 134.0874
Monoisotopic: 134.021523302
InChI Key: BJEPYKJPYRNKOW-REOHCLBHSA-N
InChI: InChI=1S/C4H6O5/c5-2(4(8)9)1-3(6)7/h2,5H,1H2,(H,6,7)(H,8,9)/t2-/m0/s1
IUPAC Name: (2S)-2-hydroxybutanedioic acid
Traditional IUPAC Name: (-)-malic acid
Chemical Formula: C4H6O5
SMILES: O[C@@H](CC(O)=O)C(O)=O
Water Solubility: 218 g/L
logP: -0.87
logP: -1.1
logS: 0.21
pKa (Strongest Acidic): 3.2
pKa (Strongest Basic): -3.9
Physiological Charge: -2
Hydrogen Acceptor Count: 5
Hydrogen Donor Count: 3
Polar Surface Area: 94.83 Ų

Rotatable Bond Count: 3
Refractivity: 24.88 m³·mol⁻¹
Polarizability: 10.93 ų
Number of Rings: 0
Bioavailability: Yes
Rule of Five: Yes
Ghose Filter: No
Veber's Rule: No
MDDR-like Rule: No
Chemical Formula: C4H6O5
IUPAC name: (2S)-2-hydroxybutanedioic acid
InChI Identifier: InChI=1S/C4H6O5/c5-2(4(8)9)1-3(6)7/h2,5H,1H2,(H,6,7)(H,8,9)/t2-/m0/s1
InChI Key: BJEPYKJPYRNKOW-REOHCLBHSA-N
Isomeric SMILES: O[C@@H](CC(O)=O)C(O)=O
Average Molecular Weight: 134.0874
Monoisotopic Molecular Weight: 134.021523302
Melting point : 101-103 °C (lit.)
alpha: -2 º (c=8.5, H2O)
Boiling point : 167.16°C (rough estimate)
density: 1.60
vapor pressure: 0 Pa at 25℃
FEMA: 2655 | L-MALIC ACID
refractive index: -6.5 ° (C=10, Acetone)

Fp : 220 °C
storage temp.: Store below +30°C.
solubility: H2O: 0.5 M at 20 °C, clear, colorless
form: Powder
color: White
Specific Gravity: 1.595 (20/4℃)
Odor: odorless
PH: 2.2 (10g/l, H2O, 20℃)
pka: (1) 3.46, (2) 5.10(at 25℃)
Odor Type: odorless
optical activity: [α]20/D 30±2°, c = 5.5% in pyridine
Water Solubility: soluble
Merck: 14,5707
JECFA Number: 619
BRN: 1723541
InChIKey: BJEPYKJPYRNKOW-REOHCLBHSA-N
LogP: -1.68
CAS DataBase Reference: 97-67-6(CAS DataBase Reference)
NIST Chemistry Reference: Butanedioic acid, hydroxy-, (s)-(97-67-6)
EPA Substance Registry System: Butanedioic acid, 2-hydroxy-, (2S)- (97-67-6)



FIRST AID MEASURES of L MALIC ACID (CAS 97-67-6):
-Description of first-aid measures:
*General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of L MALIC ACID (CAS 97-67-6):
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up dry.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of L MALIC ACID (CAS 97-67-6):
-Extinguishing media:
*Suitable extinguishing media:
Water
Foam
Carbon dioxide (CO2)
Dry powder
*Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of L MALIC ACID (CAS 97-67-6):
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection
Safety glasses
*Skin protection:
Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
Splash contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
*Body Protection:
protective clothing
*Respiratory protection:
Recommended Filter type: Filter type P2
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of L MALIC ACID (CAS 97-67-6):
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.
Dry.



STABILITY and REACTIVITY of L MALIC ACID (CAS 97-67-6):
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
no information available
-Incompatible materials:
No data available



SYNONYMS:
97-67-6
L-Malic acid
L-(-)-Malic acid
(S)-2-hydroxysuccinic acid
(2S)-2-Hydroxybutanedioic acid
(S)-Malic acid
L(-)-Malic acid
(-)-Malic acid
L-Apple acid
Apple acid
(-)-Hydroxysuccinic acid
L-malate
S-(-)-Malic acid
L-Hydroxybutanedioic acid
S-2-Hydroxybutanedioic acid
Butanedioic acid, hydroxy-, (2S)-
Malic acid, L-
L-2-Hydroxybutanedioic acid
(S)-(-)-Hydroxysuccinic acid
CHEBI:30797
(-)-L-Malic acid
(S)-malate
Malic acid L-(-)-form
Hydroxysuccinnic acid (-)
L-Hydroxysuccinic acid
J3TZF807X5
CHEMBL1234046
NSC9232
NSC-9232
MFCD00064213
NSC 9232
Butanedioic acid, 2-hydroxy-, (2S)-
(S)-Hydroxybutanedioic acid
MALATE ION
(-)-(S)-Malic acid
Hydroxybutanedioic acid, (-)-
UNII-J3TZF807X5
malic-acid
Hydroxybutanedioic acid, (S)-
2yfa
4elc
4ipi
4ipj
L-Maleic Acid
L-Hydroxysuccinate
2-Hydroxybutanedioic acid, (S)-
(S)-(-)-2-Hydroxysuccinic acid
(2s)-malic acid
EINECS 202-601-5
L-Hydroxybutanedioate
nchembio867-comp7
L-(-) malic acid
(-)-Hydroxysuccinate
L-(-)-Apple Acid
S-(-)-Malate
(S)-Hydroxybutanedioate
S-2-Hydroxybutanedioate
(-)-(S)-Malate
(S)-(-)-malic acid
(S)-hydroxy-Butanedioate
(S)-Hydroxysuccinic acid
L(-)MALIC ACID
(S)-2-hydroxysuccinicacid
bmse000238
MALIC ACID [HSDB]
MALIC ACID, (L)
(S)-(-)-Hydroxysuccinate
L-MALIC ACID [FHFI]
(S)-hydroxy-Butanedioic acid
SCHEMBL256122
L-MALIC ACID [WHO-DD]
MALIC ACID, L- [II]
(-)-(s)-hydroxybutanedioic acid
DTXSID30273987
BJEPYKJPYRNKOW-REOHCLBHSA-N
(2S)-(-)-hydroxybutanedioic acid
AMY40197
HY-Y1069
BDBM50510127
s6292
AKOS006346693
CS-W020132
MALIC ACID L-(-)-FORM [MI]
L-(-)-Malic acid, BioXtra, >=95%
AS-18628
L-(-)-Malic acid, >=95% (titration)
(S)-E 296
(-)-1-Hydroxy-1,2-ethanedicarboxylic acid
M0022
EN300-93424
C00149
L-(-)-Malic acid, purum, >=99.0% (T)
L-(-)-Malic acid, ReagentPlus(R), >=99%
M-0850
35F9ECA9-BBE6-463D-BF3F-275FACC5D14E
L-(-)-Malic acid, SAJ special grade, >=99.0%
L-(-)-Malic acid, Vetec(TM) reagent grade, 97%
Q27104150
Z1201618618
(S)-(-)-2-Hydroxysuccinic acid, L-Hydroxybutanedioic acid
L-(-)-Malic acid, 97%, optical purity ee: 99% (GLC)
L-(-)-Malic acid, certified reference material, TraceCERT(R)
L-(-)-Malic acid, BioReagent, suitable for cell culture, suitable for insect cell culture
26999-59-7
(S)-(−)-2-Hydroxysuccinic acid
L-Hydroxybutanedioic acid
(2S)-2-Hydroxybutanedioic acid
l-Malic acid
Apple acid
(-)-Malic acid
L-Hydroxysuccinic acid
(S)-(-)-2-Hydroxysuccinic acid
L-Hydroxybutanedioic acid
l-malic acid, l---malic acid
s-2-hydroxysuccinic acid
2s-2-hydroxybutanedioic acid
l--malic acid, apple acid
--malic acid
l-apple acid
s-malic acid
s-2-hydroxybutanedioic acid
(S)-Hydroxybutanedioic Acid
L-Hydroxysuccinic Acid
(-)-(S)-Malate
(-)-(S)-Malic acid
(-)-Hydroxysuccinate
(-)-Hydroxysuccinic acid
(-)-L-Malic acid
(-)-Malic acid
(2S)-2-Hydroxybutanedioate
(2S)-2-Hydroxybutanedioic acid
(S)-(-)-Hydroxysuccinate
(S)-(-)-Hydroxysuccinic acid
(S)-hydroxy-Butanedioate
(S)-hydroxy-Butanedioic acid
(S)-Hydroxybutanedioate
(S)-Hydroxybutanedioic acid
(s)-malate
Apple acid
Butanedioic acid, hydroxy-, (S)-
L-(-)-Malic acid
l-2-hydroxybutanedioic acid
l-apple acid
L-Hydroxybutanedioate
L-Hydroxybutanedioic acid
L-Hydroxysuccinate
L-Hydroxysuccinic acid
L-Malate
L-malic acid
malate
Malic acid
MLT
S-(-)-Malate
S-(-)-Malic acid
S-2-Hydroxybutanedioate
S-2-Hydroxybutanedioic acid
(-)-L-Malate
L-2-Hydroxybutanedioate
(S)-Malic acid
(2S)-2-Hydroxysuccinic acid
(2S)-Malic acid
(S)-2-Hydroxysuccinic acid
2-Hydroxybutanedioic acid
2-Hydroxyethane-1,2-dicarboxylic acid
2-Hydroxysuccinic acid
Deoxytetraric acid
Hydroxybutanedioic acid
Hydroxysuccinic acid
Monohydroxybutanedioic acid
alpha-Hydroxysuccinic acid
α-Hydroxysuccinic acid
(+-)-1-Hydroxy-1,2-ethanedicarboxylic acid
(+-)-hydroxysuccinic acid
(+-)-malic acid biospider
(+/-)-2-Hydroxysuccinic acid
(-)-(S)-Malate
(-)-(S)-Malic acid
(-)-Hydroxysuccinate
(-)-Hydroxysuccinic acid
(-)-L-Malate Generator
(-)-L-Malic acid
L-(-)-Malic acid, CP
Butanedioic acid, 2-hydroxy-, (2S)-
pinguosuan
Butanedioicacid,hydroxy-,(S)-
hydroxy-,(S)-Butanedioicacid
l-(ii)-malicacid
L-Gydroxybutanedioicacid
L-Mailcacid


L TARTARIC ACID
L Tartaric Acid

CAS No: 144814-09-5, 87-69-4, 133-37-9
EC No: 201-766-0
Molecular Formula: C4H6O6
Molecular Weight: 150.086 g/mol



APPLICATIONS


L Tartaric Acid is used to give a sour taste.
Furthermore, L Tartaric Acid is a good antioxidant.
L Tartaric Acid is the most common area for making soda.

L Tartaric Acid can be used to polish, polish and protect metals.
Oven products are used by releasing carbon dioxide.

Gelatinous desserts are preferred as thickeners in products such as L Tartaric Acid, meringue, lokum and cream whipped cream.
L Tartaric Acid obtained from grapes is highly preferred in useful pasta production.
For embossing of macaroni, L Tartaric Acid maembossed gravy instead.

The production of L Tartaric Acid wine, which has a low density, a piquant and strong taste, is preferred for fermentation of wine
L Tartaric Acid is used for making marmalade and jams.

There are several methods for the production of L Tartaric Acid.
A few of them are as follows:

Besides, L Tartaric Acid can form from the chemical reaction between Calcium Tartrate and an aqueous sulfuric acid solution.
CaC4H4O6 + H2SO4 & gt; H2C4H4O6 + CaSO4

L Tartaric Acid produced by this reaction is the only additive chemistry used to regulate acidity in the production of wines.
The major chemical substances and components used in the production of L Tartaric Acid are water, sulfuric acid and calcium.

Moreover, L Tartaric Acid is used to produce sodium carbonate, as a result of its interaction with sodium bicarbonate, by oral administration this effect of L Tartaric Acid, carbon dioxide prolongs the mast.
L Tartaric Acid is used as an antioxidant to give a sour taste to many food products.

In addition, L Tartaric Acid is used to add the embossing qualities in the food additives that are added to the bakery products.
L Tartaric Acid isused as a preservative additive in foods.
At the same time, L Tartaric Acid gives flavor.

L Tartaric Acid is generally used in the production of carbonated beverages, fruit candies and products in effervescent tablets.
At the same time, L Tartaric Acid is used to polish and clean metals and deeply tannate.
Therefore, we can think that L Tartaric Acid can also be used in sun cream production.

L Tartaric Acid is used in the manufacture of blue inks.
In addition, L Tartaric Acid is used as a component that reacts with Silver Nitrateto give the mirror silver color.
L Tartaric Acid is used for fabric dyeing with ester derivatives.
Additionally, L Tartaric Acid will be useful for performing the process required here.

L Tartaric Acid is used in wine production to preserve the color, chemical stability and taste of finished wine products.
One of the reasons for the use of L Tartaric Acid in wine production is to reduce the pH of the medium and prevent unwanted bacterial growth.
L Tartaric Acid is a useful chemical for the production of chiral molecules in organic chemistry.

When the L Tartaric Acid cream is added to the water, the copper mine forms a very well cleaned suspension.
L Tartaric Acid is used as an aroma in food and beverages.

L Tartaric Acid may be used in the synthesis of (R,R)-1,2-diammoniumcyclohexane mono-(+)-tartrate, an intermediate to prepare an enantioselective epoxidation catalyst.
More to that, L Tartaric Acid may also be used as a starting material in the multi-step synthesis of 1,4-di-O-benzyl-L-threitol.

L Tartaric Acid can be used a chiral resolving agent for the resolution of 2,2′-bispyrrolidine.
Further to that, L Tartaric Acid is chiral building block for natural products.
L Tartaric Acid also forms a Diels-Alder catalyst with TiCl2(O-i-Pr)2.


Industrial uses of L Tartaric Acid:

Food Industry:

Acidifiers and natural preservatives for jams, ice creams, jams, juices, jams and beverages
Foamer for carbonated water
In bread making sector like emulsifier and preservative; in preparing candies and sweets


Wine Industry:

L Tartaric Acid is used as an acidifier.
Furthermore, L Tartaric Acid provides an increase in acidity and a decrease in pH content, which is necessary to prepare more balanced wines interms of taste and used in wines.


Pharmaceutical Industry:

Melt in water is used as an additive for the preparation of tablets.


Building Sector:

L Tartaric Acid delays the operation and facilitates the processing of these materials. (Also used in Cement and Plaster)


Cosmetic Industry:

L Tartaric Acid is used as a basic component in many natural body creams.


Chemical Sector:

Galvanic bathrooms


Electronics industry:

Color stabilizer like the textile industry
Industrial grease as anti-oxidant


Uses of L Tartaric Acid:

Multi-component crafting kits where individual products are not designated
Products related to pottery making which can not be assigned to a more refined category
Products specifically used in a laboratory setting, e.g. laboratory diagnostics or consumables, solvents and reagents used in experiments or laboratory tests, etc. Includes supplies for medical testing. Note that pure chemicals will be included in the 'Raw materials' category.
Medical and dental supplies and equipment, e.g. medical equipment used in a hospital or doctor's office setting, at home (e.g. wheelchairs, colostomy bag). Includes clothing and personal protective equipment used in medical settings (e.g. scrubs, face masks, gowns, gloves); excludes medical testing supplies.
Fragrances, colognes, and perfumes
General hair styling or hair care products which do not fit into a more refined category
Lip products primarily for protection
Colored lip products, excluding glosses
Miscellaneous aquarium products for the maintenance of aquatic pets
rinse aid
surfactant
ph regulating agent
processing aids and additives


L Tartaric Acid is found throughout nature and classified as a fruit acid.
Moreover, L Tartaric Acid is used in soft drinks and foods, as an acidulant, complexing agent, pharmaceutic aid (buffering agent), in photography, tanning, ceramics, and to make tartrates.

Diethyl and dibutyl ester derivatives are commercially significant for use in lacquers and in textile printing.
L Tartaric Acid is used as an intermediate, in construction and ceramics applications, in cleaning products, cosmetics/personal care products, and metal surface treatments (including galvanic and electroplating products).

Besides, L Tartaric Acid is used as a flavoring agent, anticaking agent, drying agent, firming agent, humectant, leavening agent, and pH control agent for foods.
L Tartaric Acid is permitted for use as an inert ingredient in non-food pesticide products.



DESCRIPTION


L Tartaric Acid is a white, crystalline organic acid that occurs naturally in many fruits, most notably in grapes, but also in bananas, tamarinds, and citrus.
Its salt, potassium bitartrate, commonly known as cream of tartar, develops naturally in the process of fermentation.
L Tartaric Acid is commonly mixed with sodium bicarbonate and is sold as baking powder used as a leavening agent in food preparation.

L Tartaric Acid itself is added to foods as an antioxidant E334 and to impart its distinctive sour taste.
Naturally occurring L Tartaric Acid is a useful raw material in organic chemical synthesis.
L Tartaric Acid is an alpha-hydroxy-carboxylic acid, is diprotic and aldaric in acid characteristics, and is a dihydroxyl derivative of succinic acid.

L Tartaric Acid, a crystalline acid, is commonly found in plants and fruits.
In addition, L Tartaric Acid is white in color and crystalline.
L Tartaric Acid is a succinic acid is a dihydroxyl derivative.

Additionally, L Tartaric Acid has polarizing power.
L Tartaric Acid is an acidic potassium salt, which is derived from fermented grape juice.

L Tartaric Acid is designated as natural tartaric acid.
Natural Tartaric is a product of nature.
L Tartaric acid, i.e., natural tartaric acid, is obtained as by-products of wine making after obtaining alcoholic products.

More to that, L Tartaric acid should not be mixed with synthetic tartaric acid, starting from synthetic maleic acid.
L Tartaric Acid crystallizer is applied in two stages.

L Tartaric Acid has 2 purity.
The raw crystal of L (+) Tartaric Acid, i.acid, is re-dissolved and subsequently converted back into crystalline structure.
L Tartaric acid produced in this manner, i.eacid, abolishes the process residues in the application phase.

Further to that, L Tartaric Acid acid has a white crystalline residue.
Sometimes the crystalline powder can also be in structure.
The tartaric acid melting point is 206 [deg.] C.

L Tartaric Acid is a chemical that works by inhibiting the production of malic acid.
In this process, a person is exposed to tartaricdoses, resulting in Toxic accumulation in the muscles.
The high dose of L Tartaric Acid can cause paralysis and death as a result.

L Tartaric Acid prices continue to drive up prices due to increased wine consumption.
The price of L Tartaric Acid also increases the demand for L Tartaric Acid by increasing the popularity of packaged food products.
Therefore, the price of L Tartaric Acid is also increasing.
The price of L Tartaric Acid is increasing due to its use as an emulsifier in bread production.

L Tartaric Acid (E 334); crystalline, colorless organic acid commonly found in plants.
This acid which is used in various industrial branches, especially in the food industry, is obtained as a by-product of potassium during the fermentation of the wine.
L Tartaric Acid is first separated from this mixture by Carl Wilhem Scheele.

The wastes generated in the wine production are neutralized with potassium hydroxide.
L Tartaric Acid is formed by processing calcium tartar with sulfuric acid in the flour.

L Tartaric Acid is used in soda, gelatinous desserts, cleaning and polishing of metals and wool painting.
Antimony potassium tartar is also used asan insecticide and mordant.
L Tartaric Acid accounts for 1.6-2.8% of total acid in grape fruits.



PROPERTIES



Melting point: 170-172 °C(lit.)
alpha: 12 º (c=20, H2O)
Boiling point: 191.59°C (rough estimate)
Density: 1.76
vapor density: 5.18 (vs air)
vapor pressure: refractive index: 12.5 ° (C=5, H2O)
Flash point: 210 °C
storage temp.: Store at +5°C to +30°C.
solubility:
H2O: soluble1M at 20°C, clear, colorless
form : Solid
pka: 2.98, 4.34(at 25℃)
color: White or colorless
PH: 3.18(1 mM solution);2.55(10 mM solution);2.01(100 mM solution);
Optical activity: [α]20/D +13.5±0.5°, c = 10% in H2O
Water Solubility: 1390 g/L (20 ºC)
Merck: 14,9070
JECFA Number: 621
BRN: 1725147
Stability: Stable. Incompatible with oxidizing agents, bases, reducing agents. Combustible.



FIRST AID


First-aid measures general:

Never give anything by mouth to an unconscious person.
If you feel unwell, seek medical advice (show the label where possible).


First-aid measures after inhalation:

Allow victim to breathe fresh air.
Allow the victim to rest.


First-aid measures after skin contact:

Remove affected clothing and wash all exposed skin area with mild soap and water, followed by warm water rinse.


First-aid measures after eye contact:

Rinse cautiously with water for several minutes.
Remove contact lenses, if present and easy to do.
Continue rinsing.
Immediately call a poison center or doctor/physician.


First-aid measures after ingestion:

Rinse mouth.
Do NOT induce vomiting.
Obtain emergency medical attention.



HANDLING AND STORAGE


L Tartaric Acid should not be stored in areas directly exposed to sunlight.
Furthermore, L Tartaric Acid appears to be converted to glyoxylic acidin areas exposed to sunlight.

L Tartaric Acid will react with each other to produce hydrogen peroxide and glyoxylic acid formic aunder these conditions.
Therefore, L Tartaric Acid is not stable.
Moreover, L Tartaric Acid is packed in paper bags of 25 kg, 500 kg and 1500 kg.


Precautions for safe handling:

Wash hands and other exposed areas with mild soap and water before eating, drinking or smoking and when leaving work.
Provide good ventilation in process area to prevent formation of vapor.


Hygiene measures:

Wash exposed skin thoroughly after handling.


Conditions for safe storage, including any incompatibilities:

Storage conditions:

Keep container closed when not in use.


Incompatible products:

Strong bases.
Strong oxidizers.


Incompatible materials:

Sources of ignition.
Direct sunlight.



SYNONYMS


87-69-4;L-tartaric acid
L-(+)-Tartaric acid
L(+)-Tartaric acid
(2R,3R)-2,3-dihydroxysuccinic acid
tartaric acid
(+)-L-Tartaric acid
(2Rdihydroxybutanedioic acid
(R,R)-Tartaric acid
Dextrotartaric acid
L-threaric acid
(+)-(R,R)-Tartaric acid
(+)-Tartaric acid
(2R,3R)-(acid;Tartaric acid (VAN)
Threaric acid
Kyselina vinna [Czech]
Acidum tartaricum
Tartaric acid [USAN:JAN]
Tartaric acid, L-
Succidihydroxy
UNII-W4888I119H
d-alpha,beta-Dihydroxysuccinic acid
Butanedioic acid, 2,3-dihydroxy- (2R,3R)-
EINECS 201-766-0
Ntartaric acid
Kyselina 2,3-dihydroxybutandiova [Czech]
(2R,3R)-rel-2,3-Dihydroxysuccinic acid
AI3-06298
(+)-L-Tartaric acid
(+)-Tartaric acid
87-69-4
L-(+)-Tartaric acid
L-Tartaric acid
L(+)-Tartaric acid
tartaric acid
(2R,3R)-2,3-dihydroxysuccinic acid
(2R,3R)-2,3-dihydroxybutanedioic acid
(R,R)-Tartaric acid
Threaric acid
L-threaric acid
Dextrotartaric acid
DL-Tartaric acid
Natural tartaric acid
(2R,3R)-(+)-Tartaric acid
(+)-(R,R)-Tartaric acid
Tartaric acid, L-
Rechtsweinsaeure
(2R,3R)-Tartaric acid
(2R,3R)-rel-2,3-Dihydroxysuccinic acid
tartrate
(R,R)-(+)-Tartaric acid
FEMA No. 3044
133-37-9
Lamb protein (fungal)
Butanedioic acid, 2,3-dihydroxy- (2R,3R)-
(R,R)-tartrate
Tartaric acid (VAN)
Kyselina vinna [Czech]
INS NO.334
Uvic acid
CHEBI:15671
(+)-(2R,3R)-Tartaric acid
INS-334
Tartaric acid [USAN:JAN]
Weinsaeure
MFCD00064207
NSC-62778
L-tartarate
4J4Z8788N8
W4888I119H
138508-61-9
Butanedioic acid, 2,3-dihydroxy-, (2R,3R)-rel-
1,2-Dihydroxyethane-1,2-dicarboxylic acid
Resolvable tartaric acid
d-alpha,beta-Dihydroxysuccinic acid
E 334
E-334
L-(+)-tartrate
144814-09-5
Kyselina 2,3-dihydroxybutandiova [Czech]
AI3-06298
(1R,2R)-1,2-Dihydroxyethane-1,2-dicarboxylic acid
2, 3-Dihydroxybutanedioic Acid
Butanedioic acid, 2,3-dihydroxy- (2R,3R)-, homopolymer
Kyselina vinna
Tartaric acid D,L
Butanedioic acid, 2,3-dihydroxy- (R-(R*,R*))-
Tartarate
132517-61-4
(+/-)-Tartaric Acid
Succinic acid, 2,3-dihydroxy
L(+) tartaric acid
L-2,3-Dihydroxybutanedioic acid
(2RS,3RS)-Tartaric acid
EINECS 201-766-0
NSC 62778
Weinsteinsaeure
Weinsaure
tartaric-acid
L-Threaric aci
UNII-W4888I119H
Kyselina 2,3-dihydroxybutandiova
4ebt
NSC 148314
NSC-148314
(r,r)-tartarate
(2R,3R)-2,3-Dihydroxybernsteinsaeure
(+)-tartarate
(+)-Weinsaeure
l(+)tartaric acid
Tartaric acid; L-(+)-Tartaric acid
Tartaric acid (TN)
(+-)-Tartaric acid
Butanedioic acid, 2,3-dihydroxy-, (R*,R*)-
L-(+) tartaric acid
(2R,3R)-Tartarate
1d5r
DL TARTARIC ACID
TARTARICUM ACIDUM
2,3-dihydroxy-succinate
TARTARIC ACID,DL-
DSSTox_CID_3632
EC 201-766-0
SCHEMBL5762
TARTARIC ACID [II]
TARTARIC ACID, DL-
DSSTox_RID_77120
Tartaric acid (JP17/NF)
TARTARIC ACID [FCC]
TARTARIC ACID [JAN]
d-a,b-Dihydroxysuccinic acid
DSSTox_GSID_23632
TARTARIC ACID [INCI]
MLS001336057
L-TARTARIC ACID [MI]
TARTARIC ACID [VANDF]
DL-TARTARIC ACID [MI]
TARTARIC ACID [MART.]
CCRIS 8978
L-(+)-Tartaric acid, ACS
TARTARIC ACID [USP-RS]
TARTARIC ACID [WHO-DD]
CHEMBL1236315
DTXSID8023632
L-(+)-Tartaric acid, BioXtra
TARTARICUM ACIDUM [HPUS]
UNII-4J4Z8788N8
(2R,3R)-2,3-tartaric acid
TARTARIC ACID (L(+)-)
HMS2270G22
Pharmakon1600-01300044
TARTARIC ACID, DL- [II]
ZINC895301
TARTARIC ACID, (+/-)-
TARTARIC ACID,DL- [VANDF]
HY-Y0293
STR02377
TARTARIC ACID [ORANGE BOOK]
BAROS COMPONENT TARTARIC ACID
EINECS 205-105-7
Tox21_300155
(2R,3R)-2,3-dihydroxysuccinicacid
NSC759609
s6233
TARTARIC ACID [EP MONOGRAPH]
L-2,3-DIHYDROXYSUCCINIC ACID
AKOS016843282
L-(+)-Tartaric acid, >=99.5%
CS-W020107
DB09459
NSC-759609
(2R,3R)-2,3-dihydroxy-succinic acid
Butanedioic acid, 2,3-dihydroxy-; Butanedioic acid, 2,3-dihydroxy-, (R-(R*,R*))-
CAS-87-69-4
L-(+)-Tartaric acid, AR, >=99%
TARTARIC ACID COMPONENT OF BAROS
NCGC00247911-01
NCGC00254043-01
BP-31012
SMR000112492
SBI-0207063.P001
T0025
EN300-72271
C00898
D00103
D70248
L-(+)-Tartaric acid, >=99.7%, FCC, FG
L-(+)-Tartaric acid, ACS reagent, >=99.5%
L-(+)-Tartaric acid, BioUltra, >=99.5% (T)
J-500964
J-520420
L-(+)-Tartaric acid, ReagentPlus(R), >=99.5%
L-(+)-Tartaric acid, SAJ first grade, >=99.5%
L-(+)-Tartaric acid, tested according to Ph.Eur.
REL-(2R,3R)-2,3-DIHYDROXYBUTANEDIOIC ACID
Butanedioic acid, 2,3-dihydroxy-, (R*,R*)-(+-)-
L-(+)-Tartaric acid, JIS special grade, >=99.5%
L-(+)-Tartaric acid, natural, >=99.7%, FCC, FG
L-(+)-Tartaric acid, p.a., ACS reagent, 99.0%
L-(+)-Tartaric acid, Vetec(TM) reagent grade, 99%
Q18226455
F8880-9012
Z1147451717
BUTANEDIOIC ACID, 2,3-DIHYDROXY-, (R-(R*,R*))-
Butanedioic acid, 2,3-dihydroxy-, (theta,theta)-(+-)-
000189E3-11D0-4B0A-8C7B-31E02A48A51F
L-(+)-Tartaric acid, puriss. p.a., ACS reagent, >=99.5%
L-(+)-Tartaric acid, certified reference material, TraceCERT(R)
Tartaric acid, United States Pharmacopeia (USP) Reference Standard
L-(+)-Tartaric acid, anhydrous, free-flowing, Redi-Dri(TM), ACS reagent, >=99.5%
L-(+)-Tartaric acid, p.a., ACS reagent, reag. ISO, reag. Ph. Eur., 99.5%
Tartaric Acid, Pharmaceutical Secondary Standard; Certified Reference Material
L-(+)-Tartaric acid, puriss. p.a., reag. ISO, reag. Ph. Eur., 99.5-101.0% (calc. to the dried substance)
L-(+)-Tartaric acid, puriss., meets analytical specification of Ph. Eur., BP, NF, FCC, E334, 99.7-100.5% (calc. to the dried substance), grit
L-(+)-Tartaric acid, puriss., meets analytical specification of Ph. Eur., NF, 99.7-100.5% (calc. to the dried substance), powder
L TARTARIC ACID
LABSA; Dodecylbenzene Sulfonic Acid (Strait Chain); LAS; Laurylbenzenesulfonic Acid; Laurylbenzenesulfonate; n-Dodecylbenzene Sulfonic Acid; Alkylbenzene sulphonate, sodium salt; Linear Alkylbenzene Sulphonic Acid; Dodecylbenzolsulfonsäure (German); ácido dodecilbenceno sulfónico (Spanish); Acide dodécylbenzènesulfonique; cas no: 27176-87-0
L-(-)-MALIC ACID
L-(-)-Malic acid is a dicarboxylic acid that is commonly found in fruits, particularly in apples, and is responsible for their sour taste.
L-(-)-Malic acid is nearly odorless (sometimes a faint, acrid odor) with a tart, acidic taste.
L-(-)-Malic acid is nonpungent. May be prepared by hydration of maleic acid; by fermentation from sugars.

CAS Number: 97-67-6
Molecular Formula: C4H6O5
Molecular Weight: 134.09
EINECS Number: 202-601-5

Synonyms: 97-67-6, L-Malic acid, L-(-)-Malic acid, (S)-2-hydroxysuccinic acid, (2S)-2-Hydroxybutanedioic acid, (S)-Malic acid, L(-)-Malic acid, (-)-Malic acid, L-Apple acid, L-Hydroxybutanedioic acid, Apple acid, (-)-Hydroxysuccinic acid, L-malate, S-(-)-Malic acid, S-2-Hydroxybutanedioic acid, Butanedioic acid, hydroxy-, (2S)-, Malic acid, L-, L-2-Hydroxybutanedioic acid, CHEBI:30797, (-)-L-Malic acid, (S)-malate, MFCD00064213, Malic acid L-(-)-form, Hydroxysuccinnic acid (-), L-Hydroxysuccinic acid, J3TZF807X5, (S)-(-)-Hydroxysuccinic acid, CHEMBL1234046, NSC9232, (S)-(-)-2-Hydroxysuccinic acid, NSC-9232, NSC 9232, Butanedioic acid, 2-hydroxy-, (2S)-, (S)-Hydroxybutanedioic acid, (-)-(S)-Malic acid, Hydroxybutanedioic acid, (-)-, UNII-J3TZF807X5, malic-acid, Hydroxybutanedioic acid, (S)-, 2yfa, 4elc, 4ipi, 4ipj, L-Hydroxysuccinate, 2-Hydroxybutanedioic acid, (S)-, (2s)-malic acid, EINECS 202-601-5, L-Hydroxybutanedioate, nchembio867-comp7, L-(-) malic acid, (-)-Hydroxysuccinate, L-(-)-Apple Acid, S-(-)-Malate, (S)-Hydroxybutanedioate, S-2-Hydroxybutanedioate, (-)-(S)-Malate, (S)-(-)-malic acid, (S)-hydroxy-Butanedioate, (S)-Hydroxysuccinic acid, L(-)MALIC ACID, (S)-2-hydroxysuccinicacid, bmse000238, MALIC ACID [HSDB], MALIC ACID, (L), (S)-(-)-Hydroxysuccinate, L-MALIC ACID [FHFI], (S)-hydroxy-Butanedioic acid, SCHEMBL256122, L-MALIC ACID [WHO-DD], MALIC ACID, L- [II], (-)-(s)-hydroxybutanedioic acid, DTXSID30273987, (2S)-(-)-hydroxybutanedioic acid, AMY40197, HY-Y1069, BDBM50510127, s6292, AKOS006346693, CS-W020132, MALIC ACID L-(-)-FORM [MI], L-(-)-Malic acid, BioXtra, >=95%, AS-18628, L-(-)-Malic acid, >=95% (titration), (S)-E 296, (-)-1-Hydroxy-1,2-ethanedicarboxylic acid, M0022, NS00068391, EN300-93424, C00149, L-(-)-Malic acid, purum, >=99.0% (T), L-(-)-Malic acid, ReagentPlus(R), >=99%, M-0850, 35F9ECA9-BBE6-463D-BF3F-275FACC5D14E, L-(-)-Malic acid, SAJ special grade, >=99.0%, L-(-)-Malic acid, Vetec(TM) reagent grade, 97%, Q27104150, Z1201618618, (S)-(-)-2-Hydroxysuccinic acid, L-Hydroxybutanedioic acid, L-(-)-Malic acid, 97%, optical purity ee: 99% (GLC), L-(-)-Malic acid, certified reference material, TraceCERT(R), L-(-)-Malic acid, BioReagent, suitable for cell culture, suitable for insect cell culture, 26999-59-7

L-(-)-Malic acid is an organic compound with the molecular formula HO2CCH(OH)CH2CO2H.
L-(-)-Malic acid is a dicarboxylic acid that is made by all living organisms, contributes to the sour taste of fruits, and is used as a food additive.
L-(-)-Malic acid has two stereoisomeric forms (L- and D-enantiomers), though only the L-isomer exists naturally.

The salts and esters of L-(-)-Malic acid are known as malates.
The malate anion is a metabolic intermediate in the citric acid cycle.
L-(-)-Malic acid is a naturally occurring organic compound with the molecular formula C4H6O5.

L-(-)-Malic acid is nearly odorless (sometimes a faint, acrid odor).
L-(-)-Malic acid has a tart, acidic, nonpungent taste.
L-(-)-Malic acid is an organic acid that is commonly found in wine.

L-(-)-Malic acid plays an important role in wine microbiological stability.
L-(-)-Malic acid is a part of cellular metabolism.
Its application is recognized in pharmaceutics.

L-(-)-Malic acid is useful in the treatment of hepatic malfunctioning, effective against hyper-ammonemia.
L-(-)-Malic acid is used as a part of amino acid infusion.
L-(-)-Malic acid also serves as a nanomedicine in the treatment of brain neurological disorders.

L-(-)-Malic acid intermediate and partner in the malic acid aspartate shuttle.
Crystallise L-(-)-Malic acid from ethyl acetate/pet ether (b 55-56o), keeping the temperature below 65o.
Or dissolve it by refluxing in fifteen parts of anhydrous diethyl ether, decant, concentrate to one-third volume and crystallise it at 0o, repeatedly to constant melting point.

L-(-)-Malic acid, a hydroxydicarboxylic acid, is found in all forms of life.
L-(-)-Malic acid exists naturally only as the L-enantiomer.
L-(-)-Malic acid should not be confused with the similar sounding maleic and malonic acids.

L-(-)-Malic acid gives many fruits, particularly apples, their characteristic flavor.
It is often referred to as “apple acid”.
The word malic is derived from the Latin mālum, for which Malus, the genus that contains all apple species, is also named.

The word 'L-(-)-Malic acid' is derived from Latin mālum, meaning 'apple'. The related Latin word mālus, meaning 'apple tree', is used as the name of the genus Malus, which includes all apples and crabapples; and is the origin of other taxonomic classifications such as Maloideae, Malinae, and Maleae.
L-(-)-Malic acid is the naturally occurring form, whereas a mixture of L- and D-malic acid is produced synthetically.

Malate plays an important role in biochemistry.
In the C4 carbon fixation process, malate is a source of CO2 in the Calvin cycle.
In the L-(-)-Malic acid, (S)-malate is an intermediate, formed by the addition of an -OH group on the si face of fumarate.

L-(-)-Malic acid can also be formed from pyruvate via anaplerotic reactions.
L-(-)-Malic acid is also synthesized by the carboxylation of phosphoenolpyruvate in the guard cells of plant leaves.
L-(-)-Malic acid, as a double anion, often accompanies potassium cations during the uptake of solutes into the guard cells in order to maintain electrical balance in the cell.

The accumulation of these solutes within the guard cell decreases the solute potential, allowing water to enter the cell and promote aperture of the stomata.
L-(-)-Malic acid was first isolated from apple juice by Carl Wilhelm Scheele in 1785.
Antoine Lavoisier in 1787 proposed the name acide malique, which is derived from the Latin word for apple, mālum—as is its genus name Malus.

In German it is named Äpfelsäure (or Apfelsäure) after plural or singular of a sour thing from the apple fruit, but the salt(s) are called Malat(e).
L-(-)-Malic acid is the main acid in many fruits, including apricots, blackberries, blueberries, cherries, grapes, mirabelles, peaches, pears, plums, and quince, and is present in lower concentrations in other fruits, such as citrus.
L-(-)-Malic acid contributes to the sourness of unripe apples. Sour apples contain high proportions of the acid.

L-(-)-Malic acid is present in grapes and in most wines with concentrations sometimes as high as 5 g/L.
L-(-)-Malic acid confers a tart taste to wine; the amount decreases with increasing fruit ripeness.
The taste of malic acid is very clear and pure in rhubarb, a plant for which it is the primary flavor.

L-(-)-Malic acid is also the compound responsible for the tart flavor of sumac spice.
L-(-)-Malic acid is also a component of some artificial vinegar flavors, such as "salt and vinegar" flavored potato chips.
L-(-)-Malic acid is produced industrially by the double hydration of maleic anhydride.

In 2000, American production capacity was 5,000 tons per year.
The enantiomers may be separated by chiral resolution of the racemic mixture.
L-(-)-Malic acid is obtained by fermentation of fumaric acid.

Self-condensation of malic acid in the presence of fuming sulfuric acid gives the pyrone coumalic acid: 2 HO2CCH(OH)CH2CO2H → HO2CC4H3O2 + 2 CO + 4 H2O
Carbon monoxide and water are liberated during this reaction.
L-(-)-Malic acid was important in the discovery of the Walden inversion and the Walden cycle, in which (−)-malic acid first is converted into (+)-chlorosuccinic acid by action of phosphorus pentachloride.

Wet silver oxide then converts the chlorine compound to L-(-)-Malic acid, which then reacts with PCl5 to the (−)-chlorosuccinic acid.
The cycle is completed when silver oxide takes this compound back to (−)-malic acid.
L-(-)-Malic acid is used to resolve α-phenylethylamine, a versatile resolving agent in its own right.

L-(-)-Malic acid is also found in plants and animals, including humans.
In fact, L-(-)-Malic acid, in the form of its anion malate, is a key intermediate in the major biochemical energy-producing cycle in cells known as the citric acid or Krebs cycle located in the cells' mitochondria.
L-(-)-Malic acid is used in many food products and is a very popular product in beverages and sweets.

L-(-)-Malic acid, also known as apple acid and hydroxysuccinic acid, is a chiral molecule.
L-(-)-Malic acid contains natural emollient ingredients, which can remove wrinkles on the skin surface, make the skin become tender and white, smooth and elastic, so in the cosmetic formula favored; L-malic acid can be formulated a variety of flavors, spices, for a variety of daily chemical products, such as toothpaste, shampoo, etc; it is used abroad to replace citric acid as a new type of detergent additive for the synthesis of high-grade special detergents.
L-(-)-Malic acid can be used in pharmaceutical preparations, tablets, syrup, can also be mixed into the amino acid solution, can significantly improve the absorption rate of amino acids; L-malic acid can be used for the treatment of liver disease, anemia, low immunity, uremia, hypertension, liver failure and other diseases, and can reduce the toxic effect of anticancer drugs on normal cells; Can also be used for the preparation and synthesis of insect repellents, anti-Tartar agents.

In addition, L-(-)-Malic acid can also be used as industrial cleaning agent, resin curing agent, synthetic material plasticizer, feed additive, etc.
L-(-)-Malic acid is a part of cellular metabolism.
L-(-)-Malic acid's application is recognized in pharmaceutics.

L-(-)-Malic acid is useful in the treatment of hepatic malfunctioning, effective against hyper-ammonemia.
L-(-)-Malic acid is used as a part of amino acid infusion.
L-(-)-Malic acid also serves as a nanomedicine in the treatment of brain neurological disorders.

A TCA (Krebs cycle) intermediate and partner in the L-Malic acid aspartate shuttle.
L-(-)-Malic acid is the naturally occurring form, whereas a mixture of L- and D-malic acid is produced synthetically.
Malate plays an important role in biochemistry.

In the C4 carbon fixation process, malate is a source of CO2 in the Calvin cycle.
In the L-(-)-Malic acid cycle, (S)-malate is an intermediate, formed by the addition of an -OH group on the si face of fumarate.
L-(-)-Malic acid can also be formed from pyruvate via anaplerotic reactions.

L-(-)-Malic acid is also synthesized by the carboxylation of phosphoenolpyruvate in the guard cells of plant leaves.
L-(-)-Malic acid, as a double anion, often accompanies potassium cations during the uptake of solutes into the guard cells in order to maintain electrical balance in the cell.
The accumulation of these solutes within the guard cell decreases the solute potential, allowing water to enter the cell and promote aperture of the stomata.

L-(-)-Malic acid, a four-carbon dicarboxylic acid, is widely used in the food, chemical and medical industries.
As an intermediate of the TCA cycle, L-(-)-Malic acid is one of the most promising building block chemicals that can be produced from renewable sources.
To date, chemical synthesis or enzymatic conversion of petrochemical feedstocks are still the dominant mode for malic acid production.

However, with increasing concerns surrounding environmental issues in recent years, microbial fermentation for the production of L-(-)-Malic acid was extensively explored as an eco-friendly production process.
The rapid development of genetic engineering has resulted in some promising strains suitable for large-scale bio-based production of L-(-)-Malic acid.
This review offers a comprehensive overview of the most recent developments, including a spectrum of wild-type, mutant, laboratory-evolved and metabolically engineered microorganisms for malic acid production.

The technological progress in the fermentative production of L-(-)-Malic acid is presented. Metabolic engineering strategies for malic acid production in various microorganisms are particularly reviewed.
Biosynthetic pathways, transport of malic acid, elimination of byproducts and enhancement of metabolic fluxes are discussed and compared as strategies for improving malic acid production, thus providing insights into the current state of malic acid production, as well as further research directions for more efficient and economical microbial L-(-)-Malic acid production.

Melting point: 101-103 °C (lit.)
alpha: -2 º (c=8.5, H2O)
Boiling point: 167.16°C (rough estimate)
Density: 1.60
vapor pressure: 0Pa at 25℃
FEMA: 2655 | L-MALIC ACID
refractive index: -6.5 ° (C=10, Acetone)
Flash point: 220 °C
storage temp.: Store below +30°C.
solubility: H2O: 0.5 M at 20 °C, clear, colorless
form: Powder
color: White
Specific Gravity: 1.595 (20/4℃)
Odor: odorless
PH: 2.2 (10g/l, H2O, 20℃)
pka: (1) 3.46, (2) 5.10(at 25℃)
Odor Type: odorless
optical activity: [α]20/D 30±2°, c = 5.5% in pyridine
Water Solubility: soluble
Merck: 14,5707
JECFA Number: 619
BRN: 1723541
InChIKey: BJEPYKJPYRNKOW-REOHCLBHSA-N
LogP: -1.68

L-(-)-Malic acid is used as Selective α-amino protecting reagent for amino acid derivatives.
Versatile synthon for the preparation of chiral compounds including κ-opioid rece.
L-(-)-Malic acid also acts as active ingredient in many sour or tart foods.

L-(-)-Malic acid is used as synthesizing disincrustant and fluorescent whitening agent.
L-(-)-Malic acid aids in the production of polyester and alcohol acid resins.
L-(-)-Malic acid is an organic acid that is commonly found in wine.

L-(-)-Malic acid plays an important role in wine microbiological stability.
L-(-)-Malic acid has a chemical structure where a hydroxyl group (-OH) is attached to the second carbon of butanedioic acid, with the L-configuration indicating its specific stereochemistry.
The "L-(-)" notation indicates that it is the levorotatory (left-rotating) isomer of malic acid, which means it rotates plane-polarized light to the left.

In biology, L-(-)-Malic acid plays a crucial role in the citric acid cycle (Krebs cycle), which is essential for cellular respiration in plants, animals, and microorganisms.
L-(-)-Malic acid is used in the food and beverage industry as an acidulant, to add tartness and enhance flavors.
L-(-)-Malic acid is also used in cosmetics and pharmaceuticals.

L-(-)-Malic acid is a white crystalline powder that is highly soluble in water.
L-(-)-Malic acids CAS number is 97-67-6, and it has various synonyms, including (S)-2-hydroxybutanedioic acid, L-Apple acid, and L-Hydroxybutanedioic acid.
L-(-)-Malic acid is a selective α-amino protecting reagent for amino acid derivatives.

L-(-)-Malic acid is also a versatile synthon for the preparation of chiral compounds including κ-opioid receptor agonists, 1α,25-dihydroxyvitamin D3 analogue, and phoslactomycin B.
An acid of natural origin contained in most fruit (L-malic acid) or synthetically made: DL-malic.
L-(-)-Malic acid is used for the acidification of musts and wines in the conditions set by the regulation.

L-(-)-Malic acid is a white, odorless, crystalline solid. In contrast to other fruit acids, it is very hygroscopic and has a tendency to lump.
L-(-)-Malic acid is a dicarboxylic acid and has an asymmetric carbon and occurs as l(the natural)- and d-isomers.
L-(-)-Malic acid is an organic dicarboxylic acid that is present in various foods and is metabolized in humans through the Krebs (or citric acid) cycle.

In its stable isotope-labeled form, it is commonly used as an authentic standard for metabolite quantification.
L-(-)-Malic acid is nearly odorless with a tart, acidic taste.
L-(-)-Malic acid is nonpungent.

L-(-)-Malic acid is an organic acid that is commonly found in wine.
L-(-)-Malic acid plays an important role in wine microbiological stability.
L-(-)-Malic acid can be prepared by hydration of maleic acid; by fermentation from sugar.

Occurs in maple sap, apple, melon, papaya, beer, grape wine, cocoa, sake, kiwifruit and chicory root.
L-(-)-Malic acid is an organic compound with the molecular formula C4H6O5.
L-(-)-Malic acid is a dicarboxylic acid that is made by all living organisms, contributes to the sour taste of fruits, and is used as a food additive.

L-(-)-Malic acid has two stereoisomeric forms (L- and D-enantiomers), though only the L-isomer exists naturally.
The salts and esters of L-Malic acid are known as malates.
The malate anion is an intermediate in the citric acid cycle.

L-(-)-Malic acid, a hydroxydicarboxylic acid, is found in all forms of life.
L-(-)-Malic acid exists naturally only as the L-enantiomer.
L-(-)-Malic acid should not be confused with the similar sounding maleic and malonic acids.

L-(-)-Malic acid is L-hydroxysuccinic acid, by enzyme engineering method or fermentation method and separation and purification.
The content of C4H6Os shall not be less than 99.0% calculated as anhydrous.
L-(-)-Malic acid gives many fruits, particularly apples, their characteristic flavor.

L-(-)-Malic acid is often referred to as “apple acid”.
The word malic is derived from the Latin malum, for which Malus, the genus that contains all apple species, is also named.
L-(-)-Malic acid is a dicarboxylic acid that is found in many fruits and vegetables.

L-(-)-Malic acid is the substrate for the enzyme malate dehydrogenase, which catalyzes the oxidation of L-malate to oxaloacetate.
L-(-)-Malic acid is used to study mitochondrial function, as it can be used as an alternative energy source.
The L-(-)-Malic acid monosodium salt (LAM) has been shown to be effective in preventing muscle damage caused by exercise.

This may be due to L-(-)-Malic acid's ability to decrease oxidative stress and increase ATP production through increased mitochondrial activity.
L-(-)-Malic acid also has been shown to promote photoreceptor cell survival and improve retinal function in animals with damaged photoreceptors, although it does not have any effect on normal animal eyes.

L-(-)-Malic acid, is an alpha-hydroxy organic acid, is sometimes referred to as a fruit acid.
L-(-)-Malic acid is found in apples and other fruits.

Uses:
L-(-)-Malic acid is used as a food additive, Selective α-amino protecting reagent for amino acid derivatives.
Versatile synthon for the preparation of chiral compounds including κ-opioid receptor agonists, 1α,25-dihydroxyvitamin D3 analogue, and phoslactomycin B.
The naturally occuring isomer is the L-form which has been found in apples and many other fruits and plants.

L-(-)-Malic acid selective α-amino protecting reagent for amino acid derivatives.
Versatile synthon for the preparation of chiral compounds including κ-opioid rece
Intermediate in chemical synthesis.

L-(-)-Malic acid is used as Selective α-amino protecting reagent for amino acid derivatives.
Versatile synthon for the preparation of chiral compounds including κ-opioid rece.
L-(-)-Malic acid also acts as active ingredient in many sour or tart foods.

L-(-)-Malic acid is used as synthesizing disincrustant and fluorescent whitening agent.
L-(-)-Malic acid aids in the production of polyester and alcohol acid resins.
L-(-)-Malic acid is used as a food additive, Selective α-amino protecting reagent for amino acid derivatives.

Versatile synthon for the preparation of chiral compounds including κ-opioid receptor agonists, 1α,25-dihydroxyvitamin D3 analogue, and phoslactomycin B.
The naturally occuring isomer is the L-form which has been found in apples and many other fruits and plants.
Selective α-amino protecting reagent for amino acid derivatives.

L-(-)-Malic acid flavoring agent, flavor enhancer and acidulant in foods.
L-(-)-Malic acid may improve exercise performance by boosting energy and decreasing muscle fatigue.
L-(-)-Malic acid also enhances the absorption of other sports performance enhancers like creatine and citrulline.

One study found that a creatine-malate combination improved several aspects of athletes’ running performance, including peak power, distance traveled, hormone levels, and total work.
Bonding L-(-)-Malic acid with citrulline produces citrulline malate.
The L-(-)-Malic acid enhances citrulline’s innate ability to improve nitric oxide levels, remove muscle waste, increase energy, and reduce muscle soreness.

L-(-)-Malic acid may improve dry mouth, dry mouth caused by medication in particular.
L-(-)-Malic acid helps produce more saliva due to its sour flavor.
One six-week study examined the effects of a L-(-)-Malic acid spray solution on dry mouth compared to a placebo.

The L-(-)-Malic acid group had noticeably improved dry mouth symptoms and better saliva flow than the placebo group.
Another two-week trial produced similar results.
Most individuals tolerate L-(-)-Malic acid well, given that L-Malic acid’s a common compound in many fruits and vegetables.

L-(-)-Malic acid may cause mild side effects, including nausea, diarrhea, and headaches.
Individuals taking medications to lower their blood pressure should consult with a physician before taking malic acid supplements, as they may lower blood pressure.
Kidney stones are painful and can affect many people.

L-(-)-Malic acid has been researched for its potential role in preventing and treating kidney stones.
L-(-)-Malic acid is commonly used as an acidulant to enhance the sour taste in foods and beverages, such as fruit juices, candies, soft drinks, and wines.
L-(-)-Malic acids acidic nature helps preserve food by inhibiting the growth of bacteria and other microorganisms.

L-(-)-Malic acid is used to adjust and stabilize the pH levels in various food products.
L-(-)-Malic acid is used in cosmetic products for its exfoliating properties, helping to remove dead skin cells and promote skin renewal.
L-(-)-Malic acid is included in anti-aging formulations to improve skin texture and appearance.

L-(-)-Malic acid is used in dietary supplements to support energy production and improve exercise performance.
L-(-)-Malic acid can act as an excipient in pharmaceutical formulations, helping to stabilize the active ingredients and improve their absorption.
L-(-)-Malic acid can be used to adjust the pH of soil, making it more suitable for growing certain crops.

L-(-)-Malic acid may be included in fertilizers to enhance nutrient availability to plants.
L-(-)-Malic acid is used in metal cleaning and treatment processes for its ability to remove rust and scale from metal surfaces.
It serves as an intermediate in the synthesis of various chemicals and pharmaceuticals.

L-(-)-Malic acid is used in some toothpaste and mouthwash formulations for its ability to stimulate saliva production and help reduce dry mouth.
It may be used in treatments for conditions like fibromyalgia, where it is believed to help improve energy production and reduce muscle pain.
L-(-)-Malic acid is naturally present in grapes and is involved in the malolactic fermentation process, which softens the taste of wine by converting malic acid to lactic acid.

L-(-)-Malic acid is used to enhance the tartness and balance the sweetness of apple cider.
Added to carbonated beverages to provide a tangy flavor.
L-(-)-Malic acid is used in hard and soft candies to provide a sharp, tart taste.

Enhances the sour flavor profile and improves the overall taste experience.
Helps in maintaining the freshness of baked goods by controlling the pH and acting as a preservative.
Adds a subtle tartness to pastries, cakes, and other baked items.

L-(-)-Malic acid is used to enhance the tangy flavor of yogurt and other cultured dairy products.
Helps in the acidification process during cheese making.
Included in hair care products to adjust the pH and enhance the cleaning and conditioning properties.

L-(-)-Malic acid acts as a humectant, helping to retain moisture in the skin.
Adds a refreshing and invigorating scent and feel to bath products.
L-(-)-Malic acid is used in formulations to help exfoliate the skin and reduce acne breakouts.

Included in some wound care products for its moisturizing and pH-adjusting properties.
Often included in formulations aimed at improving energy levels and reducing fatigue, particularly for athletes.
L-(-)-Malic acid is used in various cleaning products for its ability to remove mineral deposits and scale.

Helps in cleaning metal parts and surfaces in industrial settings.
L-(-)-Malic acid is used a plasticizer in the production of certain types of plastics and resins to improve their flexibility and durability.
L-(-)-Malic acid is used in formulations to help break down mucus and improve respiratory function.

Included in creams and ointments for muscle and joint pain relief.
L-(-)-Malic acid is used as a feed additive to improve the taste and nutritional value of animal feed.
Sometimes included in pesticide formulations to enhance their effectiveness.

L-(-)-Malic acid is used in the textile industry to fix dyes and improve the colorfastness of fabrics.
L-(-)-Malic acid is used to adjust the pH of water in various water treatment processes.
Included in formulations for biodegradable and eco-friendly products due to its natural origin and low environmental impact.

Added to protein bars and powders to enhance flavor and improve stability.
L-(-)-Malic acid is used in sports and electrolyte drinks to balance acidity and improve taste.
Helps maintain the desired pH level and enhance the preservation of canned fruits and vegetables.

Adds a tangy flavor to sauces, dressings, and marinades.
L-(-)-Malic acid is used as a fixative in perfumes to enhance the longevity of fragrances.
Adds a refreshing scent to various personal care products.

Included in toothpaste formulations to help remove plaque and promote oral hygiene.
Enhances the flavor and freshness of mouthwash.
L-(-)-Malic acid is used as a stabilizer in pharmaceutical formulations to enhance the shelf life and efficacy of active ingredients.

Helps maintain the pH of pharmaceutical products for better stability and absorption.
Added to medical foods designed for specific dietary needs, such as for patients with metabolic disorders.
L-(-)-Malic acid is used in the production of adhesives and sealants to improve their properties and performance.

Utilized in the paper and pulp industry as a component in the bleaching process to enhance the whiteness of paper.
L-(-)-Malic acid is used in oral rehydration solutions to balance electrolytes and improve hydration.
Incorporated into transdermal patches for its role in enhancing the absorption of active ingredients through the skin.

L-(-)-Malic acid is used in the formulation of fertilizers to adjust the pH and enhance nutrient availability to plants.
Acts as a synergist in pesticide formulations to improve their efficacy against pests.
L-(-)-Malic acid is used in bioremediation processes to enhance the breakdown of pollutants in the environment.

Incorporated into environmentally friendly products due to its natural origin and biodegradability.
L-(-)-Malic acid is used as an additive in battery electrolytes to improve performance and stability.
Included in 3D printing materials to enhance their properties and performance.

L-(-)-Malic acid is used in the formulation of ceramic glazes to improve their quality and appearance.
Enhances the uptake and vibrancy of dyes in textile dyeing processes.

L-(-)-Malic acid is used as a modifier in the production of biodegradable polymers to improve their properties.
Included in electrolyte formulations for electronic components to enhance their performance.

Safety Profile:
While L-(-)-Malic acid is not highly flammable, it can burn if exposed to a strong ignition source.
Direct contact with L-(-)-Malic acid can cause irritation, redness, and discomfort. Prolonged exposure may lead to more severe skin conditions.
L-(-)-Malic acid comes into contact with the eyes, it can cause irritation, redness, pain, and potentially damage the eye tissue.

Inhaling dust or vapors of L-(-)-Malic acid can cause respiratory tract irritation, leading to coughing, sore throat, and shortness of breath.
Ingesting large amounts of L-(-)-Malic acid can cause gastrointestinal irritation, resulting in symptoms like nausea, vomiting, and abdominal pain.

L-(-)-Malic acid can be harmful to aquatic life if large quantities enter water bodies.
L-(-)-Malic acid may cause changes in water pH, which can affect aquatic organisms.


L-(-)-MALIC ACID

L-(-)-Malic acid, also known simply as malic acid, is a naturally occurring organic compound.
L-(-)-Malic acid belongs to the class of dicarboxylic acids, characterized by having two carboxyl groups (COOH) attached to a carbon chain.
Malic acid is optically active, meaning it can exist in two enantiomeric forms: L-malic acid and D-malic acid.

CAS Number: 97-67-6
EC Number: 202-601-5

Malic acid, L-malic acid, D-malic acid, Hydroxybutanedioic acid, 2-Hydroxybutanedioic acid, 2-Hydroxysuccinic acid, (S)-Hydroxysuccinic acid, (S)-Malic acid, (S)-2-Hydroxybutanedioic acid, (-)-Malic acid, (2S)-Hydroxybutanedioic acid, L-Hydroxysuccinic acid, (2S)-Malic acid, L-2-Hydroxybutanedioic acid, (S)-2-Hydroxysuccinic acid, (2S)-2-Hydroxysuccinic acid, (S)-2-Hydroxybutanedioic acid, 2-Hydroxybutanedioate, Hydroxysuccinic acid, (+)-Malic acid, L-Malate, (-)-Hydroxysuccinic acid, L-Malic acid, L-Malate, (-)-Malate, L-Hydroxysuccinic acid, Malate, (-)-Hydroxybutanedioic acid, (-)-2-Hydroxybutanedioic acid, Malic acid, hydroxybutanedioic acid, (S)-2-Hydroxybutanedioic acid, Malic acid, hydroxybutanedioic acid



APPLICATIONS


L-(-)-Malic acid is commonly used as a food additive in the food industry.
L-(-)-Malic acid serves as a flavor enhancer and acidulant in beverages, candies, and processed foods.

L-(-)-Malic acid is added to sour candies to impart a tart taste.
L-(-)-Malic acid is used in the production of carbonated beverages to provide acidity and enhance flavor.
L-(-)-Malic acid is employed as an acidulant in fruit juices and fruit-flavored drinks.

L-(-)-Malic acid is used in the fermentation process of alcoholic beverages such as cider and wine.
L-(-)-Malic acid is added to sports and energy drinks for its refreshing and tart flavor.

L-(-)-Malic acid is used as a preservative in canned fruits and vegetables to maintain their freshness.
L-(-)-Malic acid is utilized in the production of baking powder and sourdough bread.

L-(-)-Malic acid is added to certain dairy products such as yogurt and cheese for flavor enhancement.
L-(-)-Malic acid is used in the pharmaceutical industry as an ingredient in medications.

L-(-)-Malic acid is employed in the formulation of chewable tablets and effervescent powders.
L-(-)-Malic acid is used in oral care products such as mouthwashes and toothpaste.
L-(-)-Malic acid is added to skincare products for its exfoliating and rejuvenating properties.

L-(-)-Malic acid is utilized in hair care products such as shampoos and conditioners.
L-(-)-Malic acid is employed in the textile industry for dyeing and finishing processes.
L-(-)-Malic acid is used in the production of biodegradable plastics and polymers.

L-(-)-Malic acid is employed in the manufacturing of cleaning agents and detergents.
L-(-)-Malic acid is used in agricultural applications as a soil conditioner.
L-(-)-Malic acid is added to animal feed as a nutritional supplement.

L-(-)-Malic acid is used in the production of adhesives and sealants.
L-(-)-Malic acid is employed in the formulation of industrial coatings and paints.
L-(-)-Malic acid is used in the production of metal cleaners and rust removers.

L-(-)-Malic acid is utilized in the manufacturing of paper and pulp products.
Overall, L-(-)-Malic acid has a wide range of applications across various industries, contributing to its versatility and importance in the global market.

L-(-)-Malic acid is utilized in the production of dietary supplements and vitamin formulations.
It is added to fruit-flavored gummies and chewable vitamins for taste enhancement.
L-(-)-Malic acid is used in the cosmetic industry as an ingredient in skincare masks and peels.

L-(-)-Malic acid is employed in exfoliating scrubs and treatments to remove dead skin cells and improve skin texture.
L-(-)-Malic acid is utilized in anti-aging serums and creams for its skin-renewing properties.

L-(-)-Malic acid is added to facial toners and astringents to balance pH levels and tighten pores.
L-(-)-Malic acid is used in hair color products as a pH adjuster and conditioner.
L-(-)-Malic acid helps to open the hair cuticle, allowing for better penetration of color molecules.

L-(-)-Malic acid is employed in the production of flavorings and extracts for the food industry.
L-(-)-Malic acid is used in the formulation of fruit syrups, jams, and jellies for its natural tartness.
L-(-)-Malic acid is utilized in the brewing industry to adjust the acidity of beer and cider.

It contributes to the flavor profile and balance of sourness in fermented beverages.
L-(-)-Malic acid is added to marinades and sauces for meat tenderization and flavor enhancement.
It helps to break down proteins and infuse flavor into the meat during cooking.

L-(-)-Malic acid is used in the production of confectionery such as sour candies and gummies.
L-(-)-Malic acid provides a tangy and refreshing taste that complements sweet and savory flavors.
L-(-)-Malic acid is employed in the formulation of nutritional sports drinks and electrolyte beverages.

L-(-)-Malic acid helps to replenish electrolytes lost during physical activity and improve hydration.
L-(-)-Malic acid is added to frozen desserts such as sorbets and sherbets for its tart flavor.
L-(-)-Malic acid enhances the fruitiness and brightness of fruit-based frozen treats.

L-(-)-Malic acid is utilized in the production of flavored water and fruit-infused beverages.
L-(-)-Malic acid adds a zesty and invigorating taste to plain water, encouraging hydration.
L-(-)-Malic acid is used in the pharmaceutical industry to mask the bitterness of medications.

L-(-)-Malic acid improves the palatability of oral suspensions and liquid medications.
Overall, L-(-)-Malic acid plays a crucial role in various industries, contributing to the flavor, texture, and efficacy of a wide range of products.



DESCRIPTION


L-(-)-Malic acid, also known simply as malic acid, is a naturally occurring organic compound.
L-(-)-Malic acid belongs to the class of dicarboxylic acids, characterized by having two carboxyl groups (COOH) attached to a carbon chain.
Malic acid is optically active, meaning it can exist in two enantiomeric forms: L-malic acid and D-malic acid.
The L-(-)-malic acid isomer is the biologically active form found in living organisms.

Chemically, L-(-)-malic acid has the molecular formula C4H6O5 and a molar mass of approximately 134.09 grams per mole.
Its structure consists of a four-carbon chain with two carboxyl groups (COOH) and one hydroxyl group (OH).

L-(-)-Malic acid is commonly found in various fruits, particularly in apples, where it contributes to the sour taste.
L-(-)-Malic acid is also present in other fruits like grapes, cherries, and citrus fruits, as well as in certain vegetables.
In addition to its natural occurrence, L-(-)-malic acid is used as a food additive for its tart flavor and preservative properties.
L-(-)-Malic acid is commonly added to foods and beverages as an acidulant, flavor enhancer, or pH regulator.

L-(-)-Malic acid is a naturally occurring organic compound.
L-(-)-Malic acid is classified as a dicarboxylic acid due to its two carboxyl groups.

The chemical formula of L-(-)-Malic acid is C4H6O5.
L-(-)-Malic acid is optically active and exists in the L-form in biological systems.

L-(-)-Malic acid is a white, crystalline solid at room temperature.
L-(-)-Malic acid has a tart taste and is commonly found in sour fruits such as apples.

The acid has a melting point of approximately 130-131°C.
L-(-)-Malic acid is soluble in water and alcohol.
L-(-)-Malic acid is odorless and typically has a sour or acidic smell.

L-(-)-Malic acid is often used as a food additive for its sour flavor.
L-(-)-Malic acid is also used as a flavor enhancer and acidulant in the food industry.
L-(-)-Malic acid plays a role in the Krebs cycle, a key metabolic pathway in cells.

It is involved in the production of energy through the metabolism of carbohydrates.
L-(-)-Malic acid is commonly found in various fruits and vegetables.
L-(-)-Malic acid contributes to the tartness of certain wines and beverages.

L-(-)-Malic acid is used in the production of cosmetics and personal care products.
It has exfoliating properties and is often found in skincare formulations.

L-(-)-Malic acid is also used in pharmaceuticals as an ingredient in medications.
L-(-)-Malic acid has been studied for its potential health benefits, including antioxidant properties.

L-(-)-Malic acid is biodegradable and environmentally friendly.
L-(-)-Malic acid is stable under normal conditions of storage and handling.

L-(-)-Malic acid can be synthesized from fumaric acid or maleic acid.
L-(-)-Malic acid has a role in the acidity of certain fermented foods and beverages.

L-(-)-Malic acid is considered safe for consumption in appropriate quantities.
Overall, L-(-)-Malic acid is a versatile compound with various applications in food, pharmaceutical, and cosmetic industries.



PROPERTIES


Chemical Formula: C4H6O5
Molecular Weight: Approximately 134.09 grams per mole
Physical State: Solid at room temperature (crystalline)
Color: White
Odor: Odorless
Taste: Tart or sour
Solubility in Water: Soluble
Solubility in Organic Solvents: Soluble in ethanol, methanol, and other polar organic solvents
Melting Point: Approximately 130-131°C
Boiling Point: Decomposes before boiling
Density: Approximately 1.609 g/cm³
pH: Acidic (approximately 2.2 at 1% solution)
Optical Activity: Optically active (L-form)
Hygroscopicity: Low
Stability: Stable under normal conditions
Flammability: Non-flammable
Refractive Index: Approximately 1.561
Dielectric Constant: Approximately 2.3
Heat of Combustion: Approximately -1025 kJ/mol
Heat of Fusion: Approximately 21.1 kJ/mol
Heat of Vaporization: Approximately 70.5 kJ/mol
Specific Heat Capacity: Approximately 0.925 J/g°C
Flash Point: Not applicable (solid)
Surface Tension: Approximately 82.0 mN/m
Viscosity: Varies with concentration and temperature



FIRST AID


Inhalation:

If inhaled, remove the affected person to fresh air immediately.
Allow the person to rest in a well-ventilated area.
If breathing difficulties persist, seek medical attention promptly.
Provide oxygen if the person has difficulty breathing.


Skin Contact:

Remove contaminated clothing and shoes immediately.
Wash the affected area with plenty of soap and water for at least 15 minutes.
Rinse skin thoroughly to remove any traces of the substance.
If irritation, redness, or rash develops, seek medical advice.
Apply a soothing moisturizer or barrier cream to the affected area to help alleviate discomfort.


Eye Contact:

Flush eyes with lukewarm water, keeping eyelids open, for at least 15 minutes.
Remove contact lenses if present and easily removable.
Seek immediate medical attention if irritation, pain, or redness persists.
Protect the unaffected eye to prevent contamination.


Ingestion:

Rinse mouth with water and drink plenty of water to dilute the substance.
Do not induce vomiting unless instructed to do so by medical personnel.
Seek medical attention immediately and provide information on the ingested substance.
Do not give anything by mouth to an unconscious person.


General Advice:

Keep affected person calm and reassure them.
If seeking medical attention, provide the Safety Data Sheet (SDS) or product label information to healthcare providers.
If the substance has entered the respiratory tract, monitor for signs of respiratory distress and administer CPR if necessary.
Do not administer any medications unless directed by medical personnel.
If exposed to large quantities or experiencing severe symptoms, seek emergency medical assistance immediately.
Be prepared to provide information on the specific product, concentration, and duration of exposure when seeking medical advice.
If transporting an affected individual to a medical facility, ensure proper ventilation and monitor their condition closely.


Additional Precautions:

Avoid direct skin contact with L-(-)-Malic acid, especially in concentrated form.
Use appropriate personal protective equipment (PPE) such as gloves, safety glasses, and protective clothing when handling the substance.
Handle L-(-)-Malic acid in a well-ventilated area to minimize inhalation exposure.
Store L-(-)-Malic acid in a tightly sealed container away from incompatible materials.
Dispose of L-(-)-Malic acid according to local regulations and guidelines.



HANDLING AND STORAGE


Handling:

General Handling:
Handle L-(-)-Malic acid with care to prevent spills and minimize dust generation.
Use appropriate personal protective equipment (PPE) such as gloves, safety glasses, and protective clothing when handling.
Avoid inhalation of dust or vapors. Use in a well-ventilated area or use local exhaust ventilation if necessary.
Do not eat, drink, or smoke while handling L-(-)-Malic acid.
Wash hands thoroughly with soap and water after handling.

Spill and Leak Procedures:
In case of a small spill, collect the material using suitable absorbent material and place it in a labeled container for disposal.
Avoid sweeping or vacuuming the spilled material to prevent dispersion of dust.
Dispose of the collected material in accordance with local regulations.
For large spills or leaks, evacuate the area and contact appropriate authorities for cleanup and disposal.

Storage:
Store L-(-)-Malic acid in a cool, dry, well-ventilated area away from sources of heat, moisture, and ignition.
Keep containers tightly closed when not in use to prevent contamination and moisture absorption.
Store away from incompatible materials such as strong oxidizing agents and bases.
Ensure proper labeling of containers with product name, hazard warnings, and handling instructions.
Do not store near food, feed, or pharmaceuticals to avoid potential cross-contamination.

Handling Precautions:
Avoid prolonged or repeated skin contact with L-(-)-Malic acid.
Use appropriate engineering controls such as dust suppression or containment measures to minimize dust exposure.
Avoid contact with eyes and mucous membranes. In case of contact, rinse thoroughly with water.
Use caution when transferring or dispensing L-(-)-Malic acid to prevent spills and splashes.
Clean up any spills or leaks promptly and dispose of waste material properly.

Transportation:
Follow all applicable regulations and guidelines for the transportation of L-(-)-Malic acid.
Ensure containers are properly labeled, sealed, and secured to prevent leaks or spills during transportation.
Use suitable containers and packaging materials that are compatible with the chemical and designed for transportation purposes.

Emergency Procedures:
Familiarize yourself and other personnel with emergency procedures in case of accidental exposure, spill, or release.
Have appropriate spill control measures, personal protective equipment, and emergency contact information readily available.
In case of emergency, follow established procedures and notify relevant authorities for assistance.

L-(−)-MALIC ACID

L-(−)-Malic acid, also known simply as malic acid, is a naturally occurring organic compound with the chemical formula C4H6O5.
L-(−)-malic acid is a dicarboxylic acid, meaning it has two carboxylic acid functional groups (-COOH) in its structure.
Malic acid is chiral and exists in two enantiomeric forms: L-malic acid and D-malic acid.
The "L" designation refers to its specific optical rotation.

CAS Number: 97-67-6
EC Number: 201-791-2



APPLICATIONS


L-(−)-malic acid, also known simply as malic acid, has a wide range of applications across various industries due to its acidity, flavor-enhancing properties, and biological functions.
Here are some of its key applications:

Food and Beverage Industry:
L-(−)-malic acid is used as an acidulant and flavor enhancer in the production of beverages, including fruit juices, soft drinks, and sports drinks.
L-(−)-malic acid is a common ingredient in sour candies, fruit-flavored snacks, and confectionery items.
L-(−)-malic acid is utilized to provide tartness and acidity in fruit-flavored jams, jellies, and fruit preserves.
In the wine industry, L-(−)-malic acid levels are monitored and controlled during fermentation to influence wine acidity and flavor.

Food Additive:
L-(−)-malic acid is employed as a food additive (E number E296) to regulate acidity and enhance the taste of processed foods, such as canned fruits and vegetables, salad dressings, and sauces.
L-(−)-malic acid helps maintain the freshness and flavor of canned and packaged foods.

Cosmetic and Skincare Products:
L-(−)-malic acid is used in cosmetics and skincare products for its mild exfoliating properties.
L-(−)-malic acid can be found in chemical peels, facial masks, and skincare formulations designed to improve skin texture and appearance.

Pharmaceuticals:
In the pharmaceutical industry, L-(−)-malic acid can be used as an excipient in tablet formulations and as a component in certain medications.
L-(−)-malic acid may also be used as an ingredient in effervescent tablets.

Agriculture:
L-(−)-malic acid is sometimes used in agriculture to adjust soil pH levels, especially in orchards and vineyards.
Proper pH levels in the soil can improve nutrient availability to plants and enhance crop growth.

Biotechnology and Research:
In research and biotechnology, L-(−)-malic acid is used in various biochemical and molecular biology applications.
L-(−)-malic acid can serve as a substrate in enzymatic reactions and as a buffer solution in laboratory experiments.

Industrial Cleaning:
L-(−)-malic acid is used in some industrial cleaning products as an environmentally friendly alternative to harsher chemicals for descaling and cleaning purposes.

Water Treatment:
In water treatment, L-(−)-malic acid can be employed to adjust pH levels and prevent corrosion in water distribution systems.

Oral Care Products:
Some toothpaste formulations may include malic acid for its mild abrasive and tartar-control properties.

Nutraceuticals:
L-(−)-malic acid is used in the formulation of certain nutraceutical and dietary supplement products.

Artificial Flavors and Fragrances:
In the fragrance and flavor industry, L-(−)-malic acid can be used as a component in artificial flavorings and fragrances.

Beverages:
L-(−)-malic acid is frequently used in the beverage industry to provide a crisp and tart flavor in fruit juices, fruit-flavored sodas, and energy drinks.

Carbonated Beverages:
L-(−)-malic acid is an essential component in many carbonated soft drinks, contributing to their characteristic acidity and taste.

Sports Drinks:
L-(−)-malic acid is added to sports and energy drinks to enhance their refreshing and slightly sour profile.

Flavored Waters:
Some flavored bottled waters contain L-(−)-malic acid to create a pleasing taste experience.

Fruit Juices:
L-(−)-malic acid is used to adjust the acidity and flavor profile of fruit juices, ensuring a balanced and appealing taste.

Confectionery:
L-(−)-malic acid is a key ingredient in sour candies, gummies, and fruit-flavored sweets, delivering the desired tangy sensation.

Preserves:
In the production of jams and jellies, L-(−)-malic acid helps maintain acidity levels, aiding in preservation and flavor.

Salad Dressings:
L-(−)-malic acid is used to impart tanginess to salad dressings, vinaigrettes, and marinades.

Canned Fruits and Vegetables:
L-(−)-malic acid is employed as a food preservative and pH regulator in canned fruits and vegetables.

Wine Industry:
In winemaking, L-(−)-malic acid can be added to influence acidity, and its presence or absence affects the taste and quality of wine.

Cosmetic Exfoliants:
L-(−)-malic acid is utilized in cosmetic products like exfoliating scrubs and chemical peels to remove dead skin cells and improve skin texture.

Skin Cleansers:
Some facial cleansers and toners contain L-(−)-malic acid to help balance the skin's pH.

Anti-Aging Creams:
L-(−)-malic acid can be found in anti-aging creams and serums for its potential benefits in reducing signs of aging.

Effervescent Tablets:
L-(−)-malic acid is used in effervescent tablets and powders to create the characteristic fizz when dissolved in water.

Nutraceuticals:
L-(−)-malic acid is an ingredient in some dietary supplements and nutraceutical products, often combined with other compounds for health benefits.

Soil Amendments:
In agriculture, L-(−)-malic acid can be applied as a soil amendment to adjust pH levels for optimal plant growth.

Water Treatment:
L-(−)-malic acid is used in water treatment processes to control pH and prevent corrosion in water distribution systems.

Buffer Solutions:
L-(−)-malic acid is employed as a buffer solution in biochemical and laboratory applications to maintain pH stability.

Industrial Cleaning:
Some industrial cleaning products use L-(−)-malic acid as a safe and effective descaling agent.

Dentistry:
L-(−)-malic acid can be found in certain toothpaste formulations for its mild abrasive properties and tartar control.

Dietary Acidifier:
In pet food, L-(−)-malic acid may be used as a dietary acidifier to regulate urinary pH levels in certain animals.

Artificial Flavors:
L-(−)-malic acid is used as an artificial flavoring agent in various food and beverage products.

Flavor Enhancer:
L-(−)-malic acid enhances the overall flavor profile of processed foods, making them more appealing to consumers.

Preservation:
L-(−)-malic acid contributes to the preservation of packaged and canned foods by controlling pH and acidity.

Biotechnology:
In biotechnology and research, L-(−)-malic acid serves as a versatile compound in various biochemical experiments and assays.

Fruit-Based Products:
L-(−)-malic acid is used to enhance the flavor of fruit-based products like fruit syrups, fruit sauces, and fruit fillings for pastries.

Canned Vegetables:
L-(−)-malic acid helps maintain the quality and taste of canned vegetables, such as green beans and peas, by regulating acidity.

Frozen Desserts:
L-(−)-malic acid can be found in frozen desserts like sorbets and sherbets, adding a pleasant tartness.

Baking:
In baking, L-(−)-malic acid may be used as a leavening agent, contributing to the rise and texture of baked goods.

Chewing Gum:
Some chewing gum formulations include malic acid for its sour and fruity taste.

Processed Meats:
L-(−)-malic acid is used to modify the taste and texture of processed meats like sausages and deli meats.

Flavored Alcoholic Beverages:
L-(−)-malic acid is added to flavored alcoholic beverages, such as wine coolers and flavored vodkas.

Fruit-Based Snacks:
In fruit snacks and fruit leathers, malic acid enhances the natural fruit flavors.

Cider Production:
In cider-making, L-(−)-malic acid is a naturally occurring acid in apple juice, and its concentration influences cider taste.

Sour Mixes:
L-(−)-malic acid is a component in sour cocktail mixes, contributing to the desired tangy flavor.

Fruit Pectins:
L-(−)-malic acid can be added to fruit pectin preparations to help set jams and jellies.

Cheese Manufacturing:
In cheese production, malic acid may be used to control pH levels during fermentation.

Carbonated Water:
L-(−)-malic acid can be used to carbonate water, creating sparkling water or soda water.

pH Control in Brewing:
In brewing, L-(−)-malic acid can be added to adjust pH levels during the brewing process.

pH Control in Food Processing:
L-(−)-malic acid is employed in various food processing applications to control and maintain pH levels.

Fruit Flavoring:
L-(−)-malic acid is used as a fruit flavor enhancer in candies, gels, and fruit-flavored toppings.

Energy Gels:
L-(−)-malic acid is an ingredient in energy gels and chews for athletes, providing both flavor and a quick source of energy.

Gummy Vitamins:
Some gummy vitamin supplements contain malic acid for taste and texture improvement.

Personal Care Products:
L-(−)-malic acid can be found in personal care products like shampoos and conditioners as a pH regulator.

Biodegradable Plastics:
L-(−)-malic acid is being explored as a potential component in the development of biodegradable plastics.



DESCRIPTION


L-(−)-Malic acid, also known simply as malic acid, is a naturally occurring organic compound with the chemical formula C4H6O5.
L-(−)-malic acid is a dicarboxylic acid, meaning it has two carboxylic acid functional groups (-COOH) in its structure.
Malic acid is chiral and exists in two enantiomeric forms: L-malic acid and D-malic acid.
The "L" designation refers to its specific optical rotation.

L-(−)-malic acid is the naturally occurring form found in various fruits, including apples, grapes, and cherries.
L-(−)-malic acid contributes to the tart or sour taste of these fruits.
L-(−)-malic acid is also commonly used in the food and beverage industry as an acidulant to impart a sour or acidic taste to products like candies, beverages, and fruit-flavored snacks.
Additionally, L-malic acid is used as a food additive for its acidity-regulating and flavor-enhancing properties.

L-(−)-malic acid is a naturally occurring organic compound found in various fruits and vegetables.
L-(−)-malic acid is a dicarboxylic acid, which means it contains two carboxylic acid functional groups (-COOH) in its chemical structure.

L-(−)-malic acid is optically active, with a specific optical rotation that characterizes its enantiomeric form.
It exists in two enantiomeric forms: L-malic acid (the naturally occurring form) and D-malic acid.
The "L" designation indicates the stereochemistry of its optical activity.

L-malic acid is responsible for the tart or sour taste in fruits like apples, grapes, and cherries.
In addition to its presence in fruits, it can also be found in some vegetables, such as tomatoes and carrots.
L-(−)-malic acid plays a crucial role in the Krebs cycle (citric acid cycle) in cellular respiration, where it is involved in energy production.

L-(−)-malic acid is water-soluble and has a molecular formula of C4H6O5.
L-(−)-malic acid is commonly used in the food and beverage industry as an acidulant to impart a sour taste to products.

L-(−)-malic acid is considered safe for consumption and is often used in food and beverage products as an acidity regulator.
It is utilized in the production of sour candies, fruit-flavored beverages, and fruit-flavored snacks.
L-(−)-malic acid is used as a food additive to enhance the flavor of various processed foods.
L-(−)-malic acid is known for its ability to enhance the overall taste profile of products by providing a balanced sourness.

In winemaking, L-malic acid can be naturally present in grapes and is often monitored and controlled during fermentation to influence the wine's acidity.
L-(−)-malic acid can also be used as an ingredient in the formulation of some pharmaceuticals and dietary supplements.
In the cosmetics industry, L-(−)-malic acid is used in skincare products for its mild exfoliating properties.

L-(−)-malic acid is a versatile compound that contributes to the preservation and flavor enhancement of many food and beverage items.
L-(−)-malic acid has a role in buffering pH levels in biological systems and maintaining cellular functions.
L-(−)-malic acid has a crisp and refreshing taste, making it an ideal component in various beverages and confectionery.

L-(−)-malic acid is considered safe for consumption, and the human body metabolizes it without harmful effects.
L-(−)-malic acid can be synthesized from citric acid or obtained through extraction from natural sources.
Its sour taste makes it a popular choice for creating sour candies and sour-flavored products.

In the field of agriculture, L-(−)-malic acid is sometimes used to adjust the pH of soil in order to optimize plant growth.
L-(−)-malic acid is a multifaceted compound with applications spanning from food and beverages to agriculture and biochemistry.



PROPERTIES


Chemical Formula: C4H6O5
Molar Mass: Approximately 134.09 grams/mol
Chemical Structure: Malic acid is a dicarboxylic acid with two carboxylic acid functional groups (-COOH) in its structure. It has both cis and trans isomers.


Physical Properties:

Physical State: Malic acid is typically found as a white, crystalline powder or granules.
Melting Point: The melting point of malic acid is approximately 130-132°C (266-270°F).
Solubility: It is highly soluble in water, and its solubility increases with temperature.
Density: The density of malic acid varies with temperature and concentration but is typically around 1.59 g/cm³.
Odor and Taste: Malic acid has a sour or tart taste, and it is odorless.
Hygroscopicity: It exhibits hygroscopic properties, meaning it can absorb moisture from the air.
Optical Activity: Malic acid exists in two enantiomeric forms: L-malic acid and D-malic acid. L-malic acid is the naturally occurring form and is optically active.


Chemical Properties:

Acidity: Malic acid is a weak organic acid and can act as a proton donor in aqueous solutions.
pKa Values: Malic acid has two dissociation constants (pKa values) for its carboxylic acid groups: pKa1 ≈ 3.40 and pKa2 ≈ 5.20.
Buffering Capacity: Malic acid can function as a buffer, helping to stabilize pH in various solutions.
Reactivity: It can react with certain metals, such as calcium and magnesium, forming soluble complexes.
Chirality: Malic acid is chiral and can exist in both the D and L forms, with L-malic acid being the biologically relevant form.



FIRST AID


Inhalation:

Move to Fresh Air:
If malic acid dust or vapors are inhaled and respiratory discomfort occurs, immediately move the affected person to an area with fresh air.

Assist Breathing:
If breathing difficulties persist or the person is not breathing, administer artificial respiration if trained, and seek immediate medical attention.

Keep Calm:
Encourage the affected person to stay calm and avoid panic.


Skin Contact:

Remove Contaminated Clothing:
If malic acid comes into contact with the skin, promptly remove contaminated clothing, including shoes and socks, to prevent further contact.

Rinse with Water:
Wash the affected skin gently but thoroughly with copious amounts of running water for at least 15 minutes to remove any residual malic acid.

Seek Medical Attention:
If skin irritation, redness, or chemical burns develop, seek medical advice promptly.

Wash Clothing:
Wash any contaminated clothing before reuse.


Eye Contact:

Rinse Eyes:
If malic acid splashes into the eyes, immediately rinse the affected eye(s) gently but thoroughly with lukewarm, clean water for at least 15 minutes. Use an eyewash station if available.

Hold Eyelids Open:
Hold the eyelids open while rinsing to ensure thorough washing of the eye.

Seek Medical Attention:
If eye irritation or pain persists or if there are signs of eye injury, seek immediate medical attention.

Do Not Rub Eyes:
Avoid rubbing the eyes, as it may exacerbate irritation and cause further damage.


Ingestion:

Do Not Induce Vomiting:
If malic acid is ingested accidentally, do not induce vomiting unless advised to do so by a medical professional.

Rinse Mouth:
Rinse the mouth thoroughly with water to remove any residual malic acid.

Seek Immediate Medical Attention:
Contact a poison control center or seek immediate medical attention, especially if a large quantity has been ingested.

Have Information Available:
Have the product label or container information available to provide to medical personnel.



HANDLING AND STORAGE


Handling:

Personal Protective Equipment (PPE):
When working with malic acid in its solid or liquid form, wear appropriate personal protective equipment (PPE), including safety goggles or a face shield, chemical-resistant gloves, and a lab coat or protective clothing.
Use respiratory protection, such as a dust mask, if handling malic acid powder in an environment with dust concentrations above recommended exposure limits.

Ventilation:
Ensure adequate ventilation in the workspace to prevent the buildup of malic acid dust or vapors.
Use local exhaust ventilation or work in well-ventilated areas.
If ventilation is insufficient, wear a NIOSH-approved respiratory protection device suitable for the specific conditions.

Avoid Contact:
Minimize skin and eye contact with malic acid. In case of accidental contact, follow the first aid measures provided earlier.

Prevent Inhalation:
Avoid inhaling malic acid dust or vapors.
Use appropriate respiratory protection when necessary.

Avoid Ingestion:
Do not consume food, beverages, or tobacco products in areas where malic acid is being handled, and always wash hands thoroughly after handling the substance.

Equipment and Tools:
Use dedicated equipment and tools for handling malic acid to prevent cross-contamination.
Clean equipment after use.


Storage:

Container:
Store malic acid in tightly sealed containers made of compatible materials, such as plastic, glass, or stainless steel.
Ensure that containers are labeled with appropriate hazard information.

Temperature:
Keep malic acid in a cool, dry place away from heat sources, direct sunlight, and open flames.
Store at a temperature below its melting point (approximately 130-132°C or 266-270°F).

Separation:
Store malic acid away from incompatible materials, such as strong bases, strong acids, and strong oxidizers, to prevent reactions or contamination.

Moisture Control:
Prevent exposure to excessive moisture, as malic acid can be hygroscopic and may absorb water from the atmosphere.
Use desiccants or moisture-absorbing materials if needed.

Childproof Storage:
Ensure that malic acid is stored out of reach of children and unauthorized personnel.

Ventilation:
If storing large quantities of malic acid, consider storing it in a well-ventilated area or in a storage cabinet with proper ventilation.

Separation from Food Products:
Store malic acid away from food and food ingredients to prevent accidental contamination.

Chemical Compatibility:
Be aware of the chemical compatibility of the storage containers and materials.
Ensure they are resistant to malic acid.


Spill and Leak Response:

Containment:
In the event of a spill, contain the spill by creating a barrier using appropriate absorbent materials, such as vermiculite, sand, or absorbent pads.

Cleaning:
Carefully clean up the spill, avoiding direct contact.
Wear appropriate PPE during cleanup.

Disposal:
Dispose of contaminated materials and residues in accordance with local regulations and guidelines for hazardous waste disposal.



SYNONYMS


Hydroxysuccinic acid
Hydroxybutanedioic acid
2-Hydroxybutanedioic acid
2-Hydroxybutanedioate
DL-hydroxysuccinic acid
DL-malate
Apple acid
Alpha-hydroxysuccinic acid
2-Carboxy-2-hydroxybutanedioic acid
E296 (Food additive code)
L(−)-Hydroxysuccinic acid
Apple juice acid
L-malic acid
D-malic acid
D-hydroxysuccinic acid
L-hydroxysuccinic acid
DL-alpha-hydroxysuccinic acid
DL-malate
Hydroxybutanedioic acid (DL-form)
Hydroxysuccinate
2-Hydroxybutanedioate
Hydroxybutanedioate
Dihydroxysuccinic acid
2-Carboxy-2-hydroxybutanedioate
2-Hydroxybutanedioic acid (DL-form)
L(+)-LACTIC ACID
DESCRIPTION:
L(+)-Lactic Acid is an organic acid.
L(+)-Lactic Acid has the molecular formula CH3CH(OH)COOH.
L(+)-Lactic Acid is white in the solid state and L(+)-Lactic Acid is miscible with water.
When in the dissolved state, it forms a colorless solution.
Production includes both artificial synthesis as well as natural sources.

CAS Number 50-21-5
EC Number 200-018-0
Empirical Formula (Hill Notation):C3H6O3


SYNONYM(S) OF L(+)-LACTIC ACID:
(S)-2-Hydroxypropionic acid, Sarcolactic acid,2 Hydroxypropanoic Acid,2 Hydroxypropionic Acid,2-Hydroxypropanoic Acid,2-Hydroxypropionic Acid,Ammonium Lactate,D Lactic Acid,D-Lactic Acid,L Lactic Acid,L-Lactic Acid,Lactate,Lactate, Ammonium,Lactic AcidPropanoic Acid, 2-Hydroxy-, (2R)-,Propanoic Acid, 2-Hydroxy-, (2S)-,Sarcolactic Acid,L-Lactic acid,79-33-4,L-(+)-Lactic acid,(S)-Lactic acid,(S)-2-Hydroxypropanoic acid,Sarcolactic acid,(2S)-2-hydroxypropanoic acid,(+)-Lactic acid,(S)-2-Hydroxypropionic acid,Paralactic acid,(S)-(+)-Lactic acid,L(+)-LACTIC ACID,Tisulac,Lactic acid, L-,PURAC,Paramilchsaeure,Fleischmilchsaeure,(S)-Milchsaeure,(S)-lactate,Acidum sarcolacticum,Sarcolacticum acidum,L-lactate,Propanoic acid, 2-hydroxy-, (2S)-,Pleo sanvis,PH 90,(S)-2-Hydroxypropionsaeure,L-(+)-alpha-Hydroxypropionic acid,L-Milchsaeure,UNII-F9S9FFU82N,PROPANOIC ACID, 2-HYDROXY-, (S)-,EINECS 201-196-2,F9S9FFU82N,CHEBI:422,L(+)-2-Hydroxypropionsaeure,BRN 1720251,L-Lactic Acid, 90%,DEXTROROTATORY LACTIC ACID,EC 201-196-2,4-03-00-00633 (Beilstein Handbook Reference),l-milchsaure,(+)-Lactate,Sodium (S)-lactate,(S)-LACTIC ACID (EP MONOGRAPH),(S)-LACTIC ACID [EP MONOGRAPH],PLLA,S-Lactic acid; (S)-2-hydroxypropanoic acid,1-Hydroxyethane 1-carboxylic acid,L-lacticacid,Lactisan Winter,Pleo Sanuvis,MFCD00064266,(alpha)-Lactate,L-Iactic acid,L Lactic Acid,a-Hydroxypropanoate,a-Hydroxypropionate,26811-96-1,2OP,ClO2-C Activator,nchembio867-comp9,(alpha)-Lactic acid,alpha-Hydroxypropanoate,alpha-Hydroxypropionate,L-2-Hydroxypropanoate,a-Hydroxypropanoic acid,a-Hydroxypropionic acid,L-(+) Lactic Acid,(S)-2-Hydroxypropanoate,(S)-2-Hydroxypropionate,1-Hydroxyethanecarboxylate,L-Lactic acid, anhydrous,L-2-Hydroxypropanoic acid,bmse000208,bmse000818,Bmse000979,D-Lactic Acid (90%),(S)-2-hydroxy-Propanoate,(?)-LACTATE,L-LACTIC ACID [MI],L-LACTIC ACID (+),L-LACTIC ACID [JAN],L-(+)-Lactic acid solution,1-Hydroxyethane 1-carboxylate,LACTIC ACID, L-(II),(S)-2-hydroxy-Propanoic acid,(S)-2-hydroxy-propionic acid,CHEMBL330546,GTPL2932,L- LACTIC ACID (+),(S)-(+)-2-Hydroxypropanoate,L-(+)-Lactic acid, 80%,(S)(+)2 hydroxypropionic acid,DTXSID6034689,LACTIC ACID, L- [II],(s)(+)-2 hydroxypropionic acid,SARCOLACTIC ACID [WHO-DD],L-(+)-Lactic acid 95% liquid,80% (w/w) Lactic Acid Solution,L-(+)-Lactic acid solution, 1M,L-(+)-Lactic acid, >=98%,SARCOLACTICUM ACIDUM [HPUS],(S)-(+)-2-Hydroxypropanoic acid,2-Hydroxypropanoic acid, (S)- #,HY-Y0479,s6250,AKOS025146504,DB14475,L-Lactic acid, crystalline, 98.0%+,L-(+)-Lactic acid, analytical,standard,CS-0015266,L0165,NS00006010,EN300-91905,C00186,D71144,G64463,L-0990,L-1000,L-(+)-Lactic acid, BioXtra, >=98% (titration),L-(+)-Lactic acid, Vetec(TM) reagent grade, 86%,Q27080955,5E39D33D-2F71-4C24-BC7A-5E6F27E4CF83,L+Lactic Acid, Free Acid (S)-2-Hydroxypropionic acid, Sarcolactic acid,2-HYDROXYPROPIONIC ACID , L-(+)-Lactic acid , (S)-2-Hydroxypropanoic acid,(S)-2-Hydroxypropanoic acid; L-(+)-Lactic acid; Propanoic acid, 2-hydroxy-, (S)-; Lactic acid, L-; Espiritin; (S)-2-Hydroxypropionic acid; (+)-Lactic acid; (S)-Lactic acid; (S)-(+)-Lactic acid; Paralactic acid; Sarcolactic acid; Tisulac; PH 90; Propanoic acid, 2-hydroxy-, (2S)-; PURAC; lactate



(S)-lactic acid is an optically active form of lactic acid having (S)-configuration.
L(+)-Lactic Acid has a role as an Escherichia coli metabolite and a human metabolite.
L(+)-Lactic Acid is a 2-hydroxypropanoic acid and a (2S)-2-hydroxy monocarboxylic acid.

L(+)-Lactic Acid is a conjugate acid of a (S)-lactate.
L(+)-Lactic Acid is an enantiomer of a (R)-lactic acid.


L-Lactic acid is a metabolite found in or produced by Escherichia coli (strain K12, MG1655).


L-Lactic acid is a natural product found in Arabidopsis thaliana, Homo sapiens, and other organisms with data available.




Lactic acid is an alpha-hydroxy acid (AHA) due to the presence of a hydroxyl group adjacent to the carboxyl group.
L(+)-Lactic Acid is used as a synthetic intermediate in many organic synthesis industries and in various biochemical industries.
The conjugate base of lactic acid is called lactate (or the lactate anion).
The name of the derived acyl group is lactoyl.

In solution, it can ionize by a loss of a proton to produce the lactate ion CH
3CH(OH)CO−

2. Compared to acetic acid, its pKa is 1 unit less, meaning lactic acid is ten times more acidic than acetic acid.
This higher acidity is the consequence of the intramolecular hydrogen bonding between the α-hydroxyl and the carboxylate group.
Lactic acid is chiral, consisting of two enantiomers.

One is known as l-lactic acid, (S)-lactic acid, or (+)-lactic acid, and the other, its mirror image, is d-lactic acid, (R)-lactic acid, or (−)-lactic acid.
A mixture of the two in equal amounts is called dl-lactic acid, or racemic lactic acid.

Lactic acid is hygroscopic. dl-Lactic acid is miscible with water and with ethanol above its melting point, which is about 16 to 18 °C (61 to 64 °F). d-Lactic acid and l-lactic acid have a higher melting point.

Lactic acid produced by fermentation of milk is often racemic, although certain species of bacteria produce solely d-lactic acid.[6]
On the other hand, lactic acid produced by anaerobic respiration in animal muscles has the (l) enantiomer and is sometimes called "sarcolactic" acid, from the Greek sarx, meaning "flesh".

In animals, l-lactate is constantly produced from pyruvate via the enzyme lactate dehydrogenase (LDH) in a process of fermentation during normal metabolism and exercise.[7]
It does not increase in concentration until the rate of lactate production exceeds the rate of lactate removal, which is governed by a number of factors, including monocarboxylate transporters, concentration and isoform of LDH, and oxidative capacity of tissues.[7]

The concentration of blood lactate is usually 1–2 mMTooltip millimolar at rest, but can rise to over 20 mM during intense exertion and as high as 25 mM afterward.
In addition to other biological roles, l-lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), which is a Gi/o-coupled G protein-coupled receptor (GPCR).
In industry, lactic acid fermentation is performed by lactic acid bacteria, which convert simple carbohydrates such as glucose, sucrose, or galactose to lactic acid.


These bacteria can also grow in the mouth; the acid they produce is responsible for the tooth decay known as cavities.
In medicine, lactate is one of the main components of lactated Ringer's solution and Hartmann's solution.

These intravenous fluids consist of sodium and potassium cations along with lactate and chloride anions in solution with distilled water, generally in concentrations isotonic with human blood.
It is most commonly used for fluid resuscitation after blood loss due to trauma, surgery, or burns.

HISTORY OF L(+)-LACTIC ACID:

Swedish chemist Carl Wilhelm Scheele was the first person to isolate lactic acid in 1780 from sour milk.[16]
The name reflects the lact- combining form derived from the Latin word lac, meaning "milk".
In 1808, Jöns Jacob Berzelius discovered that lactic acid (actually l-lactate) also is produced in muscles during exertion.[17]

Its structure was established by Johannes Wislicenus in 1873.
In 1856, the role of Lactobacillus in the synthesis of lactic acid was discovered by Louis Pasteur.
This pathway was used commercially by the German pharmacy Boehringer Ingelheim in 1895.

In 2006, global production of lactic acid reached 275,000 tonnes with an average annual growth of 10%.[18]


PRODUCTION OF L(+)-LACTIC ACID:
Lactic acid is produced industrially by bacterial fermentation of carbohydrates, or by chemical synthesis from acetaldehyde.[19]
As of 2009, lactic acid was produced predominantly (70–90%)[20] by fermentation.
Production of racemic lactic acid consisting of a 1:1 mixture of d and l stereoisomers, or of mixtures with up to 99.9% l-lactic acid, is possible by microbial fermentation.

Industrial scale production of d-lactic acid by fermentation is possible, but much more challenging.

Fermentative production:
Fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria: Lactobacillus acidophilus, Lacticaseibacillus casei (Lactobacillus casei), Lactobacillus delbrueckii subsp. bulgaricus (Lactobacillus bulgaricus), Lactobacillus helveticus, Lactococcus lactis , Bacillus amyloliquefaciens, and Streptococcus salivarius subsp. thermophilus (Streptococcus thermophilus).

As a starting material for industrial production of lactic acid, almost any carbohydrate source containing C5 (Pentose sugar) and C6 (Hexose sugar) can be used.
Pure sucrose, glucose from starch, raw sugar, and beet juice are frequently used.[21]
Lactic acid producing bacteria can be divided in two classes: homofermentative bacteria like Lactobacillus casei and Lactococcus lactis, producing two moles of lactate from one mole of glucose, and heterofermentative species producing one mole of lactate from one mole of glucose as well as carbon dioxide and acetic acid/ethanol.[22]

Chemical production:
Racemic lactic acid is synthesized industrially by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile.
When hydrolysis is performed by hydrochloric acid, ammonium chloride forms as a by-product; the Japanese company Musashino is one of the last big manufacturers of lactic acid by this route.
Synthesis of both racemic and enantiopure lactic acids is also possible from other starting materials (vinyl acetate, glycerol, etc.) by application of catalytic procedures.[24]

Biology:
Molecular biology
l-Lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), a Gi/o-coupled G protein-coupled receptor (GPCR).
Metabolism and exercise
During power exercises such as sprinting, when the rate of demand for energy is high, glucose is broken down and oxidized to pyruvate, and lactate is then produced from the pyruvate faster than the body can process it, causing lactate concentrations to rise.

The production of lactate is beneficial for NAD+ regeneration (pyruvate is reduced to lactate while NADH is oxidized to NAD+), which is used up in oxidation of glyceraldehyde 3-phosphate during production of pyruvate from glucose, and this ensures that energy production is maintained and exercise can continue.

During intense exercise, the respiratory chain cannot keep up with the amount of hydrogen ions that join to form NADH, and cannot regenerate NAD+ quickly enough, so pyruvate is converted to lactate to allow energy production by glycolysis to continue.[25]

The resulting lactate can be used in two ways:
Oxidation back to pyruvate by well-oxygenated muscle cells, heart cells, and brain cells
Pyruvate is then directly used to fuel the Krebs cycle
Conversion to glucose via gluconeogenesis in the liver and release back into circulation by means of the Cori cycle[26]

If blood glucose concentrations are high, the glucose can be used to build up the liver's glycogen stores.
Lactate is continually formed at rest and during all exercise intensities.

Lactate serves as a metabolic fuel being produced and oxidatively disposed in resting and exercising muscle and other tissues.[25]
Some sources of excess lactate production are metabolism in red blood cells, which lack mitochondria that perform aerobic respiration, and limitations in the rates of enzyme activity in muscle fibers during intense exertion.[26]

Lactic acidosis is a physiological condition characterized by accumulation of lactate (especially l-lactate), with formation of an excessively high proton concentration [H+] and correspondingly low pH in the tissues, a form of metabolic acidosis.[25]
The first stage in metabolizing glucose is glycolysis, the conversion of glucose to pyruvate− and H+:
C6H12O6 + 2 NAD+ + 2 ADP3− + 2 HPO2−4 → 2 CH3COCO−2 + 2 H+ + 2 NADH + 2 ATP4− + 2 H2O

When sufficient oxygen is present for aerobic respiration, the pyruvate is oxidized to CO2 and water by the Krebs cycle, in which oxidative phosphorylation generates ATP for use in powering the cell.
When insufficient oxygen is present, or when there is insufficient capacity for pyruvate oxidation to keep up with rapid pyruvate production during intense exertion, the pyruvate is converted to lactate− by lactate dehydrogenase), a process that absorbs these protons:[27]
2 CH3COCO−2 + 2 H+ + 2 NADH → 2 CH3CH(OH)CO−2 + 2 NAD+
The combined effect is:
C6H12O6 + 2 ADP3− + 2HPO2−4 → 2 CH3CH(OH)CO−2 + 2 ATP4− + 2 H2O
The production of lactate from glucose (glucose → 2 lactate− + 2 H+), when viewed in isolation, releases two H+. The H+ are absorbed in the production of ATP, but H+ is subsequently released during hydrolysis of ATP:
ATP4− + H2O → ADP3− + HPO2−4 + H+
Once the production and use of ATP is included, the overall reaction is
C6H12O6 → 2 CH3CH(OH)CO−2 + 2 H+
The resulting increase in acidity persists until the excess lactose and protons are converted back to pyruvate, and then to glucose for later use, or to CO2 and water for the production of ATP.[25]


Neural tissue energy source
Although glucose is usually assumed to be the main energy source for living tissues, there is evidence that lactate, in preference to glucose, is preferentially metabolized by neurons in the brains of several mammalian species that include mice, rats, and humans.
According to the lactate-shuttle hypothesis, glial cells are responsible for transforming glucose into lactate, and for providing lactate to the neurons.

Because of this local metabolic activity of glial cells, the extracellular fluid immediately surrounding neurons strongly differs in composition from the blood or cerebrospinal fluid, being much richer with lactate, as was found in microdialysis studies.[28]

Brain development metabolism:
Some evidence suggests that lactate is important at early stages of development for brain metabolism in prenatal and early postnatal subjects, with lactate at these stages having higher concentrations in body liquids, and being utilized by the brain preferentially over glucose.[28]

It was also hypothesized that lactate may exert a strong action over GABAergic networks in the developing brain, making them more inhibitory than it was previously assumed,[32] acting either through better support of metabolites,[28] or alterations in base intracellular pH levels,[33][34] or both.

Studies of brain slices of mice show that β-hydroxybutyrate, lactate, and pyruvate act as oxidative energy substrates, causing an increase in the NAD(P)H oxidation phase, that glucose was insufficient as an energy carrier during intense synaptic activity and, finally, that lactate can be an efficient energy substrate capable of sustaining and enhancing brain aerobic energy metabolism in vitro.[36]

The study "provides novel data on biphasic NAD(P)H fluorescence transients, an important physiological response to neural activation that has been reproduced in many studies and that is believed to originate predominantly from activity-induced concentration changes to the cellular NADH pools."
Lactate can also serve as an important source of energy for other organs, including the heart and liver.
During physical activity, up to 60% of the heart muscle's energy turnover rate derives from lactate oxidation.



USES OF L(+)-LACTIC ACID:
Polymer precursor[edit]
Two molecules of lactic acid can be dehydrated to the lactone lactide.
In the presence of catalysts lactide polymerize to either atactic or syndiotactic polylactide (PLA), which are biodegradable polyesters.
PLA is an example of a plastic that is not derived from petrochemicals.


Pharmaceutical and cosmetic applications:
Lactic acid is also employed in pharmaceutical technology to produce water-soluble lactates from otherwise-insoluble active ingredients.
It finds further use in topical preparations and cosmetics to adjust acidity and for its disinfectant and keratolytic properties.
Lactic acid containing bacteria have shown promise in reducing oxaluria with its descaling properties on calcium compounds.

Foods:
Fermented food:
Lactic acid is found primarily in sour milk products, such as kumis, laban, yogurt, kefir, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by lactic acid.
Lactic acid is also responsible for the sour flavor of sourdough bread.

In lists of nutritional information lactic acid might be included under the term "carbohydrate" (or "carbohydrate by difference") because this often includes everything other than water, protein, fat, ash, and ethanol.

If this is the case then the calculated food energy may use the standard 4 kilocalories (17 kJ) per gram that is often used for all carbohydrates.
But in some cases lactic acid is ignored in the calculation.
The energy density of lactic acid is 362 kilocalories (1,510 kJ) per 100 g.

Some beers (sour beer) purposely contain lactic acid, one such type being Belgian lambics.
Most commonly, this is produced naturally by various strains of bacteria.
These bacteria ferment sugars into acids, unlike the yeast that ferment sugar into ethanol.

After cooling the wort, yeast and bacteria are allowed to "fall" into the open fermenters.
Brewers of more common beer styles would ensure that no such bacteria are allowed to enter the fermenter.
Other sour styles of beer include Berliner weisse, Flanders red and American wild ale.


In winemaking, a bacterial process, natural or controlled, is often used to convert the naturally present malic acid to lactic acid, to reduce the sharpness and for other flavor-related reasons.
This malolactic fermentation is undertaken by lactic acid bacteria.
While not normally found in significant quantities in fruit, lactic acid is the primary organic acid in akebia fruit, making up 2.12% of the juice.

Separately added
As a food additive it is approved for use in the EU,[47] United States[48] and Australia and New Zealand;[49] it is listed by its INS number 270 or as E number E270.

Lactic acid is used as a food preservative, curing agent, and flavoring agent.
It is an ingredient in processed foods and is used as a decontaminant during meat processing.

Lactic acid is produced commercially by fermentation of carbohydrates such as glucose, sucrose, or lactose, or by chemical synthesis.
Carbohydrate sources include corn, beets, and cane sugar


CHEMICAL AND PHYSICAL PROPERTIES OF L(+)-LACTIC ACID:
Chemical formula C3H6O3
Molar mass 90.078 g•mol−1
Melting point 18 °C (64 °F; 291 K)
Boiling point 122 °C (252 °F; 395 K) at 15 mmHg
Solubility in water Miscible[2]
Acidity (pKa) 3.86,[3] 15.1[4]
Thermochemistry
Std enthalpy of
combustion (ΔcH⦵298) 1361.9 kJ/mol, 325.5 kcal/mol, 15.1 kJ/g, 3.61 kcal/g
Molecular Weight
90.08 g/mol
Computed by PubChem 2.2 (PubChem release 2021.10.14)
XLogP3
-0.7
Computed by XLogP3 3.0 (PubChem release 2021.10.14)
Hydrogen Bond Donor Count
2
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Hydrogen Bond Acceptor Count
3
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Rotatable Bond Count
1
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Exact Mass
90.031694049 g/mol
Computed by PubChem 2.2 (PubChem release 2021.10.14)
Monoisotopic Mass
90.031694049 g/mol
Computed by PubChem 2.2 (PubChem release 2021.10.14)
Topological Polar Surface Area
57.5Ų
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Heavy Atom Count
6
Computed by PubChem
Formal Charge
0
Computed by PubChem
Complexity
59.1
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Isotope Atom Count
0
Computed by PubChem
Defined Atom Stereocenter Count
1
Computed by PubChem
Undefined Atom Stereocenter Count
0
Computed by PubChem
Defined Bond Stereocenter Count
0
Computed by PubChem
Undefined Bond Stereocenter Count
0
Computed by PubChem
Covalently-Bonded Unit Count
1
Computed by PubChem
Compound Is Canonicalized
Yes
Color White
Formula Weight 90.08
Density 1190 to 1250kg/mL
Quantity 25 g
Physical Form Solid
Chemical Name or Material L-Lactic Acid, Free Acid



SAFETY INFORMATION ABOUT L(+)-LACTIC ACID:
First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product.



L(+)-TARTARIC ACID
L(+)-Tartaric acid is a conjugate acid of a L-tartrate(1-).
L(+)-Tartaric acid is an enantiomer of a D-tartaric acid.
L-(+)-Tartaric Acid is a naturally occurring chemical compound found in berries, grapes and various wines.


CAS Number: 87-69-4
EC Number: 201-766-0
MDL number: MFCD00064207
Molecular Formula: C4H6O6 / COOH(CHOH)2COOH / H2C4H4O6



SYNONYMS:
(+)-L-Tartaric acid, (+)-Tartaric acid, 87-69-4, L-(+)-Tartaric acid, L-Tartaric acid, L(+)-Tartaric acid, tartaric acid, (2R,3R)-2,3-dihydroxysuccinic acid, (2R,3R)-2,3-dihydroxybutanedioic acid, (R,R)-Tartaric acid, Threaric acid, L-threaric acid, Dextrotartaric acid, Acidum tartaricum, Natural tartaric acid, (+)-(R,R)-Tartaric acid, (2R,3R)-(+)-Tartaric acid, Tartaric acid, L-, Rechtsweinsaeure, Kyselina vinna, (2R,3R)-Tartaric acid, (R,R)-(+)-Tartaric acid, tartrate, Succinic acid, 2,3-dihydroxy, Weinsteinsaeure, L-2,3-Dihydroxybutanedioic acid, (2R,3R)-rel-2,3-Dihydroxysuccinic acid, 1,2-Dihydroxyethane-1,2-dicarboxylic acid, EINECS 201-766-0, (+)-Weinsaeure, 133-37-9, NSC 62778, FEMA No. 3044, INS NO.334, DTXSID8023632, UNII-W4888I119H, CHEBI:15671, Kyselina 2,3-dihydroxybutandiova, AI3-06298, Lamb protein (fungal), INS-334, (+/-)-Tartaric Acid, Butanedioic acid, 2,3-dihydroxy- (2R,3R)-, (R,R)-tartrate, NSC-62778, W4888I119H, Tartaric acid (VAN), DTXCID203632, E 334, E-334, RR-tartaric acid, (+)-(2R,3R)-Tartaric acid, Tartaric acid, L-(+)-, EC 201-766-0, TARTARIC ACID (L(+)-), Tartaric acid, Weinsaeure, BAROS COMPONENT TARTARIC ACID, L-2,3-DIHYDROXYSUCCINIC ACID, MFCD00064207, C4H6O6, L-tartarate, 4J4Z8788N8, 138508-61-9, (2R,3R)-2,3-Dihydroxybernsteinsaeure, Resolvable tartaric acid, d-alpha,beta-Dihydroxysuccinic acid, TARTARIC ACID (II), TARTARIC ACID [II], 144814-09-5, Kyselina 2,3-dihydroxybutandiova [Czech], REL-(2R,3R)-2,3-DIHYDROXYBUTANEDIOIC ACID, TARTARIC ACID (MART.), TARTARIC ACID [MART.], (1R,2R)-1,2-Dihydroxyethane-1,2-dicarboxylic acid, TARTARIC ACID (USP-RS), TARTARIC ACID [USP-RS], BUTANEDIOIC ACID, 2,3-DIHYDROXY-, (R-(R*,R*))-, Tartaric acid D,L, Butanedioic acid, 2,3-dihydroxy- (R-(R*,R*))-, TARTARIC ACID (EP MONOGRAPH), TARTARIC ACID [EP MONOGRAPH], Tartarate, L(+) tartaric acid, (2RS,3RS)-Tartaric acid, 2,3-dihydroxy-succinic acid, Traubensaeure, Vogesensaeure, Weinsaure, acide tartrique, acido tartarico, tartaric-acid, para-Weinsaeure, L-Threaric aci, 4ebt, NSC 148314, NSC-148314, (r,r)-tartarate, (+)-tartarate, l(+)tartaric acid, Tartaric acid; L-(+)-Tartaric acid, Tartaric acid (TN), (+-)-Tartaric acid, Butanedioic acid, 2,3-dihydroxy-, (R*,R*)-, L-(+) tartaric acid, (2R,3R)-Tartarate, 1d5r, DL TARTARIC ACID, TARTARICUM ACIDUM, 2,3-dihydroxy-succinate, TARTARIC ACID,DL-, SCHEMBL5762, TARTARIC ACID, DL-, Tartaric acid (JP17/NF), TARTARIC ACID [FCC], TARTARIC ACID [JAN], d-a,b-Dihydroxysuccinic acid, MLS001336057, L-TARTARIC ACID [MI], TARTARIC ACID [VANDF], DL-TARTARIC ACID [MI], CCRIS 8978, L-(+)-Tartaric acid, ACS, TARTARIC ACID [WHO-DD], CHEMBL1236315, L-(+)-Tartaric acid, BioXtra, TARTARICUM ACIDUM [HPUS], UNII-4J4Z8788N8, (2R,3R)-2,3-tartaric acid, CHEBI:26849, HMS2270G22, Pharmakon1600-01300044, TARTARIC ACID, DL- [II], TARTARIC ACID, (+/-)-, TARTARIC ACID,DL- [VANDF], HY-Y0293, STR02377, TARTARIC ACID [ORANGE BOOK], EINECS 205-105-7, Tox21_300155, (2R,3R)-2,3-dihydroxysuccinicacid, NSC759609, s6233, AKOS016843282, L-(+)-Tartaric acid, >=99.5%, CS-W020107, DB09459, NSC-759609, (2R,3R)-2,3-dihydroxy-succinic acid, Butanedioic acid, 2,3-dihydroxy-; Butanedioic acid, 2,3-dihydroxy-, (R-(R*,R*))-, CAS-87-69-4, L-(+)-Tartaric acid, AR, >=99%, TARTARIC ACID COMPONENT OF BAROS, (R*,R*)-2,3-dihydroxybutanedioic acid, NCGC00247911-01, NCGC00254043-01, BP-31012, SMR000112492, SBI-0207063.P001, (2R,3R)-rel-2,3-dihydroxybutanedioic acid, NS00074184, T0025, EN300-72271, (R*,R*)-(+-)-2,3-dihydroxybutanedioic acid, C00898, D00103, D70248, L-(+)-Tartaric acid, >=99.7%, FCC, FG, L-(+)-Tartaric acid, ACS reagent, >=99.5%, L-(+)-Tartaric acid, BioUltra, >=99.5% (T), J-500964, TARTARIC ACID, L-TARTARIC ACID, TARTRATE, (2R,3R)-2,3-DIHYDROXYSUCCINIC ACID, Tartaric, lev, 2,3-Dihydroxysuccinic acid, l-tartaric, 2,3-DIHYDROXYBUTANEDIOIC ACID, levo, [R-(R*,R*)]-2,3-Dihydroxybutanedioic acid, L-2,3-Dihydroxybutanedioic acid, ordinary tartaric acid, natural tartaric acid, d-tartaric acid, (+)-tartaric acid, dextrotartaric acid, d-α,β-dihydroxysuccinic acid, Weinsure, Weinsteinsure, (2R,3R)-(+)-Tartaric acid, L-Threaric acid, L-2,3-Dihydroxybutanedioic acid, (2R,3R)-2,3-Dihydroxysuccinic acid, J-520420, L-(+)-Tartaric acid, ReagentPlus(R), >=99.5%, L-(+)-Tartaric acid, SAJ first grade, >=99.5%, L-(+)-Tartaric acid, tested according to Ph.Eur., Butanedioic acid, 2,3-dihydroxy-, (R*,R*)-(+-)-, L-(+)-Tartaric acid, JIS special grade, >=99.5%, L-(+)-Tartaric acid, natural, >=99.7%, FCC, FG, L-(+)-Tartaric acid, p.a., ACS reagent, 99.0%, L-(+)-Tartaric acid, Vetec(TM) reagent grade, 99%, Q18226455, F8880-9012, Z1147451717, Butanedioic acid, 2,3-dihydroxy-, (theta,theta)-(+-)-, 000189E3-11D0-4B0A-8C7B-31E02A48A51F, L-(+)-Tartaric acid, puriss. p.a., ACS reagent, >=99.5%, L-(+)-Tartaric acid, certified reference material, TraceCERT(R), Tartaric acid, United States Pharmacopeia (USP) Reference Standard, L-(+)-Tartaric acid, anhydrous, free-flowing, Redi-Dri(TM), ACS reagent, >=99.5%, L-(+)-Tartaric acid, p.a., ACS reagent, reag. ISO, reag. Ph. Eur., 99.5%, Tartaric Acid, Pharmaceutical Secondary Standard; Certified Reference Material, 132517-61-4, 2,3-Dihydroxybutanedioic acid, l-tartaric acid, l-+-tartaric acid, l +-tartaric acid, 2r,3r-2,3-dihydroxysuccinic acid, tartaric acid, 2r,3r-2,3-dihydroxybutanedioic acid, r,r-tartaric acid, #NAME?, dextrotartaric acid, l-threaric acid, L-Tartaric acid, L-2,3-dihydroxybutanedioic acid, L-2,3-dihydroxysuccinic acid



L(+)-Tartaric acid is registered under the REACH Regulation and is manufactured in and / or imported to the European Economic Area, at ≥ 10 000 to < 100 000 tonnes per annum.
L(+)-Tartaric acid is a tetraric acid that is butanedioic acid substituted by hydroxy groups at positions 2 and 3.


L(+)-Tartaric acid is a conjugate acid of a L-tartrate(1-).
L(+)-Tartaric acid is an enantiomer of a D-tartaric acid.
L(+)-Tartaric acid belongs to the group of carboxylic acids, and is abundantly found in grapes and wine.


L(+)-Tartaric acid is colorless or translucent crystals, or a white, fine granular, crystalline powder.
L(+)-Tartaric acid is odorless, has an acid taste, and is stable in air.
L-tartaric acid is a tartaric acid.


L(+)-Tartaric acid is a conjugate acid of a L-tartrate(1-).
L(+)-Tartaric acid is an enantiomer of a D-tartaric acid.
L(+)-Tartaric acid occurs as colorless monoclinic crystals, or a white or almost white crystalline powder.


L(+)-Tartaric acid is odorless, with an extremely tart taste.
L-(+)-Tartaric Acid is a naturally occurring chemical compound found in berries, grapes and various wines.
L(+)-Tartaric acid provides antioxidant properties and contributes to the sour taste within these products


L(+)-Tartaric acid is a white, crystalline organic acid, that occurs naturally in many fruits, is the primary acid component in wine grapes, is a dihydroxy dicarboxylic acid that occurs naturally in grapes.
L(+)-Tartaric acid is an orally active weak organic acid that can be isolated from grapes.


L(+)-Tartaric acid has vasodilatory and antihypertensive effects.
L(+)-Tartaric acid is soluble in water, methanol and acetone.
L(+)-Tartaric acid is incompatible with oxidizing agents, bases and reducing agents.


L(+)-Tartaric acid belongs to the class of organic compounds known as sugar acids and derivatives.
Sugar acids and derivatives are compounds containing a saccharide unit which bears a carboxylic acid group.
L(+)-Tartaric acid is a white crystalline organic acid that occurs naturally in many plants, most notably in grapes.


Tartaric is an alpha-hydroxy-carboxylic acid, is diprotic and aldaric in acid characteristics, and is a dihydroxyl derivative of succinic acid.
L(+)-Tartaric acid is a colourless or translucent crystals, or white, fine to granular, crystalline powder; odourless.
L(+)-Tartaric acid is an endogenous metabolite.


L(+)-Tartaric acid is the primary nonfermentable soluble acid in grapes and the principal acid in wine.
L(+)-Tartaric acid is abundant in nature, especially in fruits.
L(+)-Tartaric acid's primary commercial source is as a byproduct of the wine industry.


Industrial uses of L(+)-Tartaric acid include tanning, ceramics manufacture, and the production of tartrate esters for lacquers and textile printing.
L(+)-Tartaric acid is a colourless or translucent crystals, or white, fine to granular, crystalline powder; odourless.
L(+)-Tartaric acid is a naturally occurring carboxylic acid widely present in fruits like grapes, apricots, and apples.


Its significance extends beyond culinary applications, as L(+)-Tartaric acid plays a vital role in wine production, contributing to the beverage′s distinct tartness and flavor.
Throughout history, L(+)-Tartaric acid has been used in food and beverage production, but its utility has expanded into diverse scientific research areas in recent years, encompassing both in vivo and in vitro studies.


In scientific research, L(+)-Tartaric acid has been employed in various in vivo studies, where it is administered to animal models to investigate its effects on the body.
Additionally, in vitro studies utilize cell cultures and laboratory techniques to explore how L(+)-Tartaric acid impacts cellular processes.


The mechanism of action for L(+)-Tartaric acid is believed to involve its interaction with and activation of several enzymes, such as protein kinases and phosphatases.
These enzymes play pivotal roles in multiple cellular processes, including cell growth, differentiation, and apoptosis.


L(+)-Tartaric acid is a metabolite found in or produced by Escherichia coli.
L(+)-Tartaric acid is a white crystalline dicarboxylic acid found in many plants, particularly tamarinds and grapes.
In high doses, this agent acts as a muscle toxin by inhibiting the production of malic acid, which could cause paralysis and maybe death.


L(+)-Tartaric acid is a white crystalline organic acid.
L(+)-Tartaric acid occurs naturally in many plants, particularly grapes and tamarinds, and is one of the main acids found in wine.
Salts of L(+)-Tartaric acid are known as tartrates.


L(+)-Tartaric acid is a dihydroxy derivative of dicarboxylic acid.
L(+)-Tartaric acid is a muscle toxin, which works by inhibiting the production of malic acid, and in high doses causes paralysis and death.
The minimum recorded fatal dose for a human is about 12 grams.


In spite of that, L(+)-Tartaric acid is included in many foods, especially sour-tasting sweets.
As a food additive, L(+)-Tartaric acid is used as an antioxidant with E number E334, tartrates are other additives serving as antioxidants or emulsifiers.
Naturally-occurring L(+)-Tartaric acid is chiral, meaning that it has molecules that are non-superimposable on their mirror-images.


L(+)-Tartaric acid is a useful raw material in organic chemistry for the synthesis of other chiral molecules.
The naturally occurring form of the acid is L(+)-Tartaric acid or dextrotartaric acid.
The mirror-image (enantiomeric) form, levotartaric acid or D-(-)-tartaric acid, and the achiral form, mesotartaric acid, can be made artificially.


Tartarate is believed to play a role in inhibiting kidney stone formation.
Most tartarate that is consumed by humans is metabolized by bacteria in the gastrointestinal tract -- primarily in the large instestine.
Only about 15-20% of consumed tartaric acid is secreted in the urine unchanged.


L(+)-Tartaric acid has been known to winemakers for centuries.
However, the chemical process for extraction was developed in 1769 by the Swedish chemist Carl Wilhelm Scheele.
L(+)-Tartaric acid played an important role in the discovery of chemical chirality.


This property of L(+)-Tartaric acid was first observed in 1832 by Jean Baptiste Biot, who observed its ability to rotate polarized light.
Louis Pasteur continued this research in 1847 by investigating the shapes of sodium ammonium tartrate crystals, which he found to be chiral.
By manually sorting the differently shaped crystals, Pasteur was the first to produce a pure sample of levotartaric acid.



USES and APPLICATIONS of L(+)-TARTARIC ACID:
L(+)-Tartaric acid is approved in the EEA and/or Switzerland for use in biocidal products more favourable for the environment, human or animal health.
L(+)-Tartaric acid is also important in the history of chemistry because Louis Pasteur, who most people think of mainly as a biologist, used it to demonstrate molecular chirality.


Pasteur’s notebooks that described his work, however, turned up missing after his death
L(+)-Tartaric acid is widely used as acidulant in beverage,and other foods, such as soft drinks, wine, candy, bread and some colloidal sweetmeats.
L(+)-Tartaric acid is used as an additive in many foods, such as soft drinks, bakery products, and candies.


L(+)-Tartaric acid is an authorised food additive.
L(+)-Tartaric acid is used in the following products: cosmetics and personal care products, washing & cleaning products, perfumes and fragrances and fillers, putties, plasters, modelling clay.


Other release to the environment of L(+)-Tartaric acid is likely to occur from: indoor use (e.g. machine wash liquids/detergents, automotive care products, paints and coating or adhesives, fragrances and air fresheners), outdoor use in long-life materials with low release rate (e.g. metal, wooden and plastic construction and building materials), indoor use in long-life materials with low release rate (e.g. flooring, furniture, toys, construction materials, curtains, foot-wear, leather products, paper and cardboard products, electronic equipment), outdoor use and indoor use in close systems with minimal release (e.g. cooling liquids in refrigerators, oil-based electric heaters).


Other release to the environment of L(+)-Tartaric acid is likely to occur from: indoor use in long-life materials with low release rate (e.g. flooring, furniture, toys, construction materials, curtains, foot-wear, leather products, paper and cardboard products, electronic equipment) and outdoor use in long-life materials with low release rate (e.g. metal, wooden and plastic construction and building materials).


L(+)-Tartaric acid can be found in products with material based on: stone, plaster, cement, glass or ceramic (e.g. dishes, pots/pans, food storage containers, construction and isolation material).
L(+)-Tartaric acid is used by consumers, in articles, by professional workers (widespread uses), in formulation or re-packing, at industrial sites and in manufacturing.


L(+)-Tartaric acid is used in the soft drink industry, confectionery products, bakery products, gelatin desserts, as an acidulant.
L(+)-Tartaric acid is used in photography, tanning, ceramics, manufacture of tartrate.
The common commercial esters are the diethyl and dibutyl derivatives used for lacquers and in textile printing.


L(+)-Tartaric acid is used pharmaceutic aid (buffering agent).
L(+)-Tartaric acid is widely utilized in pharmaceutical industries.
L(+)-Tartaric acid is used in soft drinks, confectionaries, food products, gelatin desserts and as a buffering agent.


L(+)-Tartaric acid forms a compound, TiCl2(O-i-Pr)2 with Diels-Alder catalyst and acta as a chelate agent in metal industries.
Owing to its efficient chelating property towards metal ions, L(+)-Tartaric acid is used in farming and metal industries for complexing micronutrients and for cleaning metal surfaces, respectively.


L(+)-Tartaric acid is widely used in drugs, food, and beverage industry.
L(+)-Tartaric acid is widely used as an acidulant in beverage and other foods.
L(+)-Tartaric acid is a wine industry byproduct that is used as a food additive and industrial chemical.


With its optical activity, L(+)-Tartaric acid is used as a chemical resolving agent to resolve DL-amino-butanol, an intermediate for the antitubercular drug.
And L(+)-Tartaric acid is used as a chiral pool to synthesize tartrate derivatives.


With its acidity, L(+)-Tartaric acid is used as a catalyst in the resin finishing of polyester fabric or pH value regulator in oryzanol production.
With its complexation, L(+)-Tartaric acid is used in electroplating, sulfur removal, and acid pickling.
L(+)-Tartaric acid is also used as a complexing agent, food additives screening agent or chelating agent in chemical analysis and pharmaceutical inspection, or as resist agent in dyeing.


With its reduction, L(+)-Tartaric acid is used as a reductive agent in manufacturing mirror chemically or imaging agent in photography.
L(+)-Tartaric acid is used in the following products: cosmetics and personal care products, fillers, putties, plasters, modelling clay, perfumes and fragrances and photo-chemicals.


L(+)-Tartaric acid is used in the following areas: building & construction work.
Other release to the environment of L(+)-Tartaric acid is likely to occur from: indoor use (e.g. machine wash liquids/detergents, automotive care products, paints and coating or adhesives, fragrances and air fresheners) and outdoor use.


L(+)-Tartaric acid is used in the following products: adhesives and sealants, fillers, putties, plasters, modelling clay, pH regulators and water treatment products, laboratory chemicals, paper chemicals and dyes, perfumes and fragrances, photo-chemicals, cosmetics and personal care products and pharmaceuticals.


Release to the environment of L(+)-Tartaric acid can occur from industrial use: formulation of mixtures and formulation in materials.
L(+)-Tartaric acid is used for the manufacture of: food products and chemicals.
L(+)-Tartaric acid can also complex with metal ion and can be used as a cleaning agent or polishing agent of the metal surface.


L(+)-Tartaric acid is used in the following products: adhesives and sealants, pH regulators and water treatment products, metal surface treatment products, photo-chemicals, fillers, putties, plasters, modelling clay, laboratory chemicals, perfumes and fragrances, pharmaceuticals and cosmetics and personal care products.


L(+)-Tartaric acid is used for the manufacture of: food products, chemicals and mineral products (e.g. plasters, cement).
Release to the environment of L(+)-Tartaric acid can occur from industrial use: as processing aid, in processing aids at industrial sites, in the production of articles, as an intermediate step in further manufacturing of another substance (use of intermediates) and as processing aid.


Release to the environment of L(+)-Tartaric acid can occur from industrial use: manufacturing of the substance and as an intermediate step in further manufacturing of another substance (use of intermediates).
L(+)-Tartaric acid is a natural occurring chemical, derived from grapes and some other fruit, and it is mainly used as acidulant in the beverage industry.


L(+)-Tartaric acid can also be produced industrially, through an enantioselective synthesis process; maintaining all the characteristics of the natural occurring product, but with a more competitive level.
L(+)-Tartaric acid is an high-quality product and has a specific optical rotation [α] 25 °D of +12.0° to +13°, it is extensively used in many industries, such as food, pharmaceutical industry, chemical and building material industries.


Synthetic L(+)-Tartaric acid is made under GMP and meets the most demanding international quality standards including Food Chemicals Codex, the U.S. and the British Pharmacopoeia.
L(+)-Tartaric acid is a food additive that is widely used in a variety of food products and beverages.


L(+)-Tartaric acid is a white crystalline powder with a sour taste.
In beverages it is commonly used as an acidulant.
It is also used as a catalyst in the resin finishing of polyester fabric, as a pH value regulator in oryzanol production, and as a complexing agent, screening agent, or chelating agent in chemical analysis and pharmaceutical inspection.


L(+)-Tartaric acid is used as an acidulant in wine, food, and beverages; a raw material in the production of emulsifiers; an excipient and buffering agent in pharmaceutical products; and in other applications in plaster and effervescent antacids.
L(+)-Tartaric acid is widely utilized in pharmaceutical industries.


L(+)-Tartaric acid forms a compound, TiCl2(O-i-Pr)2 with Diels-Alder catalyst and acta as a chelate agent in metal industries.
Owing to its efficient chelating property towards metal ions, L(+)-Tartaric acid is used in farming and metal industries for complexing micronutrients and for cleaning metal surfaces, respectively.


L(+)-Tartaric acid can be used as flavorings and antioxidants in a range of foods and beverages.
L(+)-Tartaric acid can be used in laser frequency doubling and optical limiting applications.
L(+)-Tartaric acid can be used as a flavorant and antioxidant for a range of foods and beverages.


L(+)-Tartaric acid is widely utilized in pharmaceutical industries.
It is used in soft drinks, confectionaries, food products, gelatin desserts and as a buffering agent.
L(+)-Tartaric acid forms a compound, TiCl2(O-i-Pr)2 with Diels-Alder catalyst and acta as a chelate agent in metal industries.


Owing to its efficient chelating property towards metal ions, L(+)-Tartaric acid is used in farming and metal industries for complexing micronutrients and for cleaning metal surfaces, respectively.
L(+)-Tartaric acid is added to other foods to give a sour taste, and is used as an antioxidant.


L(+)-Tartaric acid is used in soft drinks, confectionaries, food products, gelatin desserts and as a buffering agent.
L(+)-Tartaric acid is used in the following areas: building & construction work, formulation of mixtures and/or re-packaging, health services and mining.


L(+)-Tartaric acid is used to generate carbon dioxide through interaction with sodium bicarbonate following oral administration.
Carbon dioxide extends the stomach and provides a negative contrast medium during double contrast radiography.


-Pharmaceutical Applications:
L(+)-Tartaric acid is used in beverages, confectionery, food products, and pharmaceutical formulations as an acidulant.
L(+)-Tartaric acid may also be used as a sequestering agent and as an antioxidant synergist.

In pharmaceutical formulations, L(+)-Tartaric acid is widely used in combination with bicarbonates, as the acid component of effervescent granules, powders, and tablets.
L(+)-Tartaric acid is also used to form molecular compounds (salts and cocrystals) with active pharmaceutical ingredients to improve physicochemical properties such as dissolution rate and solubility.



FUNCTIONAL USES OF L(+)-TARTARIC ACID:
Synergist for antioxidants, acid, sequestrant, flavouring agent



FUNCTIONS AND USAGE OF L(+)-TARTARIC ACID:
L(+)-Tartaric acid is widely used as acidulant in beverage,and other foods, such as soft drinks, wine, candy, bread and some colloidal sweetmeats.
With its optical activity, L(+)-Tartaric acid is used as chemical resolving agent to resolve DL-amino-butanol, an intermediate for antitubercular drug.

And L(+)-Tartaric acid is used as chiral pool to synthesize tartrate derivatives.
With its acidity, L(+)-Tartaric acid is used as catalyst in the resin finishing of polyester fabric or pH value regulator in oryzanol production.

With its complexation, L(+)-Tartaric acid is used in electroplating, sulfur removal and acid pickling.
L(+)-Tartaric acid is also used as complexing agent, screening agent or chelating agent in chemical analysis and pharmaceutical inspection, or as resist agent in dyeing.

With its reduction, L(+)-Tartaric acid is used as reductive agent in manufacturing mirror chemically or imaging agent in photography.
L(+)-Tartaric acid can also complex with metal ion and can be used as cleaning agent or polishing agent of metal surface.



ALTERNATIVE PARENTS OF L(+)-TARTARIC ACID:
*Short-chain hydroxy acids and derivatives
*Beta hydroxy acids and derivatives
*Monosaccharides
*Fatty acids and conjugates
*Dicarboxylic acids and derivatives
*Alpha hydroxy acids and derivatives
*Secondary alcohols
*1,2-diols
*Carboxylic acids
*Organic oxides
*Hydrocarbon derivatives
*Carbonyl compounds



SUBSTITUENTS OF L(+)-TARTARIC ACID:
*Sugar acid
*Short-chain hydroxy acid
*Beta-hydroxy acid
*Fatty acid
*Monosaccharide
*Hydroxy acid
*Dicarboxylic acid or derivatives
*Alpha-hydroxy acid
*Secondary alcohol
*1,2-diol
*Carboxylic acid
*Carboxylic acid derivative
*Organic oxide
*Hydrocarbon derivative
*Carbonyl group
*Alcohol
*Aliphatic acyclic compound



CHEMICAL PROPERTIES OF L(+)-TARTARIC ACID:
L(+)-Tartaric acid occurs as colorless monoclinic crystals, or a white or almost white crystalline powder.
L(+)-Tartaric acid is odorless, with an extremely tart taste.
L(+)-Tartaric acid is a naturally occurring chemical compound found in berries, grapes and various wines.
L(+)-Tartaric acid provides antioxidant properties and contributes to the sour taste within these products.



PRODUCTION METHODS OF L(+)-TARTARIC ACID:
L(+)-Tartaric acid occurs naturally in many fruits as the free acid or in combination with calcium, magnesium, and potassium.
Commercially, L(+)-Tartaric acid is manufactured from potassium tartrate (cream of tartar), a by-product of wine making.
Potassium tartrate is treated with hydrochloric acid, followed by the addition of a calcium salt to produce insoluble calcium tartrate.
This precipitate is then removed by filtration and reacted with 70% sulfuric acid to yield tartaric acid and calcium sulfate.



BIOCHEM/PHYSIOL ACTIONS OF L(+)-TARTARIC ACID:
L(+)-Tartaric acid serves as a donor ligand for biological processes.
L(+)-Tartaric acid is used as a food additive in candies and soft drinks to impart a sour taste.



STORAGE OF L(+)-TARTARIC ACID:
The bulk material is stable and should be stored in a well-closed container in a cool, dry place.



INCOMPATIBILITIES OF L(+)-TARTARIC ACID:
L(+)-Tartaric acid is incompatible with silver and reacts with metal carbonates and bicarbonates (a property exploited in effervescent preparations).



STEREOCHEMISTRY OF L(+)-TARTARIC ACID:
Naturally occurring form of the acid is dextro tartaric acid or L(+)-Tartaric acid (obsolete name d-tartaric acid).
Because L(+)-Tartaric acid is available naturally, it is cheaper than its enantiomer and the meso isomer.

The dextro and levo prefixes are archaic terms.
Modern textbooks refer to the natural form as (2R,3R)-tartaric acid (L(+)-Tartaric acid), and its enantiomer as (2S,3S)-tartaric acid (D-(-)-tartaric acid).
The meso diastereomer is referred to as (2R,3S)-tartaric acid or (2S,3R)-tartaric acid.

Dextro and levo form monoclinic sphenoidal crystals and orthorhombic crystals.
Racemic tartaric acid forms monoclinic and triclinic crystals (space group P1).
Anhydrous meso tartaric acid form two anhydrous polymorphs: triclinic and orthorhombic.

Monohydrated meso tartaric acid crystallizes as monoclinic and triclinic polymorphys depending on the temperature at which crystallization from aqueous solution occurs.
Tartaric acid in Fehling's solution binds to copper(II) ions, preventing the formation of insoluble hydroxide salts.



PHYSICAL and CHEMICAL PROPERTIES of L(+)-TARTARIC ACID:
CAS number: 87-69-4
EC number: 201-766-0
Grade: Ph Eur, BP, ChP, JP, NF, E 334
Hill Formula: C₄H₆O₆
Chemical formula: HOOCCH(OH)CH(OH)COOH
Molar Mass: 150.09 g/mol
HS Code: 2918 12 00
Density: 1.76 g/cm³ (20 °C)
Flash point: 150 °C
Ignition temperature: 425 °C
Melting Point: 170 - 172 °C
pH value: 1.6 (100 g/l, H₂O, 25 °C)
Vapor pressure: Bulk density: 1000 kg/m³
Solubility: 1390 g/l

CAS: 87-69-4
Molecular Formula: HO2CCH(OH)CH(OH)CO2H
Molecular Weight: 150.09 g/mol
Storage Details: Ambient
Harmonised Tariff Code: 2918120000
CAS: 87-69-4
Molecular Formula: C4H6O6
Molecular Weight (g/mol): 150.09
MDL Number: MFCD00064207
InChI Key: FEWJPZIEWOKRBE-UHFFFAOYNA-N
Molecular Weight: 150.09
Appearance Form: crystalline
Color: white
Odor: No data available
Odor Threshold: No data available


pH: 1,0 - 2 at 150 g/l at 25 °C
Melting point/freezing point:
Melting point/range: 170 - 172 °C - lit.
Initial boiling point and boiling range: 179,1 °C at 1.010 hPa
Flash point: 150 °C - closed cup
Evaporation rate: No data available
Flammability (solid, gas):
The product is not flammable.
Upper/lower flammability or explosive limits: No data available
Vapor pressure: < 0,05 hPa at 20 °C - NF T 20-048
Vapor density: 5,18 - (Air = 1.0)
Relative density: 1,76 g/cm³ at 20 °C -
Water solubility: 150 g/l at 20 °C - completely soluble

Partition coefficient: n-octanol/water log Pow: -1,91 at 20 °C - OECD
Bioaccumulation is not expected.
Autoignition temperature: 375 °C at 1.015 hPa - NF T 20-036
Decomposition temperature: > 170 °C -
Viscosity:
Viscosity, kinematic: No data available
Viscosity, dynamic: No data available
Explosive properties No data available
Flash Point: 150 °C/302 °F (Lit.)
Hazard Statements: H315-H319-H335
Melting Point: 166 - 176 °C
Optical Rotation: +12 ± 5° (c=2, water)

pH: 2.2 at 25 °C (0.1 N solution)(Lit.)
pKa: pKa1 = 2.98 at 25 °C; pKa2 = 4.34 at 25 °C (Lit.)
Purity: ≥99.0%
Vapor Density 5.18 (vs air)Lit.
Solubility:
Soluble in water (115 g/100 mL at 0 °C; 126 g/100 mL at 10 °C;
139 g/100 mL at 20 °C; 156 g/100 mL at 30 °C; 176 g/100 mL at 40 °C;
195 g/100 mL at 50 °C; 217 g/100 mL at 60 °C; 244 g/100 mL at 70 °C;
273 g/100 mL at 80 °C; 307 g/100 mL at 90 °C; 343 g/100 mL at 100 °C)
Methanol (1 g/1.7 mL)
Ethanol (1 g/3 mL)
Propanol (1 g/10.5 mL)
Ether (1 g/250 mL) or glycerol;
Insoluble in chloroform.

Appearance: Powder
Physical State: Solid
Solubility: Soluble in water
Storage: Store at room temperature
Melting Point: 170-172° C (lit.)
Optical Activity: α20/D +12.4°, c = 20 in water;
α20/D +12°±5°, c = 2 in water
Water Solubility: 161 g/L
logP: -1.3
logP: -1.8
logS: 0.03
pKa (Strongest Acidic): 2.72
pKa (Strongest Basic): -4.3
Physiological Charge: -2
Hydrogen Acceptor Count: 6
Hydrogen Donor Count: 4

Polar Surface Area: 115.06 Ų
Rotatable Bond Count: 3
Refractivity: 26.21 m³·mol⁻¹
Polarizability: 11.33 ų
Molecular Weight: 150.09 g/mol
XLogP3-AA: -1.9
Hydrogen Bond Donor Count: 4
Hydrogen Bond Acceptor Count: 6
Rotatable Bond Count: 3
Exact Mass: 150.01643791 g/mol
Monoisotopic Mass: 150.01643791 g/mol
Topological Polar Surface Area: 115 Ų
Heavy Atom Count: 10
Formal Charge: 0
Complexity: 134

Isotope Atom Count: 0
Defined Atom Stereocenter Count: 2
Undefined Atom Stereocenter Count: 0
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes
CAS Number: 87-69-4
Beilstein: 1725147
EC Number: 201-766-0
MDL number: MFCD00064207
PubChem CID: 444305
ChEBI: CHEBI:15671
IUPAC Name: (2R,3R)-2,3-dihydroxybutanedioic acid
SMILES: OC(C(O)C(O)=O)C(O)=O

IUPAC Name: (2R,3R)-2,3-dihydroxybutanedioic acid
Traditional IUPAC Name: L(+)-tartaric acid
Formula: C4H6O6
InChI: InChI=1S/C4H6O6/c5-1(3(7)8)2(6)4(9)10/h1-2,5-6H,(H,7,8)(H,9,10)/t1-,2-/m0/s1
InChI Key: FEWJPZIEWOKRBE-LWMBPPNESA-N
Molecular weight: 150.0868
Exact mass: 150.016437924
SMILES: OC@@HC(O)=O
Molecular Formula / Molecular Weight: C4H6O6 = 150.09
Physical State (20 deg.C): Solid
Storage Temperature: Room Temperature
(Recommended in a cool and dark place, <15°C)
CAS RN: 87-69-4
Reaxys Registry Number: 1725147

PubChem Substance ID: 87576049
Merck Index (14): 9070
MDL Number: MFCD00064207
CAS: 87-69-4
IUPAC Name: 2,3-dihydroxybutanedioic acid
Molecular Formula: C4H6O6
InChI Key: FEWJPZIEWOKRBE-UHFFFAOYNA-N
SMILES: OC(C(O)C(O)=O)C(O)=O
Molecular Weight (g/mol): 150.09
Synonym: (.+-.)-tartaric acid|L-(+)-tartaric acid
MDL Number: MFCD00064207
CAS NUMBER: 87-69-4
MOLECULAR WEIGHT: 150.10
BEILSTEIN REGISTRY NUMBER: 1725147
EC NUMBER: 201-766-0

MDL NUMBER: MFCD00064207
CBNumber: CB8212874
Molecular Formula: C4H6O6
Molecular Weight: 150.09
MDL Number: MFCD00064207
MOL File: 87-69-4.mol
Melting Point: 170-172 °C (lit.)
Alpha: 12º (c=20, H2O)
Boiling Point: 191.59°C (rough estimate)
Density: 1.76
Vapor Density: 5.18 (vs air)
Vapor Pressure: FEMA Number: 3044 | TARTARIC ACID (D-, L-, DL-, MESO-)
Refractive Index: 12.5 ° (C=5, H2O)

Flash Point: 210 °C
Storage Temperature: Store at +5°C to +30°C.
Solubility: H2O: soluble 1M at 20°C, clear, colorless
Form: Solid
pKa: 2.98, 4.34 (at 25°C)
Color: White or colorless
Odor: Odorless at 100.00%
pH: 3.18 (1 mM solution); 2.55 (10 mM solution); 2.01 (100 mM solution)
Odor Type: Odorless
Optical Activity: [α]20/D +13.5±0.5°, c = 10% in H2O
Water Solubility: 1390 g/L (20 °C)
Merck Index: 14, 9070
JECFA Number: 621

BRN: 1725147
Dielectric Constant: 35.9 (-10°C)
Stability: Stable.
Incompatible with oxidizing agents, bases, reducing agents.
InChIKey: FEWJPZIEWOKRBE-JCYAYHJZSA-N
LogP: -1.43
FDA 21 CFR: 184.1099; 582.1099; 582.6099
Substances Added to Food (formerly EAFUS): TARTARIC ACID, L
SCOGS (Select Committee on GRAS Substances): L(+)-tartaric acid
CAS DataBase Reference: 87-69-4 (CAS DataBase Reference)
FDA UNII: W4888I119H
NIST Chemistry Reference: Butanedioic acid, 2,3-dihydroxy- [r-(r*,r*)]-(87-69-4)
EPA Substance Registry System: Tartaric acid (87-69-4)



FIRST AID MEASURES of L(+)-TARTARIC ACID:
-Description of first-aid measures:
General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation: fresh air.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of L(+)-TARTARIC ACID:
-Personal precautions, protective equipment and emergency procedures:
Ensure adequate ventilation.
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Take up dry.
Clean up affected area.



FIRE FIGHTING MEASURES of L(+)-TARTARIC ACID:
-Extinguishing media:
Suitable extinguishing media:
Water Foam, Carbon dioxide (CO2), Dry powder
Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of L(+)-TARTARIC ACID:
-Control parameters:
Ingredients with workplace control parameters:
-Exposure controls:
Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles.
*Skin protection:
Protective clothing.
Protective boots, if the situation requires.
Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
Splash contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
*Body Protection:
Protective clothing.
*Hand protection:
Protective gloves.
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of L(+)-TARTARIC ACID:
-Conditions for safe storage, including any incompatibilities:
Storage conditions:
Tightly closed.
Dry.
-Precautions for safe handling:
*Technical measures:
Handling is performed in a well ventilated place.
Wear suitable protective equipment.
Wash hands and face thoroughlyafterhandling.
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Keep container tightly closed.
Store in a cool and dark place.



STABILITY and REACTIVITY of L(+)-TARTARIC ACID:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature).
-Incompatible materials:
No data available


L-(+)-TARTARIC ACID
L-(+)-Tartaric acid occurs as colorless monoclinic crystals, or a white or almost white crystalline powder.
L-(+)-Tartaric acid is odorless, with an extremely tart taste.
L-(+)-Tartaric acid is a naturally occurring chemical compound found in berries, grapes and various wines.

CAS Number: 87-69-4
Molecular Formula: C4H6O6
Molecular Weight: 150.09
EINECS Number: 201-766-0

Synonyms: ], Weinsaeure, BAROS COMPONENT TARTARIC ACID, L-2,3-DIHYDROXYSUCCINIC ACID, MFCD00064207, C4H6O6, L-tartarate, 4J4Z8788N8, 138508-61-9, (2R,3R)-2,3-Dihydroxybernsteinsaeure, Resolvable tartaric acid, d-alpha,beta-Dihydroxysuccinic acid, TARTARIC ACID (II), TARTARIC ACID [II], 144814-09-5, Kyselina 2,3-dihydroxybutandiova [Czech], REL-(2R,3R)-2,3-DIHYDROXYBUTANEDIOIC ACID, TARTARIC ACID (MART.), TARTARIC ACID [MART.], (1R,2R)-1,2-Dihydroxyethane-1,2-dicarboxylic acid, TARTARIC ACID (USP-RS), TARTARIC ACID [USP-RS], BUTANEDIOIC ACID, 2,3-DIHYDROXY-, (R-(R*,R*)), Tartaric acid D,L, Butanedioic acid, 2,3-dihydroxy- (R-(R*,R*)), TARTARIC ACID (EP MONOGRAPH), TARTARIC ACID [EP MONOGRAPH], Tartarate, L(+) tartaric acid, (2RS,3RS)-Tartaric acid, 2,3-dihydroxy-succinic acid, Traubensaeure, Vogesensaeure, Weinsaure, acide tartrique, acido tartarico, tartaric-acid, para-Weinsaeure, L-Threaric acid, 4ebt, NSC 148314, NSC-148314, (r,r)-tartarate, (+)-tartarate, l(+)tartaric acid, Tartaric acid; L-(+)-Tartaric acid, Tartaric acid (TN), (+/-)-Tartaric acid, Butanedioic acid, 2,3-dihydroxy-, (R*,R*), L-(+) tartaric acid, (2R,3R)-Tartarate, 1d5r, DL TARTARIC ACID, TARTARICUM ACIDUM, 2,3-dihydroxy-succinate, TARTARIC ACID,DL-, SCHEMBL5762, TARTARIC ACID, DL-, Tartaric acid (JP17/NF), TARTARIC ACID [FCC], TARTARIC ACID [JAN], d-a,b-Dihydroxysuccinic acid, MLS001336057, L-TARTARIC ACID [MI], TARTARIC ACID [VANDF], DL-TARTARIC ACID [MI], CCRIS 8978, L-(+)-Tartaric acid, ACS, TARTARIC ACID [WHO-DD], CHEMBL1236315, L-(+)-Tartaric acid, BioXtra, TARTARICUM ACIDUM [HPUS], UNII-4J4Z8788N8, (2R,3R)-2,3-tartaric acid, CHEBI:26849, HMS2270G22, Pharmakon1600-01300044, TARTARIC ACID, DL- [II], TARTARIC ACID, (+/-)-, TARTARIC ACID,DL- [VANDF], HY-Y0293, STR02377, TARTARIC ACID [ORANGE BOOK], EINECS 205-105-7, Tox21_300155, (2R,3R)-2,3-dihydroxysuccinicacid, NSC759609, s6233, AKOS016843282, L-(+)-Tartaric acid, >=99.5%, CS-W020107, DB09459, NSC-759609, (2R,3R)-2,3-dihydroxy-succinic acid, Butanedioic acid, 2,3-dihydroxy-; Butanedioic acid, 2,3-dihydroxy-, (R-(R*,R*)), CAS-87-69-4, L-(+)-Tartaric acid, AR, >=99%, TARTARIC ACID COMPONENT OF BAROS, (R*,R*)-2,3-dihydroxybutanedioic acid, NCGC00247911-01, NCGC00254043-01, BP-31012, SMR000112492, SBI-0207063.P001, (2R,3R)-rel-2,3-dihydroxybutanedioic acid, NS00074184, T0025, EN300-72271, (R*,R*)-(+-)-2,3-dihydroxybutanedioic acid, C00898, D00103, D70248, L-(+)-Tartaric acid, >=99.7%, FCC, FG, L-(+)-Tartaric acid, ACS reagent, >=99.5%, L-(+)-Tartaric acid, BioUltra, >=99.5% (T), J-500964, J-520420, L-(+)-Tartaric acid, ReagentPlus(R), >=99.5%, L-(+)-Tartaric acid, SAJ first grade, >=99.5%, L-(+)-Tartaric acid, tested according to Ph.Eur., Butanedioic acid, 2,3-dihydroxy-, (R*,R*)-(+-)-, L-(+)-Tartaric acid, JIS special grade, >=99.5%, L-(+)-Tartaric acid, natural, >=99.7%, FCC, FG, L-(+)-Tartaric acid, p.a., ACS reagent, 99.0%, L-(+)-Tartaric acid, Vetec(TM) reagent grade, 99%, Q18226455, F8880-9012, Z1147451717, Butanedioic acid, 2,3-dihydroxy-, (theta,theta)-(+-)-, 000189E3-11D0-4B0A-8C7B-31E02A48A51F, L-(+)-Tartaric acid, puriss. p.a., ACS reagent, >=99.5%, L-(+)-Tartaric acid, certified reference material, TraceCERT(R), Tartaric acid, United States Pharmacopeia (USP) Reference Standard, L-(+)-Tartaric acid, anhydrous, free-flowing, Redi-Dri(TM), ACS reagent, >=99.5%, L-(+)-Tartaric acid, p.a., ACS reagent, reag. ISO, reag. Ph. Eur., 99.5%, Tartaric Acid, Pharmaceutical Secondary Standard; Certified Reference Material.

L-(+)-Tartaric acid provides antioxidant properties and contributes to the sour taste within these products.
L-(+)-Tartaric acid belongs to the group of carboxylic acids, and is abundantly found in grapes and wine.
L-(+)-Tartaric acid is widely used in drugs, food, and beverage industry.

L-(+)-Tartaric acid occurs naturally in many fruits as the free acid or in combination with calcium, magnesium, and potassium.
Commercially, L-(+)-Tartaric acid is manufactured from potassium tartrate (cream of tartar), a by-product of wine making.
L-(+)-Tartaric acid is treated with hydrochloric acid, followed by the addition of a calcium salt to produce insoluble calcium tartrate.

This precipitate is then removed by filtration and reacted with 70% sulfuric acid to yield tartaric acid and calcium sulfate.
L-(+)-Tartaric acid is a white, crystalline organic acid that occurs naturally in many fruits, most notably in grapes but also in tamarinds, bananas, avocados, and citrus.
Its salt, potassium bitartrate, commonly known as cream of tartar, develops naturally in the process of fermentation.

L-(+)-Tartaric acid is commonly mixed with sodium bicarbonate and is sold as baking powder used as a leavening agent in food preparation.
The acid itself is added to foods as an antioxidant E334 and to impart its distinctive sour taste.
Naturally occurring tartaric acid is a useful raw material in organic chemical synthesis.

L-(+)-Tartaric acid, an alpha-hydroxy-carboxylic acid, is diprotic and aldaric in acid characteristics and is a dihydroxyl derivative of succinic acid.
L-(+)-Tartaric acid, also known as L-tartaric acid, is a naturally occurring organic acid commonly found in plants, particularly in grapes and bananas.
L-(+)-Tartaric acid is a type of tartaric acid with the chemical formula C4H6O6.

L-(+)-Tartaric acid is a tetraric acid that is butanedioic acid substituted by hydroxy groups at positions 2 and 3.
L-(+)-Tartaric acid is a conjugate acid of a L-tartrate(1-).
L-(+)-Tartaric acid is an enantiomer of a D-tartaric acid.

L-(+)-Tartaric acid serves as a donor ligand for biological processes.
L-(+)-Tartaric acid is used as a food additive in candies and soft drinks to impart a sour taste.
L-(+)-Tartaric acid has been known to winemakers for centuries.

However, the chemical process for extraction was developed in 1769 by the Swedish chemist Carl Wilhelm Scheele.
L-(+)-Tartaric acid played an important role in the discovery of chemical chirality.
This property of tartaric acid was first observed in 1832 by Jean Baptiste Biot, who observed its ability to rotate polarized light.

Louis Pasteur continued this research in 1847 by investigating the shapes of sodium ammonium tartrate crystals, which he found to be chiral.
By manually sorting the differently shaped crystals, Pasteur was the first to produce a pure sample of levotartaric acid.
Naturally occurring form of the acid is dextro tartaric acid or L-(+)-Tartaric acid (obsolete name d-tartaric acid).

Because it is available naturally, L-(+)-Tartaric acid is cheaper than its enantiomer and the meso isomer.
The dextro and levo prefixes are archaic terms.
Modern textbooks refer to the natural form as (2R,3R)-tartaric acid (L-(+)-tartaric acid), and its enantiomer as (2S,3S)-tartaric acid (D-(-)-tartaric acid).

The meso diastereomer is referred to as (2R,3S)-tartaric acid or (2S,3R)-tartaric acid.
L-(+)-Tartaric acid and levo form monoclinic sphenoidal crystals[13] and orthorhombic crystals.
Racemic tartaric acid forms monoclinic and triclinic crystals (space group P1).

L-(+)-Tartaric acid crystallizes as monoclinic and triclinic polymorphys depending on the temperature at which crystallization from aqueous solution occurs.
L-(+)-Tartaric acid in Fehling's solution binds to copper(II) ions, preventing the formation of insoluble hydroxide salts.
L-(+)-Tartaric acid isomer of tartaric acid is industrially produced in the largest amounts.

L-(+)-Tartaric acid is obtained from lees, a solid byproduct of fermentations.
The former byproducts mostly consist of potassium bitartrate (KHC4H4O6)
L-(+)-Tartaric acid may be most immediately recognizable to wine drinkers as the source of "wine diamonds", the small potassium bitartrate crystals that sometimes form spontaneously on the cork or bottom of the bottle.

These "tartrates" are harmless, despite sometimes being mistaken for broken glass, and are prevented in many wines through cold stabilization (which is not always preferred since it can change the wine's profile).
The tartrates remaining on the inside of aging barrels were at one time a major industrial source of potassium bitartrate.
L-(+)-Tartaric acid, or "natural" tartaric acid, is abundant in nature, especially in fruits.

Its primary commercial source is as a byproduct of the wine industry.
L-(+)-Tartaric acid is used as an additive in many foods, such as soft drinks, bakery products, and candies.
Industrial uses include tanning, ceramics manufacture, and the production of tartrate esters for lacquers and textile printing.

L-(+)-Tartaric acid is an endogenous metabolite. L-Tartaric acid is the primary nonfermentable soluble acid in grapes and the principal acid in wine.
L-(+)-Tartaric acid can be used as a flavorant and antioxidant for a range of foods and beverages.
L-(+)-Tartaric acid is an orally active weak organic acid that can be isolated from grapes.

L-(+)-Tartaric acid has vasodilatory and antihypertensive effects.
L-(+)-Tartaric acid can be used as flavorings and antioxidants in a range of foods and beverages.
L-(+)-Tartaric acid can be used in laser frequency doubling and optical limiting applications.

L-(+)-Tartaric acid is a white crystalline diprotic acid.
This aldaric acid occurs naturally in many plants, particularly grapes, bananas, and tamarinds, is commonly combined with baking soda to function as a leavening agent in recipes, and is one of the main acids found in wine.
L-(+)-Tartaric acid may be used in the synthesis of (R,R)-1,2-diammoniumcyclohexane mono-(+)-tartrate, an intermediate to prepare an enantioselective epoxidation catalyst.

L-(+)-Tartaric acid may also be used as a starting material in the multi-step synthesis of 1,4-di-O-benzyl-L-threitol.
L-(+)-Tartaric acid can be used a chiral resolving agent for the resolution of 2,2′-bispyrrolidine.
L-(+)-Tartaric acid is widely utilized in pharmaceutical industries.

It is used in soft drinks, confectionaries, food products, gelatin desserts and as a buffering agent.
L-(+)-Tartaric acid forms a compound, TiCl2(O-i-Pr)2 with Diels-Alder catalyst and acta as a chelate agent in metal industries.
Owing to its efficient chelating property towards metal ions, L-(+)-Tartaric acid is used in farming and metal industries for complexing micronutrients and for cleaning metal surfaces, respectively.

This is a natural acid extracted from grapes.
L-(+)-Tartaric acid is used to acidify musts and wines under conditions stipulated by regulation.
The label should indicate in a clear manner that the product is L-tartaric acid, sometimes written L(+)tartaric acid, since its rotatory power is positive.

L-(+)-Tartaric acid must also indicate the purity percentage (greater than 99.5%) and storage requirements.
L-(+)-Tartaric acid is a white crystalline organic acid that occurs naturally in many plants, most notably in grapes.
L-(+)-Tartaric acid is an alpha-hydroxy-carboxylic acid, is diprotic and aldaric in acid characteristics, and is a dihydroxyl derivative of succinic acid.

Used to impart a tart taste in food and beverages, including wine, soft drinks, and candies.
Helps in preserving foods due to its acidic properties.
Stabilizes the color of some foods and beverages.

L-(+)-Tartaric acid is used in combination with sodium bicarbonate to create effervescent tablets.
Acts as an excipient in pharmaceutical formulations.
L-(+)-Tartaric acid is used in cosmetics to adjust the pH level of products.

L-(+)-Tartaric acid utilized in skin care products for its exfoliating properties.
L-(+)-Tartaric acid is used in the textile and tanning industries to complex with metal ions.
Employed in the electroplating industry to adjust the pH of solutions.

Helps in acidifying wine musts and wines to achieve desired acidity levels.
Should be handled with care to avoid inhalation and contact with skin or eyes, as it can cause irritation.
Generally recognized as safe (GRAS) when used in food in accordance with good manufacturing practices.

Melting point: 170-172 °C(lit.)
alpha: 12 º (c=20, H2O)
Boiling point: 191.59°C (rough estimate)
Density: 1.76
vapor density: 5.18 (vs air)
vapor pressure: FEMA: 3044 | TARTARIC ACID (D-, L-, DL-, MESO-)
refractive index: 12.5 ° (C=5, H2O)
Flash point: 210 °C
storage temp.: Store at +5°C to +30°C.
solubility: H2O: soluble1M at 20°C, clear, colorless
form: Solid
pka: 2.98, 4.34(at 25℃)
color: White or colorless
Odor: at 100.00 %. odorless
PH: 3.18(1 mM solution);2.55(10 mM solution);2.01(100 mM solution);
Odor Type: odorless
optical activity: [α]20/D +13.5±0.5°, c = 10% in H2O
Water Solubility: 1390 g/L (20 ºC)
Merck: 14,9070
JECFA Number: 621
BRN: 1725147
Dielectric constant: 35.9(-10℃)
Stability: Stable. Incompatible with oxidizing agents, bases, reducing agents. Combustible.
InChIKey: FEWJPZIEWOKRBE-JCYAYHJZSA-N
LogP: -1.43

L-(+)-Tartaric acid is incompatible with silver and reacts with metal carbonates and bicarbonates (a property exploited in effervescent preparations).
L-(+)-Tartaric acid is a white crystalline diprotic acid.
This aldaric acid occurs naturally in many plants, particularly grapes,bananas, and tamarinds, is commonly combined with baking soda to function as a leavening agent in recipes, and is one of the main acids found in wine.

L-(+)-Tartaric acid is also added to other foods to give a sour taste, and is used as an antioxidant.
Salts of L-(+)-Tartaric acid are known as tartrates.
L-(+)-Tartaric acid is a dihydroxyl derivative of succinic acid.

L-(+)-Tartaric acid is a muscle toxin, which works by inhibiting the production of malic acid, and in high doses causes paralysis and death.
The median lethal dose (LD50) is about 7.5 grams/kg for a human, 5.3 grams/kg for rabbits, and 4.4 grams/kg for mice.
Given this figure, it would take over 500 g (18 oz) to kill a person weighing 70 kg (150 lb) with 50% probability, so it may be safely included in many foods, especially sour-tasting sweets.

As a food additive, tartaric acid is used as an antioxidant with E number E334; tartrates are other additives serving as antioxidants or emulsifiers.
L-(+)-Tartaric acid plays an important role chemically, lowering the pH of fermenting "must" to a level where many undesirable spoilage bacteria cannot live, and acting as a preservative after fermentation.
In the mouth, L-(+)-Tartaric acid provides some of the tartness in the wine, although citric and malic acids also play a role.

L-(+)-Tartaric acid is a white crystalline diprotic acid.
This aldaric acid occurs naturally in many plants, particularly grapes,bananas, and tamarinds, is commonly combined with baking soda to function as a leavening agent in recipes, and is one of the main acids found in wine.

L-(+)-Tartaric acid is also added to other foods to give a sour taste, and is used as an antioxidant.
L-(+)-Tartaric acid is a dihydroxyl derivative of succinic acid.
As a chiral molecule, L-(+)-tartaric acid is used to resolve and separate racemic mixtures into their enantiomers in chemical synthesis and pharmaceutical manufacturing.

L-(+)-Tartaric acid serves as a catalyst in organic reactions, particularly in asymmetric synthesis.
Used in medicine as a chelating agent for certain metal ions and in some medical treatments.
Sometimes used as a dietary supplement due to its antioxidant properties and potential health benefits.

Utilized as a standard reference material in analytical chemistry for calibration and quality control purposes.
Used in laboratories as a reagent for experimental work and research studies in various fields of science.
L-(+)-Tartaric acid is biodegradable and does not persist in the environment under normal conditions.

Generally recognized as safe (GRAS) by regulatory authorities when used in food and pharmaceutical applications.
Proper handling and storage procedures should be followed to prevent exposure and ensure safety.

Widely available from chemical suppliers, pharmaceutical companies, and food ingredient distributors.
Typically sold as a white crystalline powder or as a solution in water.

Uses:
In the soft drink industry, confectionery products, bakery products, gelatin desserts, as an acidulant.
In photography, tanning, ceramics, manufacture of tartrates.
The common commercial esters are the diethyl and dibutyl derivatives used for lacquers and in textile printing. Pharmaceutic aid (buffering agent).

L-(+)-Tartaric acid may be used in the synthesis of (R,R)-1,2-diammoniumcyclohexane mono-(+)-tartrate, an intermediate to prepare an enantioselective epoxidation catalyst.
L-(+)-Tartaric acid may also be used as a starting material in the multi-step synthesis of 1,4-di-O-benzyl-L-threitol.
L-(+)-Tartaric acid can be used a chiral resolving agent for the resolution of 2,2′-bispyrrolidine.

L-(+)-Tartaric acid is widely utilized in pharmaceutical industries.
It is used in soft drinks, confectionaries, food products, gelatin desserts and as a buffering agent.
It forms a compound, TiCl2(O-i-Pr)2 with Diels-Alder catalyst and acta as a chelate agent in metal industries.

Owing to its efficient chelating property towards metal ions, it is used in farming and metal industries for complexing micronutrients and for cleaning metal surfaces, respectively.
L-(+)-Tartaric acid is used in beverages, confectionery, food products, and pharmaceutical formulations as an acidulant.
L-(+)-Tartaric acid may also be used as a sequestering agent and as an antioxidant synergist.

In pharmaceutical formulations, it is widely used in combination with bicarbonates, as the acid component of effervescent granules, powders, and tablets.
L-(+)-Tartaric acid is also used to form molecular compounds (salts and cocrystals) with active pharmaceutical ingredients to improve physicochemical properties such as dissolution rate and solubility.
L-(+)-Tartaric acid and its derivatives have a plethora of uses in the field of pharmaceuticals.

For example, it has been used in the production of effervescent salts, in combination with citric acid, to improve the taste of oral medications.
The potassium antimonyl derivative of the acid known as tartar emetic is included, in small doses, in cough syrup as an expectorant.
L-(+)-Tartaric acid also has several applications for industrial use.

The acid has been observed to chelate metal ions such as calcium and magnesium.
Therefore, the acid has served in the farming and metal industries as a chelating agent for complexing micronutrients in soil fertilizer and for cleaning metal surfaces consisting of aluminium, copper, iron, and alloys of these metals, respectively.
L-(+)-Tartaric acid is widely used as an acidulant in the food industry to impart a sour taste to various products such as beverages (e.g., soft drinks), candies, jams, jellies, and fruit juices.

L-(+)-Tartaric acid is used in baking powder formulations where it reacts with sodium bicarbonate to produce carbon dioxide, causing dough to rise.
In winemaking, L-(+)-Tartaric acid helps adjust and balance acidity levels in grape musts and wines, which is crucial for flavor development and stability.
Due to its chiral nature, L-(+)-tartaric acid is used for resolving racemic mixtures into their respective enantiomers, a process important in pharmaceutical synthesis to produce single-isomer drugs.

L-(+)-Tartaric acid is used in dietary supplements due to its antioxidant properties and potential health benefits.
L-(+)-Tartaric acid is employed in cosmetics and personal care products as a pH adjuster to ensure formulations maintain the desired acidity or alkalinity.
It serves as an ingredient in skin care products for its exfoliating properties and ability to promote skin renewal.

L-(+)-Tartaric acid is used in textile dyeing and printing processes as a mordant to enhance dye uptake and color retention.
It acts as a chelating agent to remove rust and scale from metals in industrial cleaning processes.
L-(+)-Tartaric acid is used as a standard reference material in analytical chemistry for calibration purposes, especially in techniques like chromatography.

L-(+)-Tartaric acid is utilized in electroplating baths to adjust and control the pH of solutions.
L-(+)-Tartaric acid serves as a reagent in various laboratory experiments and research studies.
L-(+)-Tartaric acid is biodegradable and does not persist in the environment.

L-(+)-Tartaric acid is generally recognized as safe (GRAS) for use in food and pharmaceutical applications, though proper handling and storage practices are recommended.
L-(+)-Tartaric acid and its derivatives are utilized as catalysts in chemical reactions, particularly in asymmetric synthesis where the chiral center influences reaction selectivity and efficiency.
L-(+)-Tartaric acid acts as a complexing agent for metal ions in chemical processes and formulations.

L-(+)-Tartaric acid is used in agriculture as an ingredient in certain pesticides and herbicides, contributing to their effectiveness and stability.
In water treatment, L-(+)-Tartaric acid is sometimes used as a scale inhibitor to prevent the buildup of scale deposits in pipes and equipment.
L-(+)-Tartaric acid has historical use in photography as a component of developing solutions for photographic films and papers.

L-(+)-Tartaric acid is included in some oral care products such as toothpaste and mouthwash for its tartar-control properties.
In the pyrotechnics industry, L-(+)-Tartaric acid is used to produce special effects in fireworks due to its ability to enhance coloration.
L-(+)-Tartaric acid is employed in leather tanning processes to modify leather properties and improve quality.

L-(+)-Tartaric acid is considered environmentally friendly due to its biodegradable nature, minimizing environmental impact during use and disposal.
L-(+)-Tartaric acid is derived from natural sources such as grapes and other fruits, aligning with sustainable sourcing practices.

Increasing focus on green chemistry principles is likely to drive innovation in the use of L-(+)-Tartaric acid and its derivatives in environmentally sustainable manufacturing processes.
Ongoing research explores new applications of L-(+)-Tartaric acid in functional foods and nutraceuticals, leveraging its health-promoting properties.

Safety Profile:
Moderately toxic by intravenous route.
Mildly toxic by ingestion.
Reaction with silver produces the unstable silver tartrate.

When heated to decomposition L-(+)-Tartaric acid emits acrid smoke and irritating fumes.
L-(+)-Tartaric acid is widely used in food products and oral, topical, and parenteral pharmaceutical formulations.
L-(+)-Tartaric acid is generally regarded as a nontoxic and nonirritant material; however, strong tartaric acid solutions are mildly irritant and if ingested undiluted may cause gastroenteritis.

Direct contact with L-(+)-Tartaric acid in its solid form or concentrated solutions may cause irritation to the skin, especially in individuals with sensitive skin or prolonged exposure.
Contact with the eyes can cause irritation, redness, and discomfort.
Immediate flushing with water is recommended in case of accidental exposure.

Inhalation of dust or aerosolized particles of L-(+)-Tartaric acid may irritate the respiratory tract, leading to coughing, shortness of breath, or respiratory discomfort.
Ingestion of large quantities of L-(+)-Tartaric acid may cause gastrointestinal irritation, nausea, vomiting, or abdominal discomfort.

L-(+)-TARTARIC ACID

L-(+)-Tartaric acid, commonly known as tartaric acid, is a naturally occurring organic acid found in many plants, particularly in grapes.
L-(+)-Tartaric acid is a white, crystalline solid that is soluble in water and alcohol.
Chemically, tartaric acid belongs to the class of dicarboxylic acids, characterized by having two carboxyl groups (COOH) attached to a carbon chain.

CAS Number: 87-69-4
EC Number: 201-766-0

Tartaric acid, (+)-Tartaric acid, D-Tartaric acid, L-Tartaric acid, 2,3-Dihydroxybutanedioic acid, 2,3-Dihydroxysuccinic acid, Threaric acid, Threoinic acid, Uvic acid, (-)-Tartaric acid, (R)-Tartaric acid, (R)-(+)-Tartaric acid, (R)-(-)-Tartaric acid, L(+)-Tartaric acid, (2R,3R)-2,3-Dihydroxybutanedioic acid, (2R,3R)-2,3-Dihydroxysuccinic acid



APPLICATIONS


L-(+)-Tartaric acid is commonly used in the food and beverage industry as an acidulant and flavoring agent.
L-(+)-Tartaric acid is added to foods and beverages to impart a tart taste and enhance flavor.
L-(+)-Tartaric acid is used in the production of fruit-flavored candies, jams, and jellies.

L-(+)-Tartaric acid is a key ingredient in baking powder, where it reacts with sodium bicarbonate to produce carbon dioxide gas, which leavens baked goods.
L-(+)-Tartaric acid is utilized in winemaking to adjust the acidity of grape must and balance the flavors of wine.

L-(+)-Tartaric acid is added to wine during fermentation to promote clarity and stability.
L-(+)-Tartaric acid is used in the pharmaceutical industry as an ingredient in medications and supplements.

L-(+)-Tartaric acid is utilized as an acidulant and flavoring agent in effervescent tablets and vitamin formulations.
Tartaric acid is employed in the cosmetic industry in skincare products such as exfoliating scrubs and chemical peels.

L-(+)-Tartaric acid helps to remove dead skin cells, unclog pores, and promote skin renewal.
L-(+)-Tartaric acid is used in the production of metal cleaning solutions and rust removers.
L-(+)-Tartaric acid acts as a chelating agent, binding to metal ions and facilitating their removal from surfaces.

Tartaric acid is utilized in the textile industry for dyeing and finishing processes.
L-(+)-Tartaric acid helps to fix dyes to fibers and improve colorfastness.

L-(+)-Tartaric acid is added to cleaning agents and detergents as a pH buffer and water softener.
L-(+)-Tartaric acid enhances the cleaning efficiency of these products and prevents mineral deposits on surfaces.

Tartaric acid is used in the manufacturing of adhesives and sealants as a cross-linking agent.
L-(+)-Tartaric acid helps to improve the adhesion and durability of these materials.
L-(+)-Tartaric acid is employed in the production of photography chemicals as a developing agent.

L-(+)-Tartaric acid helps to reduce silver halides to metallic silver during film processing.
L-(+)-Tartaric acid is used in the leather industry for tanning and finishing processes.
L-(+)-Tartaric acid helps to stabilize collagen fibers and improve the quality of leather products.

L-(+)-Tartaric acid is utilized in the production of ceramics and glass as a fluxing agent.
L-(+)-Tartaric acid lowers the melting point of raw materials and promotes uniform melting and shaping.
Tartaric acid is employed in agricultural applications as a soil conditioner and plant nutrient.

L-(+)-Tartaric acid is utilized in the production of carbonated beverages as a flavoring agent and acidity regulator.
L-(+)-Tartaric acid enhances the tartness and refreshment of soft drinks, colas, and sparkling water.
L-(+)-Tartaric acid is added to fruit juices and fruit-flavored drinks to balance sweetness and acidity.

In the confectionery industry, L-(+)-Tartaric acid is used to impart a sour taste to candies, gummies, and sour powders.
L-(+)-Tartaric acid contributes to the tanginess and flavor intensity of sour candies and confectionery products.

L-(+)-Tartaric acid is employed in the preparation of gelatin desserts and fruit-flavored gelatin molds.
L-(+)-Tartaric acid helps to stabilize gelatin and improve its texture and consistency.

The compound is added to canned fruits and vegetables as a preservative to maintain color and freshness.
L-(+)-Tartaric acid is utilized in the production of fruit jams, jellies, and preserves to enhance flavor and promote gel formation.

L-(+)-Tartaric acid is added to salad dressings and marinades as a flavor enhancer and emulsifying agent.
L-(+)-Tartaric acid is used in the brewing industry to adjust the acidity of beer and improve flavor stability.

L-(+)-Tartaric acid helps to balance the sweetness and bitterness of beer and prevent off-flavors.
The compound is employed in the dairy industry in the production of yogurt and cheese to enhance acidity and texture.

L-(+)-Tartaric acid is utilized in the textile printing process as a mordant to fix dyes to fabrics and improve color retention.
It is added to metalworking fluids as a corrosion inhibitor and pH buffer to protect metal surfaces from rust and degradation.

L-(+)-Tartaric acid is used in electroplating solutions as a complexing agent to improve the deposition of metal coatings.
L-(+)-Tartaric acid is added to antifreeze solutions as a pH buffer and stabilizer to prevent corrosion in automotive cooling systems.

L-(+)-Tartaric acid is employed in the production of synthetic resins and polymers as a cross-linking agent to improve mechanical properties.
L-(+)-Tartaric acid is used in the manufacture of paper and pulp to adjust pH levels and enhance pulp bleaching processes.

L-(+)-Tartaric acid is utilized in the oil and gas industry in the production of drilling fluids as a pH buffer and viscosity modifier.
L-(+)-Tartaric acid is added to water treatment chemicals as a scale inhibitor to prevent mineral deposits in pipes and equipment.

L-(+)-Tartaric acid is used in the production of detergents and cleaning agents as a chelating agent to remove metal ions and improve cleaning efficiency.
L-(+)-Tartaric acid is employed in the construction industry as an additive in cement and concrete formulations to improve workability and reduce setting time.

L-(+)-Tartaric acid is added to personal care products such as toothpaste and mouthwash as a pH adjuster and tartar control agent.
Overall, L-(+)-Tartaric acid plays a vital role in a wide range of applications across numerous industries, contributing to its versatility and importance.



DESCRIPTION


L-(+)-Tartaric acid, commonly known as tartaric acid, is a naturally occurring organic acid found in many plants, particularly in grapes.
L-(+)-Tartaric acid is a white, crystalline solid that is soluble in water and alcohol.
Chemically, tartaric acid belongs to the class of dicarboxylic acids, characterized by having two carboxyl groups (COOH) attached to a carbon chain.

The chemical formula of L-(+)-Tartaric acid is C4H6O6, and its molar mass is approximately 150.09 grams per mole.
L-(+)-Tartaric acid is optically active and exists in two enantiomeric forms: L-(+)-tartaric acid and D-(-)-tartaric acid.
The L-(+)-tartaric acid isomer is the biologically active form found in living organisms.

L-(+)-Tartaric acid has a variety of applications across different industries.
In the food and beverage industry, it is commonly used as an acidulant and flavoring agent.
L-(+)-Tartaric acid contributes to the tartness of certain foods and beverages and is often added to jams, jellies, soft drinks, and wine to enhance their flavor profile.

L-(+)-Tartaric acid is a naturally occurring organic compound found in many fruits, particularly grapes.
L-(+)-Tartaric acid is a white, crystalline solid with a tart taste and acidic smell.
The chemical formula of L-(+)-Tartaric acid is C4H6O6, and its molar mass is approximately 150.09 grams per mole.

L-(+)-Tartaric acid is optically active and exists in two enantiomeric forms: L-(+)-tartaric acid and D-(-)-tartaric acid.
L-(+)-Tartaric acid is soluble in water and alcohol, making it versatile for various applications.

L-(+)-Tartaric acid has two carboxylic acid functional groups, which contribute to its acidity and reactivity.
L-(+)-Tartaric acid has a melting point of approximately 171-174°C.
L-(+)-Tartaric acid is commonly found in nature as the potassium salt, potassium bitartrate, known as cream of tartar.

L-(+)-Tartaric acid plays a crucial role in winemaking, where it helps regulate acidity and stabilize wines.
L-(+)-Tartaric acid is also used in the baking industry as a leavening agent in conjunction with baking soda.

L-(+)-Tartaric acid contributes to the rise and texture of baked goods such as cakes, cookies, and bread.
L-(+)-Tartaric acid is utilized in the pharmaceutical industry as an ingredient in medications and dietary supplements.

L-(+)-Tartaric acid is added to effervescent tablets to produce carbon dioxide gas when dissolved in water.
L-(+)-Tartaric acid is utilized in cosmetic products such as skincare masks and exfoliating scrubs for its skin-renewing properties.

L-(+)-Tartaric acid is used in metal cleaning solutions and rust removers for its chelating abilities.
L-(+)-Tartaric acid helps remove mineral deposits and stains from metal surfaces.

L-(+)-Tartaric acid is employed in the textile industry for dyeing and finishing processes.
L-(+)-Tartaric acid acts as a mordant, helping to fix dyes to fibers and improve colorfastness.

L-(+)-Tartaric acid is utilized in cleaning agents and detergents as a pH buffer and water softener.
L-(+)-Tartaric acid is added to adhesives and sealants to improve their adhesion and durability.

The compound is used in photography chemicals as a developing agent, aiding in the production of photographic prints.
L-(+)-Tartaric acid is employed in the ceramic and glass industry as a fluxing agent, facilitating the melting and shaping of raw materials.
L-(+)-Tartaric acid is utilized in agricultural applications as a soil conditioner and plant nutrient.

L-(+)-Tartaric acid helps improve soil structure and fertility, leading to better plant growth and crop yield.
Overall, L-(+)-Tartaric acid is a versatile compound with diverse applications across various industries, contributing to its importance and widespread use.



PROPERTIES


Chemical Formula: C4H6O6
Molecular Weight: Approximately 150.09 grams per mole
Physical State: Solid at room temperature (crystalline)
Color: White
Odor: Odorless
Taste: Tart or sour
Solubility in Water: Soluble
Solubility in Organic Solvents: Soluble in alcohol, slightly soluble in ether
Melting Point: Approximately 171-174°C
Boiling Point: Decomposes before boiling
Density: Approximately 1.79 g/cm³
pH: Acidic (approximately 2.2 at 1% solution)
Optical Activity: Optically active (D-tartaric acid rotates polarized light to the right, L-tartaric acid rotates it to the left)
Hygroscopicity: Low
Stability: Stable under normal conditions
Flammability: Non-flammable
Refractive Index: Approximately 1.63
Dielectric Constant: Approximately 10.5
Heat of Combustion: Approximately -1575 kJ/mol
Heat of Fusion: Approximately 53 kJ/mol
Heat of Vaporization: Approximately 106 kJ/mol
Specific Heat Capacity: Approximately 0.868 J/g°C
Flash Point: Not applicable (solid)
Surface Tension: Approximately 105 mN/m
Viscosity: Varies with concentration and temperature



FIRST AID


Inhalation:

If inhaled, immediately remove the affected person to fresh air.
Allow the person to rest in a well-ventilated area.
If breathing difficulties persist, seek medical attention promptly.
Provide oxygen if the person has difficulty breathing.


Skin Contact:

Remove contaminated clothing and shoes immediately.
Wash the affected area with plenty of soap and water for at least 15 minutes.
Rinse skin thoroughly to remove any traces of the substance.
If irritation, redness, or rash develops, seek medical advice.
Apply a soothing moisturizer or barrier cream to the affected area to help alleviate discomfort.


Eye Contact:

Flush eyes with lukewarm water, keeping eyelids open, for at least 15 minutes.
Remove contact lenses if present and easily removable.
Seek immediate medical attention if irritation, pain, or redness persists.
Protect the unaffected eye to prevent contamination.


Ingestion:

Rinse mouth with water and drink plenty of water to dilute the substance.
Do not induce vomiting unless instructed to do so by medical personnel.
Seek medical attention immediately and provide information on the ingested substance.
Do not give anything by mouth to an unconscious person.


General Advice:

Keep affected person calm and reassure them.
If seeking medical attention, provide the Safety Data Sheet (SDS) or product label information to healthcare providers.
If the substance has entered the respiratory tract, monitor for signs of respiratory distress and administer CPR if necessary.
Do not administer any medications unless directed by medical personnel.
If exposed to large quantities or experiencing severe symptoms, seek emergency medical assistance immediately.
Be prepared to provide information on the specific product, concentration, and duration of exposure when seeking medical advice.
If transporting an affected individual to a medical facility, ensure proper ventilation and monitor their condition closely.



HANDLING AND STORAGE


Handling:

Personal Protective Equipment (PPE):
Wear suitable protective clothing, including gloves, safety glasses, and a lab coat, when handling L-(+)-Tartaric acid to prevent skin contact and eye irritation.
Use respiratory protection, such as a dust mask or respirator, if handling in powdered form or in poorly ventilated areas to prevent inhalation of dust particles.

Ventilation:
Handle L-(+)-Tartaric acid in a well-ventilated area or under a fume hood to minimize exposure to airborne particles and vapors.
Ensure adequate ventilation in storage areas to prevent the accumulation of vapors and maintain air quality.

Avoidance of Contamination:
Prevent contamination of L-(+)-Tartaric acid by keeping containers tightly closed when not in use.
Do not allow the substance to come into contact with incompatible materials, such as strong oxidizing agents or bases, to avoid hazardous reactions.

Safe Handling Practices:
Avoid generating dust or aerosols when handling L-(+)-Tartaric acid.
Use appropriate handling tools, such as scoops or spatulas, to minimize skin contact and prevent spills.
Do not eat, drink, or smoke while handling L-(+)-Tartaric acid to prevent accidental ingestion.

Emergency Procedures:
Familiarize yourself and other personnel with emergency procedures in case of spills, leaks, or exposure incidents.
Have appropriate spill control measures, absorbent materials, and personal protective equipment readily available.


Storage:

Storage Conditions:
Store L-(+)-Tartaric acid in a cool, dry, well-ventilated area away from sources of heat, moisture, and direct sunlight.
Keep containers tightly closed when not in use to prevent contamination and moisture absorption.

Temperature and Humidity:
Maintain storage temperature within the recommended range (typically room temperature) to ensure stability and minimize degradation.
Avoid exposure to extreme temperatures or fluctuations, as this may affect the quality and shelf life of the product.

Compatibility:
Store L-(+)-Tartaric acid away from incompatible materials, such as strong oxidizing agents, alkalis, and reducing agents, to prevent hazardous reactions.
Segregate L-(+)-Tartaric acid from other chemicals to avoid cross-contamination and potential hazards.

Labeling and Identification:
Clearly label storage containers with the product name, hazard warnings, handling instructions, and date of receipt.
Ensure proper identification and labeling of L-(+)-Tartaric acid to prevent confusion and facilitate safe handling and storage.

Security Measures:
Restrict access to storage areas containing L-(+)-Tartaric acid to authorized personnel only.
Implement appropriate security measures, such as locked cabinets or storage rooms, to prevent unauthorized access or tampering.

Spill Containment and Cleanup:
Have spill containment kits, absorbent materials, and personal protective equipment readily available for spill cleanup.
Follow established spill cleanup procedures and disposal guidelines to minimize environmental impact and ensure safety.

Regulatory Compliance:
Store and handle L-(+)-Tartaric acid in compliance with local regulations, codes, and guidelines governing the storage and handling of hazardous substances.
Maintain accurate records of storage conditions, inventory levels, and handling procedures for regulatory compliance and safety auditing purposes.
LABSA
LABSA; Dodecylbenzene Sulfonic Acid (Strait Chain); LAS; Laurylbenzenesulfonic Acid; Laurylbenzenesulfonate; n-Dodecylbenzene Sulfonic Acid; Alkylbenzene sulphonate, sodium salt; Linear Alkylbenzene Sulphonic Acid; Dodecylbenzolsulfonsäure (German); ácido dodecilbenceno sulfónico (Spanish); Acide dodécylbenzènesulfonique; cas no: 27176-87-0
LABSA LIQUID
LABSA LIQUID Linear Alkyl Benzene Sulphonic Acid Chemical Name: Linear Alkyl Benzene Sulphonic Acid; Linear Alkyl Benzene Sulphonic Acid Description and Uses: Linear Alkyl Benzene Sulphonic Acid; is an anionic surfactant commonly used in the manufacture of detergents and emulsifiers. It is environmentally friendly as it can be dried as powder. Usage areas LABSA Liquid is formed by the reaction of Linear Alkyl Benzene Sulphonic Acid (LAB) with SO3 (sulfonation). Today, LABSA Liquid is used as the main surfactant in liquid, gel or powder detergent production processes. It is one of the main raw materials of synthetic detergent industry. Laundry, dishwasher powder detergents, detergent gels, liquid soaps, cleaning powders, oily soaps and so on. as. It is used as mercerizing and washing agent in textile sector. As the raw material of detergent, it is used in the production of alkynbenzene solphonic acid sodium in decontamination, emulsion, dispersion performance, wetting and foam properties. It is widely used in various detergent and emulsion production such as washing powder, dishwashing detergent, light or hard dirt detergent, textile industry cleaner, paint assistant, coating and leather making industry and paper making industry. PRODUCT IDENTIFICATION CAS NO. 27176-87-0 LINEAR ALKYL BENZENE SULPHONIC ACID EINECS NO. 248-289-4 FORMULA CH3(CH2)11C6H4SO3H SYNONYMS Dodecylbenzene Sulfonic Acid (Strait Chain); LAS; LABSA Liquid; Laurylbenzenesulfonic Acid; Laurylbenzenesulfonate; n-Dodecylbenzene Sulfonic Acid; Alkylbenzene sulphonate, sodium salt; Linear Alkyl benzene Sulphonic Acid; Dodecylbenzolsulfonsäure (German); ácido dodecilbenceno sulfónico (Spanish); Acide dodécylbenzènesulfonique (French); CLASSIFICATION Anionic Surfactant DESCRIPTION OF LABSA Liquid Linear alkyl benzene sulphonic acid is the largest-volume synthetic surfactant because of its relatively low cost, good performance, the fact that it can be dried to a stable powder and the biodegradable environmental friendliness as it has straight chain. LABSA Liquid is an anionic surfactants with molecules characterized by a hydrophobic and a hydrophilic group. Alpha-olefin sulfonates (AOS) alkyl sulfates (AS) are also examples of commercial anionic surfactants. They are nonvolatile compounds produced by sulfonation. LABSA Liquid are complex mixtures of homologues of different alkyl chain lengths (C10 to C13 or C14) and phenyl positional isomers of 2 to 5-phenyl in proportions dictated by the starting materials and reaction conditions, each containing an aromatic ring sulfonated at the para position and attached to a linear alkyl chain at any position with the exception of terminal one (1-phenyl). The properties of LABSA Liquid differ in physical and chemical properties according to the alkyl chain length, resulting in formulations for various applications. The starting material LABSA Liquid (linear alkylbenzene) is produced by the alkylation of benzene with n-paraffins in the presence of hydrogen fluoride (HF) or aluminium chloride (AlCl3) as a catalyst. LABSA Liquid is produced by the sulfonation of LAB with oleum in batch reactors. Other sulfonation alternative reagents are sulfuric acid, diluted sulfur trioxide, chlorosulfonic acid and sulfamic acid on falling film reactors. LABSA Liquid are then neutralized to the desired salt (sodium, ammonium, calcium, potassium, and triethanolamine salts). Surfactants are widely used in the industry needed to improve contact between polar and non-polar media such as between oil and water or between water and minerals. Linear alkyl benzene sulphonic acid is mainly used to produce household detergents including laundry powders, laundry liquids, dishwashing liquids and other household cleaners as well as in numerous industrial applications like as a coupling agent and as an emulsifier for agricultural herbicides and in emulsion polymerization. PHYSICAL AND CHEMICAL PROPERTIES Household detergents including laundry powders, laundry liquids, dishwashing liquids and other household cleaners. Industrial applications of wetting agent, emulsifier for agricultural herbicides and in polymerization. LABSA Liquid HOMOLOGUES AND SALTS Linear Alkyl benzene Sulphonic Acid (LABSA Liquid)/Linear Alkylate Sulfonate (LAS) Linear alkyl benzene sulphonic acid (LABSA Liquid) is prepared commercially by sulfonating linear alkylbenzene (LAB). Linear alkylbenzene sulfonate (LABSA Liquid), the world’s largest-volume synthetic surfactant, which includes the various salts of sulfonated alkylbenzenes, is widely used in household detergents as well as in numerous industrial applications. The LABSA Liquid market is driven by the markets for LABSA Liquid, primarily household detergents. Linear alkylbenzene sulfonate was developed as a biodegradable replacement for nonlinear (branched) alkylbenzene sulfonate (BAS) and has largely replaced BAS in household detergents throughout the world. The pattern of LABSA Liquid consumption demonstrates the overwhelming preference by consumers for liquid laundry detergents in North America, whereas powders continue to be the dominant products in Western Europe, Japan, and China. Comparable and reliable data in other world regions are generally unavailable. In these less-developed world areas, LABSA Liquid is essentially used only in laundry powders (particularly in India and Indonesia) and hand dishwashing liquids. The latter are often used as general-purpose cleaners. The following pie chart shows world consumption of LABSA Liquid: About 82–87% of LABSA Liquid is used in household detergents, including laundry powders, laundry liquids, dishwashing liquids, and other household cleaners. Industrial, institutional, and commercial cleaners account for most of the other applications, but LABSA Liquid is also used as an emulsifier (e.g., for agricultural herbicides and in emulsion polymerization) and as a wetting agent. Very small volumes are also used in personal care applications. Demand in the North American household segment fell sharply in 2000–11, as a result of several developments, including reformulations away from LABSA Liquid to alternative surfactants because of cost considerations, the greater use of enzymes, and adverse economic conditions that resulted in lower overall surfactant levels in detergents. However, consumption stabilized during 2011–17. Although consumption of LABSA Liquid will likely stabilize or decline slightly in the highly developed regions, it will increase by 3.0–5.0% in some less-developed regions or countries, such as the Middle East, Africa, India, and China, as well as Southeast Asia. As a result of the rapid growth of LABSA Liquid demand in the Asia Pacific region, demand in the region accounted for over half of global demand in 2017. The worldwide growth of LABSA Liquid will be negatively impacted by the efforts of detergent manufacturers to reduce the active content in their surfactant formulations, by the shift to liquid detergents in some countries (which benefits competing surfactants), and by less consumer overdosing (particularly in North America with unit dose laundry products, assuming they continue to take some market share from traditional liquid detergents). However, consumption of LABSA Liquid will be positively affected in countries/regions such as India, China, Africa, and the Middle East, where powder detergents are still a very large part of the laundry detergent market. Linear alkylbenzene sulfonate competes with several other major surfactants for use in household detergents. Some of the competitive surfactants have greater hard-water tolerance and better compatibility with enzymes and are milder than LABSA Liquid. Historically, however, LABSA Liquid has most often been lower in cost and has had other more favorable properties compared with competing surfactants. During 2002–06, very high crude oil prices made LABSA Liquid far less competitive than had been true in most years since its introduction. During 2007–11, LABSA Liquid prices tracked more closely those of the competitive surfactants. This led to a more stable pattern of consumption, even as prices for all surfactants continued to be very volatile. From late 2014 through 2017, low crude oil prices helped LABSA Liquid become more competitive. LABSA Liquid/LAS production is impacted by the supply situation for competing products—mainly alcohol ether sulfates (AES). Shortages in AES supply or its high price has usually favored the use of LABSA Liquid/LAS. In the developing world, LABSA Liquid competes with soaps. Alkylbenzene sulfonates are a class of anionic surfactants, consisting of a hydrophilic sulfonate head-group and a hydrophobic alkylbenzene tail-group. Along with sodium laureth sulfate they are one of the oldest and most widely used synthetic detergents and may be found in numerous personal-care products (soaps, shampoos, toothpaste etc.) and household-care products (laundry detergent, dishwashing liquid, spray cleaner etc.).[1] They were first introduced in the 1930s in the form of branched alkylbenzene sulfonates (BAS) however following environmental concerns these were replaced with linear alkylbenzene sulfonates (LABSA Liquid) during the 1960s.[2] Since then production has increased significantly from about 1 million tons in 1980, to around 3.5 million tons in 2016, making them most produced anionic surfactant after soaps. Linear alkylbenzene sulfonates (LAS) are prepared industrially by the sulfonation of linear alkylbenzenes (LABSA Liquid), which can themselves be prepared in several ways.[2] In the most common route benzene is alkylated by long chain monoalkenes (e.g. dodecene) using hydrogen fluoride as a catalyst.[9] The purified dodecylbenzenes (and related derivatives) are then sulfonated with sulfur trioxide to give the sulfonic acid.[10] The sulfonic acid is subsequently neutralized with sodium hydroxide.[1] The term "linear" refers to the starting alkenes rather than the final product, perfectly linear addition products are not seen, in-line with Markovnikov's rule. Thus, the alkylation of linear alkenes, even 1-alkenes such as 1-dodecene, gives several isomers of phenyldodecane.[11] Structure property relationships Under ideal conditions the cleaning power of BAS and LABSA Liquid is very similar, however LABSA Liquid performs slightly better in normal use conditions, due to it being less affected by hard water.[12] Within LABSA Liquid itself the detergency of the various isomers are fairly similar,[13][14] however their physical properties (Krafft point, foaming etc.) are noticeably different.[15][16] In particular the Krafft point of the high 2-phenyl product (i.e. the least branched isomer) remains below 0 °C up to 25% LABSA Liquid whereas the low 2-phenyl cloud point is ∼15 °C.[17] This behavior is often exploited by producers to create either clear or cloudy products.. LABSA Liquid Linear Alkyl Benzene Sulphonic Acid Product Information LABSA Liquid Linear alkyl benzene Sulphonic Acid is a chemical which is colorless and have viscous properties. LABSA Liquid Linear alkyl benzene sulphonic acid mainly using in detergent formulations. It is one of the most important and cheapest surfactants in powder formulation and detergent fluids. It has excellent cleansing properties. Usages of Linear Alkyl Benzene Sulphonic Acid LABSA Liquid Linear Alkyl Benzene sulphonic acid is a batch of organic sulfur compounds that are used in most home detergents, dishwashing detergents, detergent powder, cleaning powder, washing powders, detergent cake, liquid soap, soaps etc. LABSA Liquid, sulfonic acid compound is used as a foaming agent, cleaning agent in more formulations and toilet soaps for foaming. Sulfonic acid, LABSA Liquid is using in detergent industries, in textile industry as a washing agent, pesticides industries to improve the quality of spray. Sulfonic acid, LABSA Liquid is not inflammable substance and can dissolve in water, but not in organic solvent. industrial uses. LABSA Liquid Linear alkyl benzene Sulphonic Acid uses in produce sulfonic acid. LABSA Liquid is an additive as a LABSA Liquid Linear alkyl benzene Sulphonic Acid packing Basekim Chemical Production can supply LABSA Liquid Linear alkyl benzene Sulphonic Acid with drum. Each drum can take 220 kg and 80 drum can easily load in a container. It also depends on customer demands as well. LABSA Liquid Linear alkyl benzene Sulphonic Acid LABSA Liquid Linear alkyl benzene Sulphonic Acid is a chemical which is colorless and have viscous properties. LABSA Liquid Linear alkyl benzene Sulphonic Acid mainly using in detergent formulations. It is one of the most important and cheapest surfactants in powder formulation and detergent fluids. It has excellent cleansing properties. LABSA Liquid Linear alkyl benzene Sulphonic Acid in the formulation of anionic, non-anionic, and amphoteric surfactants, and it is extremely important for its degradability in nature. It is soluble in water and emulsifying agent. Linear Alkyl benzene sulphonic acid is one of the most widely used anionic surfactants due to its low cost, high efficiency and biocompatibility due to its linear chain. This anionic surfactant has hydrophilic and hydrophobic groups. These are non-volatile compounds produced by the sulfonation process. These compounds consist of mixtures of carbon chains of 10 to 14 carbon lengths that are a phenyl group with a sulfonate group LABSA Liquid Linear alkyl benzene Sulphonic Acid LABSA Liquid Linear alkyl benzene Sulphonic Acid application The properties of LABSA Liquid Linear alkyl benzene Sulphonic Acid depend on the length of the alkane chains that give them different functionality. Surfactants are used in the industry to increase the contact of polar and non-polar phases, such as oil, water, or water and minerals. Linear alkyl benzene Sulphonic Acid sulfonate is mainly used for the manufacture of household detergents such as laundry powder, washing liquid, dishwashing liquid and other household cleaners and other industrial uses. LABSA Liquid Linear alkyl benzene Sulphonic Acid uses in produce sulfonic acid. LABSA Liquid is an additive as an lubricating agent oils and have as corrosion and rust prevention. his product is a very effective intermediate surfactant. It is usually neutralized with alkali types and forms sulphonates used in different fields. This product can be used in acidic environments. LABSA Liquid Linear alkyl benzene Sulphonic Acid packing can supply LABSA Liquid Linear alkyl benzene Sulphonic Acid with drum . Each drum can take 220 kg and 80 drum can easily load in a container LABSA Liquid Linear alkyl benzene Sulphonic Acid PACKING Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) Specification LABSA Liquid properties: 1. Linear alkyl benzene sulphonic acids (LABSA Liquid) are anionic surfactants. Linear alkyl benzene Synonyms LAS;LABSA Liquid;LABS;Laurylbenzenesulfonic Acid;Laurylbenzenesulfonate;Linear Alkyl benzene Sulphonic Acid;DDBSA;Dodecyl Benzene Sulphonic Acid;Dodecyl Benzene Sulfonic Acid Linear alkyl benzene sulphonic acid, also known as LABSA Liquid is a synthetic chemical surfactant, which is a widely used industrial detergent. It is used in washing powder, detergent powder, oil soap, cleaning powder and detergent cake. DESCRIPTION LABSA Liquid is an anionic surfactant, whose molecules are characterized by a hydrophilic and a hydrophobic group. This nonvolatile chemical compound is synthesized through the process of sulfonation. The sulfonation reagents include sulfuric acid, chlorosulfonic acid, sulfamic acid and diluted sulfur trioxide. The properties of LABSA Liquid, differs in chemical and physical properties based on the length of the alkyl chain. This results in formulations, which finds many applications. The resulting surfactants are used in the chemical industry to improve contact between water and minerals. USES LABSA Liquid is chiefly used in the detergent industry for the manufacture of washing powder, detergent powder, detergent cake, liquid soap, oil soap, scouring bar and cleaning powder. This chemical finds applications in anionic specialty formulations. The quality of pesticide sprays can be improved from it. Linear alkyl benzene sulphonic acid is used as a washing and mercerizing agent in the textile industry. The surface area of distempers is increased using LABSA Liquid. It is used as a wetting agent as well as an emulsifier in small quantities along with other surfactants, for foaming of toilet soaps. Owing to its high active matter content and miscibility with low salt content and water, LABSA Liquid is used in the polymerization of emulsions and in production of coupling agents, emulsifiers, agricultural herbicides, household and industrial cleaners. ENVIRONMENTAL AND SAFETY CONSIDERATIONS Most anionic surfactants including LABSA Liquid are nontoxic in nature. However, prolonged exposure to these surfactants, could irritate and damage the skin through the disruption of the lipid membrane, which protects the skin and other cells. On the other hand, the biodegradability is determined by surfactant's hydrophobic hydrocarbon group. ADVANTAGES Linear Alkyl Benzene Sulphonic Acid is one of the largest synthetic surfactants by volume due to its low cost and high performance. Apart from this, LABSA Liquid can be dried to a stable powder form. This chemical is biodegradable and environmentally friendly. Buy excess stock of LABSA Liquid for a discounted price. Product Description Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 90% is the largest-volume synthetic surfactant because of its relatively low cost, good performance, the fact that it can be dried to a stable powder and the biodegradable environmental friendliness. LAB Sulphonic Acid is an anionic surfactant widely used in formulation of all ranges of Domestic Detergents Powder ,Cake & Dish wash cleaners. Linear Alkyl Benzene Sulphonic Acid Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 90% is the largest-volume synthetic surfactant because of its relatively low cost, good performance, the fact that it can be dried to a stable powder and the biodegradable environmental friendliness. LAB Sulphonic Acid is an anionic surfactant widely used in formulation of all ranges of Domestic Detergents Powder ,Cake & Dish wash cleaners. Due to its high active matter , miscibility with water and low salt content , it is also used in formulation of Industrial & Household liquid cleaners as well as in numerous industrial applications like as a coupling agent and as an emulsifier for agricultural herbicides and in emulsion polymerization. Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 90% - Soft Acid Slurry is main raw material for: Properties of LABSA Liquid Nature Anionic Constitution Sulphonated Linear Alkyl Benzene Sulphonic Acid Appearance Light Yellow-Brown viscous liquid Solubility Readily soluble in water Specifications of LABSA Liquid Active matter ( % by weight) 90 ± 1% Non-Digestive oil matter( % by weight) 1% Max Free Sulphuric acid % by weight) 7 Max Color [KLETT] (When dispatched) 30 Avg Advantages of LABSA Liquid 90 % over LABSA Liquid 96 % Cost Factor Cost of LABSA Liquid 90% Sulphonation Plant is 1/10th as compared to LABSA Liquid 96 % Sulphonation plant thereby giving huge cost advantage as a result of which LABSA Liquid 90% can be offered to consumers at competitive prices vis-a-vis LABSA Liquid 96% LABSA Liquid 90 % has 5-6 % Free Acid which is converted to Glauber Salt (Sodium Sulphate) on reaction with Soda Ash which is the common ingredient for all Detergent Powders. This Glauber Salt helps in keeping End Product i.e Detergent Powder free flowing and imparts anti-caking properties which is absent in Detergents formulated with LABSA Liquid 96 % LINEAR ALKYL BENZENE SULPHONIC ACID/ SODIUM ALKYL BENZENE SULFONATE / LABSA Liquid/ SODIUM DODYL BENZENE SULFONATE Anionic surfactant used in all cleaning & detergent products like dishwashing liquid, all purpose cleaner, laundry liquid , car shampoo, degreasers and in so many industrial cleaners. LABSA Liquid is acidic & has to be neutralized with any of caustic soda, potassium hydroxide or TEA ( you can also order them from us). We are providing LABSA Liquid as below 1. pure acid LABSA Liquid/ linear alkyl benzene sulphonic acid/ dodyl benzene 2. ready neutralized LABSA Liquid..LABSA Liquid sodium salt/ sodium dodyl benzene sulfonate 40%. ..................................Uniclean america......................... sizes are :- plastic HDPE : 16 oz, 32 oz, 64 oz, 128 oz, 5 gallon & 20 liter . Linear Alkyl Benzene Sulphonic Acid| LABSA Liquid Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is a largest volume surfactant because of its low cost, good performance; environmental friendliness .For the production of Linear Alkyl Benzene sulphonic acid, LABSA Liquid, alkaline benzene linear sulfation is usually used. Its components: linear alkyl benzene Sulphonic Acid, oxygen, sulfur and citric acid. (LABSA Liquid) Linear Alkyl Benzene Sulphonic Acid| LABSA Liquid used in: Linear Alkyl Benzene Sulphonic acid, LABSA Liquid is a batch of organic sulfur compounds that are used in most home detergents, dishwashing detergents, detergent powder, cleaning powder, washing powders, detergent cake, liquid soap, soaps etc. LABSA Liquid, sulfonic acid compound is used as a foaming agent , cleaning agent in more formulations and toilet soaps for foaming. Linear Alkyl Benzene Sulphonic acid, LABSA Liquid is using in detergent industries, in textile industry as a washing agent, pesticides industries to improve the quality of spray. Sulfonic acid, LABSA Liquid is not inflammable substance and can dissolve in water, but not in organic solvent. Definition Linear Alkyl Benzene Sulphonic Acid Definition Linear Alkyl Benzene Sulphonic Acid, Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) LABSA Liquid properties: Chemical Name: Linear Alkyl Benzene Sulphonic Acid Synonyms: LABSA Liquid;LABS;Laurylbenzenesulfonic Acid;Laurylbenzenesulfonate;Linear Alkyl benzene Sulphonic Acid;DDBSA;Dodecyl Benzene Sulphonic Acid; Dodecyl Benzene Sulfonic Acid Formula Linear Alkyl Benzene Sulphonic Acid Storage Linear Alkyl Benzene Sulphonic Acid | LABSA Liquid Linear Alkyl Benzene Sulphonic Acid Stored in cool, ventilated and dry place, kept away from sunshine and rain Packing Linear Alkyl Sulphonic Acid | LABSA Liquid Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) package by 200 kg Linear Alkyl Benzene Sulphonic Acid package by 210 kg Linear Alkyl Benzene Sulphonic Acid package by 220 kg net plastic drum. It’s possible packing in pelleting for each 4 LABSA Liquid drums. However according to customer inquiries it is able to offer in Bulk. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid Exporting Destinations: ATDM are exporting Sulphonic Acid to African, European, South American, East Asian countries.ATDM lead to packing and exporting to mention above destinations, under Iran authorization by the best Iranian LABSA Liquid raw materials in accordance with standard. If you want the updated price for LABSA Liquid or Linear Alkyl Benzene Sulphonic acid and knowing more about further details, please contact us. Advantage of Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid: LABSA Liquid Excellent solubility even at low temperatures LABSA Liquid has high power of foam LABSA Liquid is a biodegradable. Linear Alkyl Benzene Sulphonic Acid application Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is used in produce cleansers, light detergent, hard detergent, Liquid Soap, Cleaning powder, Scouring Bar, Oil soaps etc. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is used in produce various detergents and emulsifiers. It is used to increase the surface area of distempers Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is used in produce cleaner of textile industry such as washing powder. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is used in produce industrial electronic, leather industry. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is used in produce paper-making industry. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid can be used in produce detergent of dishware. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is used to produce Linear Alkyl Benzene Sulphonic Acid sodium. Warning LABSA Liquid, Linear Alkyl Benzene Sulphonic Acid LABSA Liquid, Linear Alkyl Benzene Sulphonic acid is capable of causing eye, skin and lung irritation as well as burns in extreme cases. Thus, occupational exposure limits should be implemented for safe industrial practices. When you work with sulfonic acid, LABSA Liquid, you must be caring you. Same as workplace that make use of Linear Alkyl Benzene sulphonic acid, LABSA Liquid should have enclosed operations with the use of local ventilation or exhaust to release the chemicals. You should be attention to warning information at the work area to communicate all the safety about this corrosive element. Linear Alkyl Benzene Sulphonic Acid Product description CAS No.: 27176-87-0 Synonyms: Dodecylbenzene Sulfonic Acid (Strait Chain); LAS; LABSA Liquid; Laurylbenzenesulfonic Acid; Laurylbenzenesulfonate; n-Dodecylbenzene Sulfonic Acid Linear Alkyl Benzene Sulphonic Acid is a synthetic surfactant with a wide range of applications like as a coupling agent, as an emulsifier and in the production of household detergents. LABSA Liquid 96% Linear Alkyl Benzene Sulphonic Acid DBSA For Laundry soap detergent Description: it is a kind of weak organic acid and easy to dissolve in water. Widely used in washing powder, civil detergent cleanser and industrial detergents 96% active content,brown liquid ,must be neutralized by hydroxyl sodium when use it . Feature: Product name: Linear Alkyl Benzene Sulphonic Acid Other name: LAS,LABSA Liquid,Dodecyl Benzenesulfonic Acid Molecular Formula:C18H30O3S CAS No.: 85536-14-7 HS Code: 34021100 Molecular weight: 326.49 Apparence:brown liquid Synonyms: Linear alkyl benzene Sulphonic Acid (LABSA Liquid) SYNONYMS: Dodecylbenzene Sulfonic Acid (Strait Chain); LAS; LABSA Liquid; Laurylbenzenesulfonic Acid; Laurylbenzenesulfonate; N-Dodecylbenzene Sulfonic Acid; Alkylbenzene sulphonate, sodium salt; Linear Alkyl benzene Sulphonic Acid; Linear alkyl benzene Sulphonic Acid is household detergents including laundry powders, laundry liquids, dishwashing liquids and other household cleaners. Industrial applications of wetting agent, emulsifier for agricultural herbicides and in polymerization Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 Detergent Chemical: Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 / Application [1] Used as raw material for washing powder, laundry detergent and industrial detergent. [2] can be used as a curing catalyst for amino baking varnish, used to prepare various liquid and solid detergents. [3] It is used for the production of linear alkylbenzene sulfonate sodium salt, ammonium salt and ethanolamine salt. It is the main raw material for the production of detergents, household liquid detergents, industrial detergents and other common detergents. Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 Synonyms: Linear Alkyl benzene Sulphonic Acid; LABSA Liquid;DBSA; Molecular Formula: C18H30O3S Type: Detergent chemical material Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 / Properties LABSA Liquid has the action of detergency, moistening, foaming, emulsion. dispersionand brown viscous fluid in appearance with acidity. it is nonflammable. quickly ,the product has strong absorbency. it would be unclear viscous liquid after absorbed water. Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 / Specification Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 / Application [1] Used as raw material for washing powder, laundry detergent and industrial detergent. [2] can be used as a curing catalyst for amino baking varnish, used to prepare various liquid and solid detergents. [3] It is used for the production of linear alkylbenzene sulfonate sodium salt, ammonium salt and ethanolamine salt. It is the main raw material for the production of detergents, household liquid detergents, industrial detergents and other common detergents. Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 / Packing Packed in plastic drums netted 200 kgs,16 mt / 20 fcl Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid) 96% CAS No. 27176-87-0 Hot Tags: linear alkyl benzene sulphonic acid (LABSA Liquid) 96% CAS No. 27176-87-0, China, suppliers, manufacturers, factory, price, for sale, free sample ARTICLES / LINEAR ALKYL BENZENE SULPHONIC ACID LABSA Liquid | MSDS | APPLICATIONS. Uses advised against Food, drug, pesticide or biocidal product use. 69669-44-9 C10-14 Alkyl deriv benzene sulfonic acid, sodium salt 85117-50-6 C10-14 Monoalkylbenzene sulfonic acid, sodium salt 90194-45-9 C10-13 Alkyl deriv benzene sulfonic acid, sodium salt 127184-52-5 4-C10-13-sec Alkyl deriv. Details of the supplier of the safety data sheet Emergency Telephone Number For information … III. The LABSA Liquid market is driven by the markets … : AC325900000; AC325900010; AC325905000 CAS-No 85536-14-7 Synonyms Mostly dodecylbenzene sulfonic acid. First Aid Measures Inhalation: Move to fresh air. Linear Alkyl Benzene Sulphonic Acid, LABSA Liquid is a largest volume surfactant because of its low cost, good performance; environmental friendliness .For the production of Linear Alkyl Benzene sulphonic acid, LABSA Liquid, alkaline benzene linear sulfation is usually used. CAS N. EC N. SYMBOL Common Name Linear Alkyl Benzene Sulphonic Acid CAS Number Mixture COMPONENT CAS NUMBER CONCENTRATION Benzenesulfonic Acid, C10-16 alkyl Derivatives 68584-22-5 90 – 100% Sulfuric Acid (Byproduct) 7664-93-9 < 1.5% Benzene, C10-16 alkyl Derivatives 68648-87-3 < 1.5% Sulfur Dioxide 7446-09-5 < 0.1% Section 4. We have a combined production capacity of 80000 MT LABSA Liquid per Annum. CHEMICAL NAME : Linear Alkyl Benzene Sulphonic Acid CHEMICAL FORMULA : C6H4 (SO3H) (CS2)10CS3 CAS NUMBER : 27176-87-0 EINECS NUMBER : 248-289-4 EC NUMBER : Not Classified. LINEAR ALKYL BENZENE SULPHONIC ACID. Recommended Use Laboratory chemicals. Linear alkylbenzene sulfonate (LABSA Liquid), the world’s largest-volume synthetic surfactant, which includes the various salts of sulfonated alkylbenzenes, is widely used in household detergents as well as in numerous industrial applications. HAZARDOUS IMPURITIES NAME CONCENTR. Major portion of our production … Linear alkyl benzene sulphonic acid (LABSA Liquid) is prepared commercially by sulfonating linear alkylbenzene (LAB). Its components: linear alkyl benzene Sulphonic Acid, oxygen, sulfur and citric acid. Linear alkyl benzene sulphonic acid is prepared commercially by just sulfonating linear alkylbenzene (LABSA Liquid).Linear alkyl benzene sulphonic acid which is mainly called (LABSA Liquid), the worlds largest volume synthetic surfactant, which includes the various salts of sulfonated alkylbenzenes, which is widely used in household detergents as well as in numerous industrial application. We, New India Detergents Ltd. Group of Companies are engaged in manufacturing of Linear Alkyl Benzene Sulphonic Acid (LABSA Liquid 90% ) since 20 years and have grown to be a leader in its area of operations, adhering to the quality standards and catering to the domestic & global markets. LABSA Liquid . Product Name Dodecylbenzene sulfonic acid, mixture of C10-C13 isomers Cat No. benzene sulfonic acid, sodium salt Category Name Linear Alkylbenzene Sulfonate (LABSA Liquid) Structural Formula Call a … INTRODUCTION: This project profile in detail foresees setting up of unit to produce ACID SLURRY LABSA Liquid have been the major surfactant used in detergents for more than thirty years and continues to represent a substantial portion of the surfactants market today. Supporting this history of safe usage is a large archive of environmental research that has been conducted on LABSA Liquid. This environmental research, performed by top environmental scientists and research agencies, has investigated virtually every part of the environment that could have been exposed to LABSA Liquid. The studies have repeatedly proven LABSA
LACTAMIDE
LACTAMIDE MEA, N° CAS : 5422-34-4, Nom INCI : LACTAMIDE MEA. Nom chimique : N-2-hydroxyethyllactamide. N° EINECS/ELINCS : 226-546-1. Classification : MEA Ses fonctions (INCI) : Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance Humectant : Maintient la teneur en eau d'un cosmétique dans son emballage et sur la peau Agent d'entretien de la peau : Maintient la peau en bon état
LACTAMIDE MEA
BUTYL LACTATE, N° CAS : 138-22-7, Nom INCI : BUTYL LACTATE, Nom chimique : Propanoic acid, 2-hydroxy-, butyl ester, N° EINECS/ELINCS : 205-316-4; Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Solvant : Dissout d'autres substances. Noms français :HYDROXY-2 PROPANOATE DE BUTYLE NORMAL; Lactate de butyle normal; N-BUTYL 2-HYDROXYPROPANOATE; PROPANOIC ACID, 2-HYDROXY, BUTYL ESTER. Noms anglais : BUTYL LACTATE; BUTYL LACTATE (NORMAL-); n-Butyl lactate; Utilisation: Solvant de laques, solvant d'encres d'imprimerie. 2-Hydroxypropanoic acid butyl ester; Butyl alpha-hydroxypropionate; Butyl lactate; Butyl lactate (natural); Butylester kyseliny mlecne; Lactic acid, butyl ester ; n-Butyl lactate; Propanoic acid, 2-hydroxy-, butyl ester. : butyl 2-hydroxypropanoate. Hydroxypropanoic acid, butylester
Lactate de butyle normal ( BUTYL LACTATE)
CALCIUM LACTATE, N° CAS : 814-80-2 - Lactate de calcium, Nom INCI : CALCIUM LACTATE, Nom chimique : Calcium dilactate, N° EINECS/ELINCS : 212-406-7, Additif alimentaire : E327, Astringent : Permet de resserrer les pores de la peau, Régulateur de pH : Stabilise le pH des cosmétiques, Kératolytique : Décolle et élimine les cellules mortes de la couche cornée de l'apiderme.Principaux synonymes. Noms français : 2-HYDROXYPROPANOIC ACID CALCIUM SALT; 2-HYDROXYPROPANOIC ACID, CALCIUM SALT; CALCIUM, LACTATE DE; HYDROXY-2 PROPANOATE DE CALCIUM; LACTATE DE CALCIUM; LACTIC ACID, CALCIUM SALT (2:1); PROPANOIC ACID, 2-HYDROXY-, CALCIUM SALT (2:1). Noms anglais :CALCIUM LACTATE; LACTIC ACID, CALCIUM SALT. Utilisation et sources d'émission :Additif alimentaire, fabrication de produits pharmaceutiques
Lactate de calcium ( CALCIUM LACTATE)
LAURYL LACTATE, Lactate de lauryle, N° CAS : 6283-92-7, Nom INCI : LAURYL LACTATE, Nom chimique : Dodecyl lactate, N° EINECS/ELINCS : 228-504-8 Ses fonctions (INCI) Emollient : Adoucit et assouplit la peau Agent d'entretien de la peau : Maintient la peau en bon état
Lactate de lauryle ( LAURYL LACTATE)
ETHYL LACTATE, N° CAS : 97-64-3. Nom INCI : ETHYL LACTATE. Nom chimique : Propanoic acid, 2-hydroxy-, ethyl ester. N° EINECS/ELINCS : 202-598-0. Solvant : Dissout d'autres substances Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. Noms français : Ethyl 2-hydropropionate Ethyl alpha-hydroxypropionate Ethyl hydroxy-2 propionate Lactate d'éthyle Lactic acid,ethyl ester Propanoic acid, 2-hydroxy-, ethyl ester Solactol Noms anglais : Ethyl lactate Famille chimique Ester Commentaires Le lactate d'éthyle existe sous deux formes isomériques, le (S)-lactate d'éthyle, qui est la forme L (CAS : 687-47-8) et le (R)-lactate d'éthyle, qui est la forme D (CAS : 7699-00-5); ce sont des images miroir l'une de l'autre. Le lactate d'éthyle vendu commercialement, sans désignation particulière quant à l'isomère présent, est un mélange de ces deux isomères, et il porte le numéro de CAS de la présente fiche (97-64-3). Utilisation: Le lactate d'éthyle est utilisé dans de nombreux domaines d'activité : décapage de peintures et de revêtements organiques dégraissage de pièces industrielles nettoyage de précision enlèvement des graffitis décapage d'adhésifs à base d’époxy nettoyage des presses offset formulation de produits cosmétiques et de préparations pharmaceutiques photolithographie (solvant de résine positive photosensible) polymères (solvant pour le nitrate de cellulose, l'acétobutyrate de cellulose, l'acétate de polyvinyle, les polyacrylates et polyméthacrylates, les résines polaires) synthèse organique de médicaments ou de produits agrochimiques (à partir d'un seul isomère) additif alimentaire, pharmaceutique ou cosmétique
Lactate d'éthyle ( ETHYL LACTATE)
SYNONYMS 2-Hydroxypropanoic acid; Lactic acid; 1-Hydroxyethanecarboxylic acid; Ethylidenelactic acid; alpha-Hydroxypropionic Acid; CAS NO 50-21-5, 79-33-4 (L), 10326-41-7 (D)
LACTIC ACID
LACTIC ACID Lactic acid Jump to navigationJump to search Lactic acid 7 Milchsäure.svg L-Lactic acid molecule spacefill.png Names Preferred IUPAC name 2-Hydroxypropanoic acid[1] Other names Lactic acid[1] Milk acid Identifiers CAS Number 50-21-5 check 79-33-4 (l) check 10326-41-7 (d) check 3D model (JSmol) Interactive image 3DMet B01180 Beilstein Reference 1720251 ChEBI CHEBI:422 check ChEMBL ChEMBL330546 check ChemSpider 96860 check ECHA InfoCard 100.000.017 Edit this at Wikidata EC Number 200-018-0 E number E270 (preservatives) Gmelin Reference 362717 IUPHAR/BPS 2932 KEGG C00186 PubChem CID 612 RTECS number OD2800000 UNII 33X04XA5AT ☒ UN number 3265 CompTox Dashboard (EPA) DTXSID7023192 Edit this at Wikidata InChI[show] SMILES[show] Properties Chemical formula C3H6O3 Molar mass 90.078 g·mol−1 Melting point 18 °C (64 °F; 291 K) Boiling point 122 °C (252 °F; 395 K) at 15 mmHg Solubility in water Miscible[2] Acidity (pKa) 3.86,[3] 15.1[4] Thermochemistry Std enthalpy of combustion (ΔcH⦵298) 1361.9 kJ/mol, 325.5 kcal/mol, 15.1 kJ/g, 3.61 kcal/g Pharmacology ATC code G01AD01 (WHO) QP53AG02 (WHO) Hazards GHS pictograms GHS05: Corrosive[5] GHS hazard statements H315, H318[5] GHS precautionary statements P280, P305+351+338[5] Related compounds Other anions Lactate Related carboxylic acids Acetic acid Glycolic acid Propionic acid 3-Hydroxypropanoic acid Malonic acid Butyric acid Hydroxybutyric acid Related compounds 1-Propanol 2-Propanol Propionaldehyde Acrolein Sodium lactate Ethyl lactate Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). ☒ verify (what is check☒ ?) Infobox references Lactic acid is an organic acid. It has a molecular formula CH3CH(OH)COOH. It is white in the solid state and it is miscible with water.[2] When in the dissolved state, it forms a colorless solution. Production includes both artificial synthesis as well as natural sources. Lactic acid is an alpha-hydroxy acid (AHA) due to the presence of a hydroxyl group adjacent to the carboxyl group. It is used as a synthetic intermediate in many organic synthesis industries and in various biochemical industries. The conjugate base of lactic acid is called lactate. In solution, it can ionize, producing the lactate ion CH 3CH(OH)CO− 2. Compared to acetic acid, its pKa is 1 unit less, meaning lactic acid is ten times more acidic than acetic acid. This higher acidity is the consequence of the intramolecular hydrogen bonding between the α-hydroxyl and the carboxylate group. Lactic acid is chiral, consisting of two enantiomers. One is known as l-(+)-lactic acid or (S)-lactic acid and the other, its mirror image, is d-(−)-lactic acid or (R)-lactic acid. A mixture of the two in equal amounts is called dl-lactic acid, or racemic lactic acid. Lactic acid is hygroscopic. dl-Lactic acid is miscible with water and with ethanol above its melting point, which is around 16, 17 or 18 °C. d-Lactic acid and l-lactic acid have a higher melting point. Lactic acid produced by fermentation of milk is often racemic, although certain species of bacteria produce solely (R)-lactic acid. On the other hand, lactic acid produced by anaerobic respiration in animal muscles has the (S) configuration and is sometimes called "sarcolactic" acid, from the Greek "sarx" for flesh. In animals, l-lactate is constantly produced from pyruvate via the enzyme lactate dehydrogenase (LDH) in a process of fermentation during normal metabolism and exercise.[6] It does not increase in concentration until the rate of lactate production exceeds the rate of lactate removal, which is governed by a number of factors, including monocarboxylate transporters, concentration and isoform of LDH, and oxidative capacity of tissues.[7] The concentration of blood lactate is usually 1–2 mM at rest, but can rise to over 20 mM during intense exertion and as high as 25 mM afterward.[8][9] In addition to other biological roles, l-lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), which is a Gi/o-coupled G protein-coupled receptor (GPCR).[10][11] In industry, lactic acid fermentation is performed by lactic acid bacteria, which convert simple carbohydrates such as glucose, sucrose, or galactose to lactic acid. These bacteria can also grow in the mouth; the acid they produce is responsible for the tooth decay known as caries.[12][13][14][15] In medicine, lactate is one of the main components of lactated Ringer's solution and Hartmann's solution. These intravenous fluids consist of sodium and potassium cations along with lactate and chloride anions in solution with distilled water, generally in concentrations isotonic with human blood. It is most commonly used for fluid resuscitation after blood loss due to trauma, surgery, or burns. Contents 1 History 2 Production 2.1 Fermentative production 2.2 Chemical production 3 Biology 3.1 Molecular biology 3.2 Exercise and lactate 3.3 Metabolism 4 Blood testing 5 Polymer precursor 6 Pharmaceutical and cosmetic applications 7 Foods 8 Forgery 9 Cleaning products 10 See also 11 References 12 External links History Swedish chemist Carl Wilhelm Scheele was the first person to isolate lactic acid in 1780 from sour milk.[16] The name reflects the lact- combining form derived from the Latin word lac, which means milk. In 1808, Jöns Jacob Berzelius discovered that lactic acid (actually l-lactate) also is produced in muscles during exertion.[17] Its structure was established by Johannes Wislicenus in 1873. In 1856, the role of Lactobacillus in the synthesis of lactic acid was discovered by Louis Pasteur. This pathway was used commercially by the German pharmacy Boehringer Ingelheim in 1895. In 2006, global production of lactic acid reached 275,000 tonnes with an average annual growth of 10%.[18] Production Lactic acid is produced industrially by bacterial fermentation of carbohydrates, or by chemical synthesis from acetaldehyde.[19] In 2009, lactic acid was produced predominantly (70–90%)[20] by fermentation. Production of racemic lactic acid consisting of a 1:1 mixture of d and l stereoisomers, or of mixtures with up to 99.9% l-lactic acid, is possible by microbial fermentation. Industrial scale production of d-lactic acid by fermentation is possible, but much more challenging. Fermentative production Fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria: Lactobacillus acidophilus, Lactobacillus casei, Lactobacillus delbrueckii subsp. bulgaricus (Lactobacillus bulgaricus), Lactobacillus helveticus, Lactococcus lactis, and Streptococcus salivarius subsp. thermophilus (Streptococcus thermophilus). As a starting material for industrial production of lactic acid, almost any carbohydrate source containing C5 and C6 sugars can be used. Pure sucrose, glucose from starch, raw sugar, and beet juice are frequently used.[21] Lactic acid producing bacteria can be divided in two classes: homofermentative bacteria like Lactobacillus casei and Lactococcus lactis, producing two moles of lactate from one mole of glucose, and heterofermentative species producing one mole of lactate from one mole of glucose as well as carbon dioxide and acetic acid/ethanol.[22] Chemical production Racemic lactic acid is synthesized industrially by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile. When hydrolysis is performed by hydrochloric acid, ammonium chloride forms as a by-product; the Japanese company Musashino is one of the last big manufacturers of lactic acid by this route.[23] Synthesis of both racemic and enantiopure lactic acids is also possible from other starting materials (vinyl acetate, glycerol, etc.) by application of catalytic procedures.[24] Biology Molecular biology l-Lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), a Gi/o-coupled G protein-coupled receptor (GPCR).[10][11] Exercise and lactate During power exercises such as sprinting, when the rate of demand for energy is high, glucose is broken down and oxidized to pyruvate, and lactate is then produced from the pyruvate faster than the body can process it, causing lactate concentrations to rise. The production of lactate is beneficial for NAD+ regeneration (pyruvate is reduced to lactate while NADH is oxidized to NAD+), which is used up in oxidation of glyceraldehyde 3-phosphate during production of pyruvate from glucose, and this ensures that energy production is maintained and exercise can continue. During intense exercise, the respiratory chain cannot keep up with the amount of hydrogen ions that join to form NADH, and cannot regenerate NAD+ quickly enough. The resulting lactate can be used in two ways: Oxidation back to pyruvate by well-oxygenated muscle cells, heart cells, and brain cells Pyruvate is then directly used to fuel the Krebs cycle Conversion to glucose via gluconeogenesis in the liver and release back into circulation; see Cori cycle[25] If blood glucose concentrations are high, the glucose can be used to build up the liver's glycogen stores. However, lactate is continually formed even at rest and during moderate exercise. Some causes of this are metabolism in red blood cells that lack mitochondria, and limitations resulting from the enzyme activity that occurs in muscle fibers having high glycolytic capacity.[25] In 2004, Robergs et al. maintained that lactic acidosis during exercise is a "construct" or myth, pointing out that part of the H+ comes from ATP hydrolysis (ATP4− + H2O → ADP3− + HPO2− 4 + H+), and that reducing pyruvate to lactate (pyruvate− + NADH + H+ → lactate− + NAD+) actually consumes H+.[26] Lindinger et al.[27] countered that they had ignored the causative factors of the increase in [H+]. After all, the production of lactate− from a neutral molecule must increase [H+] to maintain electroneutrality. The point of Robergs's paper, however, was that lactate− is produced from pyruvate−, which has the same charge. It is pyruvate− production from neutral glucose that generates H+: Polymer precursor Main article: polylactic acid Two molecules of lactic acid can be dehydrated to the lactone lactide. In the presence of catalysts lactide polymerize to either atactic or syndiotactic polylactide (PLA), which are biodegradable polyesters. PLA is an example of a plastic that is not derived from petrochemicals. Pharmaceutical and cosmetic applications Lactic acid is also employed in pharmaceutical technology to produce water-soluble lactates from otherwise-insoluble active ingredients. It finds further use in topical preparations and cosmetics to adjust acidity and for its disinfectant and keratolytic properties. Foods Lactic acid is found primarily in sour milk products, such as koumiss, laban, yogurt, kefir, and some cottage cheeses. The casein in fermented milk is coagulated (curdled) by lactic acid. Lactic acid is also responsible for the sour flavor of sourdough bread. In lists of nutritional information lactic acid might be included under the term "carbohydrate" (or "carbohydrate by difference") because this often includes everything other than water, protein, fat, ash, and ethanol.[40] If this is the case then the calculated food energy may use the standard 4 kilocalories (17 kJ) per gram that is often used for all carbohydrates. But in some cases lactic acid is ignored in the calculation.[41] The energy density of lactic acid is 362 kilocalories (1,510 kJ) per 100 g.[42] Some beers (sour beer) purposely contain lactic acid, one such type being Belgian lambics. Most commonly, this is produced naturally by various strains of bacteria. These bacteria ferment sugars into acids, unlike the yeast that ferment sugar into ethanol. After cooling the wort, yeast and bacteria are allowed to “fall” into the open fermenters. Brewers of more common beer styles would ensure that no such bacteria are allowed to enter the fermenter. Other sour styles of beer include Berliner weisse, Flanders red and American wild ale.[43][44] In winemaking, a bacterial process, natural or controlled, is often used to convert the naturally present malic acid to lactic acid, to reduce the sharpness and for other flavor-related reasons. This malolactic fermentation is undertaken by lactic acid bacteria. While not normally found in significant quantities in fruit, lactic acid is the primary organic acid in akebia fruit, making up 2.12% of the juice.[45] As a food additive it is approved for use in the EU,[46] USA[47] and Australia and New Zealand;[48] it is listed by its INS number 270 or as E number E270. Lactic acid is used as a food preservative, curing agent, and flavoring agent.[49] It is an ingredient in processed foods and is used as a decontaminant during meat processing.[50] Lactic acid is produced commercially by fermentation of carbohydrates such as glucose, sucrose, or lactose, or by chemical synthesis.[49] Carbohydrate sources include corn, beets, and cane sugar.[51] Forgery Lactic acid has historically been used to assist with the erasure of inks from official papers to be modified during forgery.[52] Cleaning products Lactic acid is used in some liquid cleaners as a descaling agent for removing hard water deposits such as calcium carbonate, forming the lactate, Calcium lactate. Owing to its high acidity, such deposits are eliminated very quickly, especially where boiling water is used, as in kettles. It also is gaining popularity in antibacterial dish detergents and hand soaps replacing Triclosan. See also Hydroxybutyric acid Acids in wine Alanine cycle Biodegradable plastic Dental caries MCT1, a lactate transporter Thiolactic acid Lactic acid, or lactate, is a chemical byproduct of anaerobic respiration — the process by which cells produce energy without oxygen around. Bacteria produce it in yogurt and our guts. Lactic acid is also in our blood, where it's deposited by muscle and red blood cells. It was long thought that lactic acid was the cause of muscle soreness during and after an intense period of exercise, but recent research suggests that's not true, said Michael Gleeson, an exercise biochemist at Loughborough University in the U.K., and author of "Eat, Move, Sleep, Repeat" (Meyer & Meyer Sport, 2020). "Lactate has always been thought of as the bad boy of exercise," Gleeson told Live Science. Contrary to that reputation, lactic acid is a constant, harmless presence in our bodies. While it does increase in concentration when we exercise hard, it returns to normal levels as soon as we're able to rest — and even gets recycled back into energy our body can use later on, Gleeson said. CLOSE How muscles produce lactic acid Throughout most of the day, our body burns energy aerobically — that is, in the presence of oxygen. Part of that energy comes from sugar, which our muscle cells break down in a series of chemical reactions called glycolysis. (We also get energy from fat, but that involves a whole other chemical process). The end product of glycolysis is pyruvate, a chemical that the body uses to produce even more energy. But energy can be harvested from pyruvate only in the presence of oxygen. That changes during hard exercise. Related: Muscle spasms and cramps: Causes and treatments When you break into an all-out sprint your muscles start working overtime. The harder you work, the more energy your muscles need to sustain your pace. Luckily, our muscles have built-in turbo-boosters, called fast-twitch muscle. Unlike slow-twitch muscle, which we use for most of the day, fast-twitch muscle is super-effective at producing lots of energy quickly and does so anaerobically, Gleeson said. Fast-twitch muscle also uses glycolysis to produce energy, but it skips harvesting energy from pyruvate, a process that takes oxygen. Instead, pyruvate gets converted into a waste product, lactic acid, and released into the bloodstream. It's a common misconception that muscle cells produce lactic acid when they can't get enough oxygen, Gleeson said. "That's not the case. Your muscles are getting plenty of oxygen," he said. But in times of intense energy needs, muscles switch to anaerobic respiration simply because it's a much quicker way to produce energy. Other sources of lactic acid Muscle cells aren't the only sources of lactic acid. Red blood cells also produce lactic acid as they roam the body, according to the online text Anatomy and Physiology published by Oregon State University. Red blood cells don't have mitochondria — the part of the cell responsible for aerobic respiration — so they only respire anaerobically. Many species of bacteria also respire anaerobically and produce lactic acid as a waste product. In fact, these species make up between 0.01-1.8% of the human gut, according to a review published in the Journal of Applied Microbiology. The more sugar these little guys eat, the more lactic acid they produce. Slightly more insidious are the lactic acid bacteria that live in our mouths. Because of the acidifying effect they have on saliva, these bacteria are bad news for tooth enamel, according to a study published in Microbiology. Finally, lactic acid is commonly found in fermented dairy products, like buttermilk, yogurt and kefir. Bacteria in these foods use anaerobic respiration to break lactose — milk sugar — into lactic acid. That doesn't mean that lactic acid itself is a dairy product, however — it's 100% vegan. It happens to get its name from dairy simply because Carl Wilhelm, the first scientist to isolate lactic acid, did so from some spoiled milk, according to a study published in the American Journal of Physiology. A young girl eating yogurt out of a cup. Lactic acid is found in fermented dairy products, like yogurt, but lactic acid itself isn't dairy — it's 100% vegan. (Image credit: Shutterstock) Your body on lactic acid It's common to feel a burning in your legs after you squat with heavy weights, or complete a hard workout. But contrary to popular belief, it's not lactic acid that causes the soreness, Gleeson said. Lactic acid is processed by the liver and the heart. The liver converts it back into sugar; the heart converts it into pyruvate. During exercise, concentrations of lactic acid in the body do spike because the heart and liver can't deal with the waste product as quickly as it's produced. But as soon as we're done exercising, lactic acid concentrations go back to normal, Gleeson said. Related: Feel the pain? Don't blame lactic acid. Muscle soreness after exercise most likely has more to do with tissue damage and inflammation, Gleeson said. Hard exercise physically breaks down your muscles, and it can take days for them to recover. Lactic acid can build up to life-threatening levels in the body, according to a review published in the Mayo Clinic Proceedings. But this condition, called acute lactic acidosis, happens because of acute illness or injury, not exercise. When tissues are deprived of blood due to a heart attack or sepsis, for example, they tend to go into anaerobic respiration, producing lactic acid. "They get starved of oxygen," Gleeson said. But Gleeson said he's never heard of a case of life-threatening lactic acidosis because of exercise. "That would be most unusual." Additional resources: Read about anaerobic respiration on Khan Academy. Find out why you feel so sore after a workout. Learn about acute lactic acidosis on Medscape.
LACTIC ACID (2-HYDROXYPROPIONIC ACID)
Lactic acid (2-hydroxypropionic acid) is the most widely occurring organic acid in nature.
Due to its chiral a-carbon atom, Lactic acid (2-hydroxypropionic acid) has two enantiomeric forms.
Of these, Lactic acid (2-hydroxypropionic acid) is more important in food and pharmaceutical industries because humans have only L-lactate dehydrogenase.

CAS: 50-21-5
MF: C3H6O3
MW: 90.08
EINECS: 200-018-0

Synonyms
FEMA 2611;DL-ALPHA-HYDROXYPROPIONIC ACID;DL-Lactic acid, ACS reagent, 85+%;LACTIC ACID, 85% REAGENT (ACS);Lactic;dl-lactic acid, acs;LACTICACID,RACEMIC,USP;2-Hydroxy-2-methylacetic acid
;lactic acid;2-hydroxypropanoic acid;DL-Lactic acid;50-21-5;2-hydroxypropionic acid;Milk acid;lactate;Tonsillosan;Racemic lactic acid;Ordinary lactic acid;Ethylidenelactic acid;26100-51-6;Lactovagan;Acidum lacticum;Milchsaeure;Lactic acid, dl-;Kyselina mlecna;Lacticum acidum;DL-Milchsaeure;Lactic acid USP;(+/-)-Lactic acid;Propanoic acid, 2-hydroxy-;Aethylidenmilchsaeure;598-82-3;1-Hydroxyethanecarboxylic acid;alpha-Hydroxypropionic acid;Lactic acid (natural);(RS)-2-Hydroxypropionsaeure;FEMA No. 2611;Milchsaure;Kyselina 2-hydroxypropanova;Lurex;Propionic acid, 2-hydroxy-;Purac FCC 80;Purac FCC 88;Cheongin samrakhan;DL- lactic acid;FEMA Number 2611;CCRIS 2951;HSDB 800;Cheongin Haewoohwan;Cheongin Haejanghwan;SY-83;2-Hydroxypropionicacid;(+-)-2-Hydroxypropanoic acid;Biolac;NSC 367919
;Lactic acid, tech grade;Chem-Cast;alpha-Hydroxypropanoic acid;AI3-03130;HIPURE 88;EINECS 200-018-0;EINECS 209-954-4;EPA Pesticide Chemical Code 128929;Lactic acid,buffered;NSC-367919;UNII-3B8D35Y7S4;2-Hydroxy-2-methylacetic acid;BRN 5238667;INS NO.270;DTXSID7023192;(+/-)-2-hydroxypropanoic acid;CHEBI:78320;INS-270;2 Hydroxypropanoic Acid;3B8D35Y7S4;E 270
;MFCD00004520;LACTIC ACID (+-);.alpha.-Hydroxypropanoic acid;.alpha.-Hydroxypropionic acid;DTXCID003192;E-270;EC 200-018-0;NCGC00090972-01;2-hydroxy-propionic acid;C01432;Milchsaure [German];Lactic acid [JAN];Kyselina mlecna [Czech];Propanoic acid, hydroxy-;CAS-50-21-5;(R)-2-Hydroxy-propionic acid;H-D-Lac-OH;2 Hydroxypropionic Acid;Kyselina 2-hydroxypropanova [Czech];Lactic acid [USP:JAN];lactasol;1-Hydroxyethane 1-carboxylic acid;acido lactico;DL-Milchsaure;MFCD00064266;(2RS)-2-Hydroxypropanoic acid;Lactate (TN);4b5w;Propanoic acid, (+-);DL-Lactic Acid, Racemic;LACTIC ACID (II);(.+/-.)-Lactic acid;Lactic acid (7CI,8CI);DL-Lactic Acid (90%);Lactic acid (JP17/USP);Lactic acid, 85%, FCC;Lactic Acid, Racemic, USP;NCIOpen2_000884;(+-)-LACTIC ACID;DL-LACTIC ACID [MI];LACTIC ACID [WHO-IP];(RS)-2-hydroxypropanoic acid;LACTIC ACID, DL-(II);LACTICUM ACIDUM [HPUS];1-hydroxyethane carboxylic acid;33X04XA5AT;DL-Lactic Acid (90per cent);L-(+)-Lactic acid, 98%;CHEMBL1200559;Lactic acid, natural, >=85%;BDBM23233;L-lactic acid or dl-lactic acid;Lactic Acid, 85 Percent, FCC;LACTIC ACID, DL- [II];DL-Lactic acid, ~90% (T);DL-Lactic acid, AR, >=88%;DL-Lactic acid, LR, >=88%;DL- LACTIC ACID [WHO-DD];LACTIC ACID (EP MONOGRAPH);Lactic Acid, 10 Percent Solution;HY-B2227;LACTIC ACID (USP MONOGRAPH);Propanoic acid, 2-hydroxy- (9CI);Tox21_111049;Tox21_202455;Tox21_303616;BBL027466;NSC367919;STL282744;AKOS000118855;AKOS17278364;Tox21_111049_1;ACIDUM LACTICUM [WHO-IP LATIN];AM87208;DB04398;SB44647;SB44652;Propanoic acid,2-hydroxy-,(.+/-.)-;2-Hydroxypropionic acid, DL-Lactic acid;NCGC00090972-02;NCGC00090972-03;NCGC00257515-01;NCGC00260004-01;849585-22-4;Lactic Acid, 85 Percent, Reagent, ACS;(R)-Lactate;(R)-2-Hydroxypropionic acid;;DB-071134;DB-347146;CS-0021601;L0226;EN300-19542;Lactic acid, meets USP testing specifications;D00111;F71201;A877374;DL-Lactic acid, SAJ first grade, 85.0-92.0%;Q161249;DL-Lactic acid, JIS special grade, 85.0-92.0%;Dl-alpha-hydroxypropionic acid;2-hydroxypropionic acid;F2191-0200;Z104474158;BC10F553-5D5D-4388-BB74-378ED4E24908;Lactic acid, United States Pharmacopeia (USP) Reference Standard;Lactic acid, Pharmaceutical Secondary Standard; Certified Reference Material;DL-Lactic acid 90%, synthetic, meets the analytical specifications of Ph. Eur.;152-36-3

The chemical behavior of Lactic acid (2-hydroxypropionic acid) is mostly determined by the two functional groups.
Besides the acidic character in aqueous medium, the bifunctionality (a terminal carboxylic acid and a hydroxyl group) allows Lactic acid (2-hydroxypropionic acid) molecules to form ‘‘interesters’’ such as the cyclic dimers, the trimers, or longer lactic acid oligomers.
After its first isolation by the Swedish chemist Scheel in 1780 from sour milk, Lactic acid (2-hydroxypropionic acid) has been produced commercially since the 1880s in the United States and later in Europe.
Worldwide, Lactic acid (2-hydroxypropionic acid) production was approximately 250,000 metric tons per year in 2012 and is expected to reach 330,000 metric tons by the year 2015, with an average price of 1.25 US$ per kilogram in 2013 (food grade, 80–85 % purity).
Approximately 85 % of the demand for LA is from the food industry.
The primary use of Lactic acid (2-hydroxypropionic acid) is as a pH-adjusting agent in the beverage sector and as a preservative in the food industry.

Lactic acid (2-hydroxypropionic acid) is included in the Generally Recognized as Safe (GRAS) by the U.S. Food and Drug Administration as a food ingredient and was deemed safe by the European Food Safety Authority as well.
The acceptable daily intake for Lactic acid (2-hydroxypropionic acid) was defined by the Joint FAO/WHO Expert Committee on Food Additives as ‘‘not limited,’’ and it is also supported by the Scientific Committee of Food.
In recent decades, the consumption of Lactic acid (2-hydroxypropionic acid) due to its novel applications has grown quite rapidly, by 19 % per year.
Nonfood use of Lactic acid (2-hydroxypropionic acid) for polymer production contributes to this growth.
Biodegradable polylactic acid is considered to be an environmentally friendly alternative to other plastics from petroleum.
Lactic acid (2-hydroxypropionic acid) is used in various fields, including drug delivery systems, medical devices, fibers, and packaging materials.
Lactic acid (2-hydroxypropionic acid) can be produced via chemical synthesis or carbohydrate fermentation.
The chemical route has various issues, including toxic raw materials, low conversion rates, and especially the inability to produce the optically pure isomer.
Therefore, approximately 90 % of Lactic acid (2-hydroxypropionic acid) worldwide is produced by biotechnological processes, namely fermentations using renewable resources, which is relatively fast, economical, and able to supply selectively one or two stereoisomers of lactic acid.

Lactic acid (2-hydroxypropionic acid) is an organic acid.
Lactic acid (2-hydroxypropionic acid) has the molecular formula CH3CH(OH)COOH.
Lactic acid (2-hydroxypropionic acid) is white in the solid state and it is miscible with water.
When in the dissolved state, Lactic acid (2-hydroxypropionic acid) forms a colorless solution.
Production includes both artificial synthesis as well as natural sources.
Lactic acid (2-hydroxypropionic acid) is an alpha-hydroxy acid (AHA) due to the presence of a hydroxyl group adjacent to the carboxyl group.
Lactic acid (2-hydroxypropionic acid) is used as a synthetic intermediate in many organic synthesis industries and in various biochemical industries.

The conjugate base of Lactic acid (2-hydroxypropionic acid) is called lactate (or the lactate anion).
The name of the derived acyl group is lactoyl.
In solution, Lactic acid (2-hydroxypropionic acid) can ionize by a loss of a proton to produce the lactate ion CH
3CH(OH)CO−2.
Compared to acetic acid, its pKa is 1 unit less, meaning Lactic acid (2-hydroxypropionic acid) is ten times more acidic than acetic acid.
This higher acidity is the consequence of the intramolecular hydrogen bonding between the α-hydroxyl and the carboxylate group.

Lactic acid (2-hydroxypropionic acid) is chiral, consisting of two enantiomers.
One is known as Lactic acid (2-hydroxypropionic acid), (S)-lactic acid, or (+)-lactic acid, and the other, its mirror image, is d-lactic acid, (R)-lactic acid, or (−)-lactic acid.
A mixture of the two in equal amounts is called dl-lactic acid, or racemic Lactic acid (2-hydroxypropionic acid).
Lactic acid is hygroscopic.
Lactic acid (2-hydroxypropionic acid) is miscible with water and with ethanol above its melting point, which is about 16 to 18 °C (61 to 64 °F).
d-Lactic acid and l-lactic acid have a higher melting point.
Lactic acid (2-hydroxypropionic acid) produced by fermentation of milk is often racemic, although certain species of bacteria produce solely d-lactic acid.
On the other hand, Lactic acid (2-hydroxypropionic acid) produced by anaerobic respiration in animal muscles has the enantiomer and is sometimes called "sarcolactic" acid, from the Greek sarx, meaning "flesh".

In animals, Lactic acid (2-hydroxypropionic acid) is constantly produced from pyruvate via the enzyme lactate dehydrogenase (LDH) in a process of fermentation during normal metabolism and exercise.
Lactic acid (2-hydroxypropionic acid) does not increase in concentration until the rate of lactate production exceeds the rate of lactate removal, which is governed by a number of factors, including monocarboxylate transporters, concentration and isoform of LDH, and oxidative capacity of tissues.
The concentration of blood lactate is usually 1–2 mMTooltip millimolar at rest, but can rise to over 20 mM during intense exertion and as high as 25 mM afterward.
In addition to other biological roles, Lactic acid (2-hydroxypropionic acid) is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), which is a Gi/o-coupled G protein-coupled receptor (GPCR).

In industry, Lactic acid (2-hydroxypropionic acid) fermentation is performed by lactic acid bacteria, which convert simple carbohydrates such as glucose, sucrose, or galactose to lactic acid.
These bacteria can also grow in the mouth; the acid they produce is responsible for the tooth decay known as cavities.
In medicine, lactate is one of the main components of lactated Ringer's solution and Hartmann's solution.
These intravenous fluids consist of sodium and potassium cations along with lactate and chloride anions in solution with distilled water, generally in concentrations isotonic with human blood.
Lactic acid (2-hydroxypropionic acid) is most commonly used for fluid resuscitation after blood loss due to trauma, surgery, or burns.

Lactic acid (2-hydroxypropionic acid) is an alpha hydroxy acid, an organic compound with the formula CH3CH(OH)CO2H.
Lactic acid (2-hydroxypropionic acid) is a white, water-soluble solid or clear liquid,having a mild acid odor and taste.
Lactic acid (2-hydroxypropionic acid) is found in muscle tissue and blood and is an intermediate in the metabolism of carbohydrates.
Lactic acid (2-hydroxypropionic acid) is also used as an acidifying agent.
Lactic acid (2-hydroxypropionic acid) is produced from natural corn starch by advanced bio-fermentation and refining technology.

Lactic acid (2-hydroxypropionic acid) is a compound that plays a role in a variety of biochemical processes.
Lactic acid (2-hydroxypropionic acid) is a carboxylic acid with a molecular formula of C3H6O3.
Lactic acid (2-hydroxypropionic acid) is a carboxylic acid containing a hydroxyl group, so it is an alpha-hydroxy acid (AHA).
In the aqueous solution, Lactic acid (2-hydroxypropionic acid)'s carboxyl group releases a proton to produce the lactate ion CH3CHOHCOO.
During fermentation, lactate dehydrogenase converts pyruvate to Lactic acid (2-hydroxypropionic acid).
In general metabolism and exercise, Lactic acid (2-hydroxypropionic acid) is constantly produced, but its concentration generally does not increase.

Lactic acid (2-hydroxypropionic acid) Chemical Properties
Melting point: 18°C
Boiling point: 122 °C/15 mmHg (lit.)
Alpha: -0.05 º (c= neat 25 ºC)
Density: 1.209 g/mL at 25 °C (lit.)
Vapor density: 0.62 (vs air)
Vapor pressure: 19 mm of Hg (@ 20°C)
FEMA: 2611 | LACTIC ACID
Refractive index: n20/D 1.4262
Fp: >230 °F
Storage temp.: 2-8°C
Solubility: Miscible with water and with ethanol (96 per cent).
Form: syrup
pka: 3.08(at 100℃)
Color: Colorless to yellow
Specific Gravity: 1.209
PH: 3.51(1 mM solution);2.96(10 mM solution);2.44(100 mM solution);
Odor: at 100.00 %. odorless
Odor Type: odorless
Water Solubility: SOLUBLE
Merck: 14,5336
JECFA Number: 930
BRN: 1209341
Dielectric constant: 22.0(16℃)
Stability: Stable. Combustible. Incompatible with strong oxidizing agents.
InChIKey: JVTAAEKCZFNVCJ-UHFFFAOYSA-N
LogP: -0.72
CAS DataBase Reference: 50-21-5(CAS DataBase Reference)
NIST Chemistry Reference: Lactic acid (2-hydroxypropionic acid) (50-21-5)
EPA Substance Registry System: Lactic acid (2-hydroxypropionic acid) (50-21-5)

Lactic acid (2-hydroxypropionic acid), CH3CHOHCOOH, also known as 2-hydroxypropanoic acid, is a hygroscopic liquid that exists in three isometric forms.
Lactic acid (2-hydroxypropionic acid) is found in blood and animal tissue as a product of glucose and glycogen metabolism.
Lactic acid (2-hydroxypropionic acid) is obtained by fermentation of sucrose (corn refining), The racemic mixture is present in foods prepared by bacterial fermentation or prepared synthetically.
Lactic acid (2-hydroxypropionic acid) is soluble in water,alcohol,and ether.
Lactic acid (2-hydroxypropionic acid) is used as a solvent, in manufacturing confectionery, and in medicine.
Lactic acid (2-hydroxypropionic acid) is odorless.
Lactic acid (2-hydroxypropionic acid) consists of a mixture of lactic acid (C3H6O3) and lactic acid lactate (C6H10O5).
The commercial product is the racemic form.

Lactic acid (2-hydroxypropionic acid) is usually available in solutions containing 50 to 90% lactic acid.
Lactic acid (2-hydroxypropionic acid) consists of a mixture of 2-hydroxypropionic acid, its condensation products, such as lactoyllactic acid and other polylactic acids, and water.
Lactic acid (2-hydroxypropionic acid) is usually in the form of the racemate, (RS)-lactic acid, but in some cases the (S)-(+)-isomer is predominant.
A colorless or yellowish, nearly odorless, syrupy liquid consisting of a mixture of lactic acid (C3H6O3) and lactic acid lactate (C6H10O5).
Lactic acid (2-hydroxypropionic acid) is obtained by the lactic fermentation of sugars or is prepared synthetically.
The commercial product is the racemic form.
Lactic acid (2-hydroxypropionic acid) is usually available in solutions containing the equivalent of from 50% to 90% lactic acid.
Lactic acid (2-hydroxypropionic acid) is hygroscopic, and when concentrated by boiling, the acid condenses to form lactic acid lactate, 2-(lactoyloxy)propanoic acid, which on dilution and heat ing hydrolyzes to lactic acid.
Lactic acid (2-hydroxypropionic acid) is miscible with water and with alcohol.

Uses
Lactic acid (2-hydroxypropionic acid) is a multi-purpose ingredient used as a preservative, exfoliant, moisturizer, and to provide acidity to a formulation.
In the body, Lactic acid (2-hydroxypropionic acid) is found in the blood and muscle tissue as a product of the metabolism of glucose and glycogen.
Lactic acid (2-hydroxypropionic acid) is also a component of the skin’s natural moisturizing factor.
Lactic acid (2-hydroxypropionic acid) has better water intake than glycerin.
Studies indicate an ability to increase the water-retention capacity of the stratum corneum.
They also show that the pliability of the stratum corneum layer is closely related to the absorption of Lactic acid (2-hydroxypropionic acid); that is, the greater the amount of absorbed lactic acid, the more pliable the stratum corneum layer.
Researchers report that continuous use of preparations formulated with lactic acid in concentrations ranging between 5 and 12 percent provided a mild to moderate improvement in fine wrinkling and promote softer, smoother skin.
Lactic acid (2-hydroxypropionic acid)'s exfoliating properties can help in the process of removing excess pigment from the surface of the skin, as well as improving skin texture and feel.

Lactic acid (2-hydroxypropionic acid) is an alpha hydroxy acid occurring in sour milk and other lesser-known sources, such as beer, pickles, and foods made through a process of bacterial fermentation.
Lactic acid (2-hydroxypropionic acid) is caustic when applied to the skin in highly concentrated solutions.
Lactic acid (2-hydroxypropionic acid) can be used in fruit wine, beverages, meat, food, pastry making, vegetables, pickling and canning processing, grain processing, fruit storage, etc., because Lactic acid (2-hydroxypropionic acid) has the ability to adjust pH, extend shelf life, flavor, maintain food color, and improve Product quality and other effects;
In terms of seasonings, the special sourness of Lactic acid (2-hydroxypropionic acid) can increase the deliciousness of food.
Adding an appropriate amount of Lactic acid (2-hydroxypropionic acid) to salads, soy sauce, vinegar and other seasonings can maintain the stability of the microorganisms in the product and make the taste more mild.
Lactic acid (2-hydroxypropionic acid) is an inherent ingredient in dairy products.
Lactic acid (2-hydroxypropionic acid) has the taste of dairy products and good antimicrobial effects.
Lactic acid (2-hydroxypropionic acid) has been widely used in foods such as blended yogurt, cheese, ice cream, etc., and has become a popular sour agent for dairy products.

Biology
Molecular biology
Lactic acid (2-hydroxypropionic acid) is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), a Gi/o-coupled G protein-coupled receptor (GPCR).

Exercise and lactate
During power exercises such as sprinting, when the rate of demand for energy is high, glucose is broken down and oxidized to pyruvate, and lactate is then produced from the pyruvate faster than the body can process Lactic acid (2-hydroxypropionic acid), causing lactate concentrations to rise.
The production of Lactic acid (2-hydroxypropionic acid) is beneficial for NAD+ regeneration (pyruvate is reduced to lactate while NADH is oxidized to NAD+), which is used up in oxidation of glyceraldehyde 3-phosphate during production of pyruvate from glucose, and this ensures that energy production is maintained and exercise can continue.
During intense exercise, the respiratory chain cannot keep up with the amount of hydrogen ions that join to form NADH, and cannot regenerate NAD+ quickly enough.

The resulting lactate can be used in two ways:

Oxidation back to pyruvate by well-oxygenated muscle cells, heart cells, and brain cells
Pyruvate is then directly used to fuel the Krebs cycle
Conversion to glucose via gluconeogenesis in the liver and release back into circulation; see Cori cycle
If blood glucose concentrations are high, the glucose can be used to build up the liver's glycogen stores.
However, lactate is continually formed at rest and during all exercise intensities.
Lactate serves as a metabolic fuel being produced and oxidatively disposed in resting and exercising muscle.
Some causes of this are metabolism in red blood cells that lack mitochondria, and limitations resulting from the enzyme activity that occurs in muscle fibers having high glycolytic capacity.
Lactic acidosis is a physiological condition characterized by accumulation of lactate (especially l-lactate), with formation of an excessively low pH in the tissues – a form of metabolic acidosis.

Lactic acidosis during exercise may occur due to the H+ from ATP hydrolysis (ATP4− + H2O → ADP3− + HPO2−4 + H+), and that reducing pyruvate to lactate (pyruvate− + NADH + H+ → lactate− + NAD+) actually consumes H+.
The causative factors of the increase in [H+] result from the production of lactate− from a neutral molecule, increasing [H+] to maintain electroneutrality.
A contrary view is that lactate− is produced from pyruvate−, which has the same charge.
Lactic acid (2-hydroxypropionic acid) is pyruvate− production from neutral glucose that generates H+:

C6H12O6 + 2 NAD+ + 2 ADP3− + 2 HPO2−4 → 2 CH3COCO−2 + 2 H+ + 2 NADH + 2 ATP4− + 2 H2O
Subsequent lactate− production absorbs these protons:

2 CH3COCO−2 + 2 H+ + 2 NADH → 2 CH3CH(OH)CO−2 + 2 NAD+
The combined effect is:

C6H12O6 + 2 ADP3− + 2HPO2−4 → 2 CH3CH(OH)CO−2 + 2 ATP4− + 2 H2O
Although the reaction glucose → 2 lactate− + 2 H+ releases two H+ when viewed on its own, the H+ are absorbed in the production of ATP.
On the other hand, the absorbed acidity is released during subsequent hydrolysis of ATP:

ATP4− + H2O → ADP3− + HPO2−4 + H+
So once the use of ATP is included, the overall reaction is

C6H12O6 → 2 CH3CH(OH)CO−2 + 2 H+

Neural tissue energy source
Although glucose is usually assumed to be the main energy source for living tissues, there are a few reports that indicate that Lactic acid (2-hydroxypropionic acid) is lactate, and not glucose, that is preferentially metabolized by neurons in the brain of several mammalian species (the notable ones being mice, rats, and humans).
According to the lactate-shuttle hypothesis, glial cells are responsible for transforming glucose into lactate, and for providing lactate to the neurons.
Because of this local metabolic activity of glial cells, the extracellular fluid immediately surrounding neurons strongly differs in composition from the blood or cerebrospinal fluid, being much richer with lactate, as was found in microdialysis studies.

Brain development metabolism
Some evidence suggests that lactate is important at early stages of development for brain metabolism in prenatal and early postnatal subjects, with lactate at these stages having higher concentrations in body liquids, and being utilized by the brain preferentially over glucose.
Lactic acid (2-hydroxypropionic acid) was also hypothesized that lactate may exert a strong action over GABAergic networks in the developing brain, making them more inhibitory than Lactic acid (2-hydroxypropionic acid) was previously assumed, acting either through better support of metabolites, or alterations in base intracellular pH levels, or both.

Studies of brain slices of mice show that β-hydroxybutyrate, Lactic acid (2-hydroxypropionic acid), and pyruvate act as oxidative energy substrates, causing an increase in the NAD(P)H oxidation phase, that glucose was insufficient as an energy carrier during intense synaptic activity and, finally, that Lactic acid (2-hydroxypropionic acid) can be an efficient energy substrate capable of sustaining and enhancing brain aerobic energy metabolism in vitro.
The study "provides novel data on biphasic NAD(P)H fluorescence transients, an important physiological response to neural activation that has been reproduced in many studies and that is believed to originate predominantly from activity-induced concentration changes to the cellular NADH pools."
Lactic acid (2-hydroxypropionic acid) can also serve as an important source of energy for other organs, including the heart and liver.
During physical activity, up to 60% of the heart muscle's energy turnover rate derives from Lactic acid (2-hydroxypropionic acid) oxidation.
LACTIC ACID (E270)
Lactic Acid (E270) (2-hydroxypropionic acid, CH3-CHOH-COOH) is the most widely occurring organic acid in nature.
Due to Lactic Acid (E270)s chiral a-carbon atom, lactic acid (LA) has two enantiomeric forms.
Of these, L-(+)-Lactic Acid (E270) is more important in food and pharmaceutical industries because humans have only L-lactate dehydrogenase.

CAS: 50-21-5
MF: C3H6O3
MW: 90.08
EINECS: 200-018-0

The chemical behavior of Lactic Acid (E270) is mostly determined by the two functional groups.
Besides the acidic character in aqueous medium, the bifunctionality (a terminal carboxylic acid and a hydroxyl group) allows Lactic Acid (E270) molecules to form ‘‘interesters’’ such as the cyclic dimers, the trimers, or longer lactic acid oligomers.
After Lactic Acid (E270)s first isolation by the Swedish chemist Scheel in 1780 from sour milk, lactic acid has been produced commercially since the 1880s in the United States and later in Europe.
Worldwide, Lactic Acid (E270) production was approximately 250,000 metric tons per year in 2012 and is expected to reach 330,000 metric tons by the year 2015, with an average price of 1.25 US$ per kilogram in 2013 (food grade, 80–85 % purity).
Approximately 85 % of the demand for LA is from the food industry.
The primary use of Lactic Acid (E270) is as a pH-adjusting agent in the beverage sector and as a preservative in the food industry.
Lactic Acid (E270) is included in the Generally Recognized as Safe (GRAS) by the U.S. Food and Drug Administration as a food ingredient and was deemed safe by the European Food Safety Authority as well.
The acceptable daily intake for Lactic Acid (E270) was defined by the Joint FAO/WHO Expert Committee on Food Additives as ‘‘not limited,’’ and it is also supported by the Scientific Committee of Food.
In recent decades, the consumption of Lactic Acid (E270) due to its novel applications has grown quite rapidly, by 19 % per year.
Nonfood use of Lactic Acid (E270) for polymer production contributes to this growth.
Biodegradable polylactic acid is considered to be an environmentally friendly alternative to other plastics from petroleum.

Lactic Acid (E270) is used in various fields, including drug delivery systems, medical devices, fibers, and packaging materials.
Lactic Acid (E270) can be produced via chemical synthesis or carbohydrate fermentation.
The chemical route has various issues, including toxic raw materials, low conversion rates, and especially the inability to produce the optically pure isomer.
Therefore, approximately 90 % of Lactic Acid (E270) worldwide is produced by biotechnological processes, namely fermentations using renewable resources, which is relatively fast, economical, and able to supply selectively one or two stereoisomers of lactic acid.
A colorless to yellow odorless syrupy liquid.
Corrosive to metals and tissue.
Used to make cultured dairy products, as a food preservative, and to make chemicals.
Lactic Acid (E270) is an organic acid.
Lactic Acid (E270) has the molecular formula CH3CH(OH)COOH.
Lactic Acid (E270) is white in the solid state and it is miscible with water.
When in the dissolved state, Lactic Acid (E270) forms a colorless solution.
Production includes both artificial synthesis as well as natural sources.
Lactic Acid (E270) is an alpha-hydroxy acid (AHA) due to the presence of a hydroxyl group adjacent to the carboxyl group.
Lactic Acid (E270) is used as a synthetic intermediate in many organic synthesis industries and in various biochemical industries.
The conjugate base of Lactic Acid (E270) is called lactate (or the lactate anion).
The name of the derived acyl group is lactoyl.
In solution, Lactic Acid (E270) can ionize by a loss of a proton to produce the lactate ion CH3CH(OH)CO−2.
Compared to acetic acid, Lactic Acid (E270)'s pKa is 1 unit less, meaning Lactic Acid (E270) is ten times more acidic than acetic acid.
This higher acidity is the consequence of the intramolecular hydrogen bonding between the α-hydroxyl and the carboxylate group.
Lactic Acid (E270) is chiral, consisting of two enantiomers.
One is known as l-lactic acid, (S)-lactic acid, or (+)-lactic acid, and the other, Lactic Acid (E270)'s mirror image, is d-lactic acid, (R)-lactic acid, or (−)-lactic acid.
A mixture of the two in equal amounts is called dl-lactic acid, or racemic lactic acid.
Lactic Acid (E270) is hygroscopic.
dl-Lactic acid is miscible with water and with ethanol above its melting point, which is about 16 to 18 °C (61 to 64 °F).
d-Lactic acid and l-lactic acid have a higher melting point.
Lactic Acid (E270) produced by fermentation of milk is often racemic, although certain species of bacteria produce solely d-lactic acid.

On the other hand, Lactic Acid (E270) produced by anaerobic respiration in animal muscles has the (l) enantiomer and is sometimes called "sarcolactic" acid, from the Greek sarx, meaning "flesh".
In animals, l-lactate is constantly produced from pyruvate via the enzyme lactate dehydrogenase (LDH) in a process of fermentation during normal metabolism and exercise.
Lactic Acid (E270) does not increase in concentration until the rate of lactate production exceeds the rate of lactate removal, which is governed by a number of factors, including monocarboxylate transporters, concentration and isoform of LDH, and oxidative capacity of tissues.
The concentration of blood lactate is usually 1–2 mMTooltip millimolar at rest, but can rise to over 20 mM during intense exertion and as high as 25 mM afterward.
In addition to other biological roles, l-lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), which is a Gi/o-coupled G protein-coupled receptor (GPCR).
In industry, Lactic Acid (E270) fermentation is performed by lactic acid bacteria, which convert simple carbohydrates such as glucose, sucrose, or galactose to lactic acid.
These bacteria can also grow in the mouth; the acid they produce is responsible for the tooth decay known as caries.
In medicine, lactate is one of the main components of lactated Ringer's solution and Hartmann's solution.
These intravenous fluids consist of sodium and potassium cations along with lactate and chloride anions in solution with distilled water, generally in concentrations isotonic with human blood.
Lactic Acid (E270) is most commonly used for fluid resuscitation after blood loss due to trauma, surgery, or burns.
Lactic Acid (E270), also known as Milk Acid, is found primarily in sour milk products, such as yoghurt, kefir, koumiss, lassi and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by Lactic Acid (E270).
Lactic Acid (E270) is also responsible for the sour flavour of sourdough breads.
Lactic Acid (E270) is used in beer brewing, to lower the pH and increase the body of the beer.
Lactic Acid (E270) is also used in various beverages and cocktails to impart a sour taste.

Lactic Acid (E270) Chemical Properties
Melting point: 18°C
Boiling point: 122 °C/15 mmHg (lit.)
Alpha: -0.05 º (c= neat 25 ºC)
Density: 1.209 g/mL at 25 °C (lit.)
Vapor density: 0.62 (vs air)
Vapor pressure: 19 mm of Hg (@ 20°C)
FEMA: 2611 | LACTIC ACID
Refractive index: n20/D 1.4262
Fp: >230 °F
Storage temp.: 2-8°C
Solubility: Miscible with water and with ethanol (96 per cent).
Form: syrup
Pka: 3.08(at 100℃)
Color: Colorless to yellow
Specific Gravity: 1.209
PH: 3.51(1 mM solution);2.96(10 mM solution);2.44(100 mM solution);
Odor: at 100.00 %. odorless
Odor Type: odorless
Water Solubility: SOLUBLE
Merck: 14,5336
JECFA Number: 930
BRN: 1209341
Dielectric constant: 22.0(16℃)
Stability: Stable. Combustible. Incompatible with strong oxidizing agents.
InChIKey: JVTAAEKCZFNVCJ-UHFFFAOYSA-N
LogP: -0.72
CAS DataBase Reference: 50-21-5(CAS DataBase Reference)
NIST Chemistry Reference: Propanoic acid, 2-hydroxy-(50-21-5)
EPA Substance Registry System: Lactic Acid (E270) (50-21-5)

Chemical Properties
Lactic Acid (E270) is odorless.
Lactic Acid (E270) consists of a mixture of lactic acid (C3H6O3) and lactic acid lactate (C6H10O5).
The commercial product is the racemic form.
Lactic Acid (E270) is usually available in solutions containing 50 to 90% lactic acid.
Lactic Acid (E270), CH3CHOHCOOH, also known as 2-hydroxypropanoic acid, is a hygroscopic liquid that exists in three isometric forms.
Lactic Acid (E270) is found in blood and animal tissue as a product of glucose and glycogen metabolism.
Lactic Acid (E270) is obtained by fermentation of sucrose (corn refining), The racemic mixture is present in foods prepared by bacterial fermentation or prepared synthetically.
Lactic Acid (E270) is soluble in water,alcohol,and ether.

Lactic Acid (E270) is used as a solvent, in manufacturing confectionery, and in medicine.
Lactic Acid (E270) consists of a mixture of 2-hydroxypropionic acid, its condensation products, such as lactoyllactic acid and other polylactic acids, and water.
Lactic Acid (E270) is usually in the form of the racemate, (RS)-lactic acid, but in some cases the (S)-(+)-isomer is predominant.
Lactic Acid (E270) is a practically odorless, colorless or slightly yellowcolored, viscous, hygroscopic, nonvolatile liquid.
A colorless or yellowish, nearly odorless, syrupy liquid consisting of a mixture of Lactic Acid (E270) (C3H6O3) and lactic acid lactate (C6H10O5).
Lactic Acid (E270)is obtained by the lactic fermentation of sugars or is prepared synthetically.
The commercial product is the racemic form.
Lactic Acid (E270) is usually available in solutions containing the equivalent of from 50% to 90% lactic acid.
Lactic Acid (E270) is hygroscopic, and when concentrated by boiling, the acid condenses to form lactic acid lactate, 2-(lactoyloxy)propanoic acid, which on dilution and heat ing hydrolyzes to lactic acid.
Lactic Acid (E270) is miscible with water and with alcohol.

Uses
Lactic Acid (E270) is a multi-purpose ingredient used as a preservative, exfoliant, moisturizer, and to provide acidity to a formulation.
In the body, Lactic Acid (E270) is found in the blood and muscle tissue as a product of the metabolism of glucose and glycogen.
Lactic Acid (E270) is also a component of the skin’s natural moisturizing factor.
Lactic Acid (E270) has better water intake than glycerin.
Studies indicate an ability to increase the water-retention capacity of the stratum corneum.
They also show that the pliability of the stratum corneum layer is closely related to the absorption of lactic acid; that is, the greater the amount of absorbed Lactic Acid (E270), the more pliable the stratum corneum layer.
Researchers report that continuous use of preparations formulated with lactic acid in concentrations ranging between 5 and 12 percent provided a mild to moderate improvement in fine wrinkling and promote softer, smoother skin.
Lactic Acid (E270)'s exfoliating properties can help in the process of removing excess pigment from the surface of the skin, as well as improving skin texture and feel.
Lactic Acid (E270) is an alpha hydroxy acid occurring in sour milk and other lesser-known sources, such as beer, pickles, and foods made through a process of bacterial fermentation.

Lactic Acid (E270) is caustic when applied to the skin in highly concentrated solutions.
Lactic Acid is an acidulant that is a natural organic acid present in milk, meat, and beer, but is normally associated with milk.
Lactic Acid (E270) is a syrupy liquid available as 50 and 88% aqueous solutions, and is mis- cible in water and alcohol.
Lactic Acid (E270) is heat stable, nonvolatile, and has a smooth, milk acid taste.
Lactic Acid (E270) functions as a flavor agent, preservative, and acidity adjuster in foods.
Lactic Acid (E270) is used in spanish olives to prevent spoilage and provide flavor, in dry egg powder to improve disper- sion and whipping properties, in cheese spreads, and in salad dress- ing mixes.
Lactic Acid (E270) showed good depressing effect on hornblende, pyroxene and biotite during flotation of hematite and ilmenite minerals.
Lactic Acid (E270) is used in some liquid cleaners as a descaling agent for removing hard water deposits such as calcium carbonate, forming the lactate, calcium lactate.
Owing to Lactic Acid (E270)'s high acidity, such deposits are eliminated very quickly, especially where boiling water is used, as in kettles.
Lactic Acid (E270) is used in some antibacterial soaps and dish detergents as a replacement for triclosan.
Lactic Acid (E270) has historically been used to assist with the erasure of inks from official papers to be modified during forgery.

Production Methods
Lactic Acid (E270) is prepared by the fermentation of carbohydrates, such as glucose, sucrose, and lactose, with Bacillus acidi lacti or related microorganisms.
On a commercial scale, whey, corn starch, potatoes, or molasses are used as a source of carbohydrate.
Lactic Acid (E270) may also be prepared synthetically by the reaction between acetaldehyde and carbon monoxide at 130–200°C under high pressure, or by the hydrolysis of hexoses with sodium hydroxide.
Lactic Acid (E270) prepared by the fermentation of sugars is levorotatory; lactic acid prepared synthetically is racemic.
However, Lactic Acid (E270) prepared by fermentation becomes dextrorotatory on dilution with water owing to the hydrolysis of (R)-lactic acid lactate to (S)- lactic acid.

Fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria: Lactobacillus acidophilus, Lacticaseibacillus casei (Lactobacillus casei), Lactobacillus delbrueckii subsp. bulgaricus (Lactobacillus bulgaricus), Lactobacillus helveticus, Lactococcus lactis , Bacillus amyloliquefaciens, and Streptococcus salivarius subsp. thermophilus (Streptococcus thermophilus).
As a starting material for industrial production of lactic acid, almost any carbohydrate source containing C5 (Pentose sugar) and C6 (Hexose sugar) can be used.
Pure sucrose, glucose from starch, raw sugar, and beet juice are frequently used.
Lactic Acid (E270) producing bacteria can be divided in two classes: homofermentative bacteria like Lactobacillus casei and Lactococcus lactis, producing two moles of lactate from one mole of glucose, and heterofermentative species producing one mole of lactate from one mole of glucose as well as carbon dioxide and acetic acid/ethanol.

Biochem Actions
In animals, Lactic Acid (E270) is a metabolic compound produced by proliferating cells and during anaerobic conditions such as strenuous exercise.
Lactic Acid (E270) can be oxidized back to pyruvate or converted to glucose via gluconeogenesis.
Lactic Acid (E270) is preferentially metabolized by neurons in several mammal species and during early brain development.

Synonyms
lactic acid
2-hydroxypropanoic acid
DL-Lactic acid
50-21-5
2-hydroxypropionic acid
Milk acid
lactate
Tonsillosan
Racemic lactic acid
Ordinary lactic acid
Ethylidenelactic acid
Lactovagan
Acidum lacticum
26100-51-6
Milchsaeure
Lactic acid, dl-
Kyselina mlecna
Lacticum acidum
DL-Milchsaeure
Lactic acid USP
(+/-)-Lactic acid
Propanoic acid, 2-hydroxy-
Aethylidenmilchsaeure
598-82-3
1-Hydroxyethanecarboxylic acid
alpha-Hydroxypropionic acid
Lactic acid (natural)
(RS)-2-Hydroxypropionsaeure
FEMA No. 2611
Milchsaure
Kyselina 2-hydroxypropanova
Lurex
Propionic acid, 2-hydroxy-
Purac FCC 80
Purac FCC 88
Cheongin samrakhan
FEMA Number 2611
CCRIS 2951
HSDB 800
Cheongin Haewoohwan
Cheongin Haejanghwan
SY-83
2-Hydroxypropionicacid
(+-)-2-Hydroxypropanoic acid
Biolac
NSC 367919
Lactic acid, tech grade
Chem-Cast
alpha-Hydroxypropanoic acid
AI3-03130
HIPURE 88
DL- lactic acid
EINECS 200-018-0
EINECS 209-954-4
EPA Pesticide Chemical Code 128929
Lactic acid,buffered
NSC-367919
UNII-3B8D35Y7S4
2-Hydroxy-2-methylacetic acid
BRN 5238667
INS NO.270
DTXSID7023192
(+/-)-2-hydroxypropanoic acid
CHEBI:78320
INS-270
3B8D35Y7S4
E 270
MFCD00004520
LACTIC ACID (+-)
.alpha.-Hydroxypropanoic acid
.alpha.-Hydroxypropionic acid
DTXCID003192
E-270
EC 200-018-0
NCGC00090972-01
2-hydroxy-propionic acid
(R)-2-Hydroxy-propionic acid;H-D-Lac-OH
C01432
Milchsaure [German]
Lactic acid [JAN]
Kyselina mlecna [Czech]
Propanoic acid, hydroxy-
CAS-50-21-5
2 Hydroxypropanoic Acid
2 Hydroxypropionic Acid
Kyselina 2-hydroxypropanova [Czech]
Lactic acid [USP:JAN]
lactasol
1-Hydroxyethane 1-carboxylic acid
acido lactico
DL-Milchsaure
(2RS)-2-Hydroxypropanoic acid
Lactate (TN)
4b5w
Propanoic acid, (+-)
DL-Lactic Acid, Racemic
LACTIC ACID (II)
(.+/-.)-Lactic acid
Lactic acid (7CI,8CI)
Lactic acid (JP17/USP)
Lactic acid, 85%, FCC
Lactic Acid, Racemic, USP
NCIOpen2_000884
(+-)-LACTIC ACID
DL-LACTIC ACID [MI]
LACTIC ACID [WHO-IP]
(RS)-2-hydroxypropanoic acid
LACTIC ACID, DL-(II)
LACTICUM ACIDUM [HPUS]
1-hydroxyethane carboxylic acid
33X04XA5AT
DL-Lactic Acid (90per cent)
CHEMBL1200559
Lactic acid, natural, >=85%
BDBM23233
L-lactic acid or dl-lactic acid
Lactic Acid, 85 Percent, FCC
LACTIC ACID, DL- [II]
DL-Lactic acid, ~90% (T)
DL-Lactic acid, AR, >=88%
DL-Lactic acid, LR, >=88%
DL- LACTIC ACID [WHO-DD]
LACTIC ACID (EP MONOGRAPH)
Lactic Acid, 10 Percent Solution
HY-B2227
LACTIC ACID (USP MONOGRAPH)
Propanoic acid, 2-hydroxy- (9CI)
Tox21_111049
Tox21_202455
Tox21_303616
NSC367919
AKOS000118855
AKOS017278364
Tox21_111049_1
ACIDUM LACTICUM [WHO-IP LATIN]
AM87208
DB04398
SB44647
SB44652
Propanoic acid,2-hydroxy-,(.+/-.)-
2-Hydroxypropionic acid, DL-Lactic acid
NCGC00090972-02
NCGC00090972-03
NCGC00257515-01
NCGC00260004-01
26811-96-1
Lactic Acid, 85 Percent, Reagent, ACS
CS-0021601
FT-0624390
FT-0625477
FT-0627927
FT-0696525
FT-0774042
L0226
EN300-19542
Lactic acid, meets USP testing specifications
D00111
F71201
A877374
DL-Lactic acid, SAJ first grade, 85.0-92.0%
Q161249
DL-Lactic acid, JIS special grade, 85.0-92.0%
F2191-0200
Z104474158
BC10F553-5D5D-4388-BB74-378ED4E24908
Lactic acid, United States Pharmacopeia (USP) Reference Standard
Lactic acid, Pharmaceutical Secondary Standard; Certified Reference Material
DL-Lactic acid 90%, synthetic, meets the analytical specifications of Ph. Eur.
152-36-3
LACTIC ACID (MILK ACID)
DESCRIPTION:
Lactic acid (milk acid) is an organic acid.
Lactic acid (milk acid)has a molecular formula CH3CH(OH)COOH.
Lactic acid (milk acid)is white in the solid state and it is miscible with water.


CAS Number: 50-21-5
EC Number: 200-018-0

When in the dissolved state, Lactic acid (milk acid) forms a colorless solution.
Production includes both artificial synthesis as well as natural sources.
Lactic acid (milk acid)is an alpha-hydroxy acid (AHA) due to the presence of a hydroxyl group adjacent to the carboxyl group.

Lactic acid (milk acid)is used as a synthetic intermediate in many organic synthesis industries and in various biochemical industries.
The conjugate base of Lactic acid (milk acid) is called lactate (or the lactate anion).
The name of the derived acyl group is lactoyl.









In solution, it can ionize by loss of a proton to produce the lactate ion CH3CH(OH)CO−2.
Compared to acetic acid, its pKa is 1 unit less, meaning lactic acid is ten times more acidic than acetic acid.
This higher acidity is the consequence of the intramolecular hydrogen bonding between the α-hydroxyl and the carboxylate group.

Lactic acid is chiral, consisting of two enantiomers.
One is known as l-lactic acid, (S)-lactic acid, or (+)-lactic acid, and the other, its mirror image, is d-lactic acid, (R)-lactic acid, or (−)-lactic acid.
A mixture of the two in equal amounts is called dl-lactic acid, or racemic lactic acid. Lactic acid is hygroscopic.

dl-Lactic acid is miscible with water and with ethanol above its melting point, which is about 16 to 18 °C (61 to 64 °F).
d-Lactic acid and l-lactic acid have a higher melting point.
Lactic acid produced by fermentation of milk is often racemic, although certain species of bacteria produce solely d-lactic acid.

On the other hand, lactic acid produced by anaerobic respiration in animal muscles has the (l) enantiomer and is sometimes called "sarcolactic" acid, from the Greek sarx, meaning "flesh".

In animals, l-lactate is constantly produced from pyruvate via the enzyme lactate dehydrogenase (LDH) in a process of fermentation during normal metabolism and exercise.
It does not increase in concentration until the rate of lactate production exceeds the rate of lactate removal, which is governed by a number of factors, including monocarboxylate transporters, concentration and isoform of LDH, and oxidative capacity of tissues.

The concentration of blood lactate is usually 1–2 mMTooltip millimolar at rest, but can rise to over 20 mM during intense exertion and as high as 25 mM afterward.
In addition to other biological roles, l-lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), which is a Gi/o-coupled G protein-coupled receptor (GPCR).


In industry, lactic acid fermentation is performed by lactic acid bacteria, which convert simple carbohydrates such as glucose, sucrose, or galactose to lactic acid.
These bacteria can also grow in the mouth; the acid they produce is responsible for the tooth decay known as caries.
In medicine, lactate is one of the main components of lactated Ringer's solution and Hartmann's solution.

These intravenous fluids consist of sodium and potassium cations along with lactate and chloride anions in solution with distilled water, generally in concentrations isotonic with human blood.
It is most commonly used for fluid resuscitation after blood loss due to trauma, surgery, or burns.

HISTORY OF LACTIC ACID (MILK ACID):
Swedish chemist Carl Wilhelm Scheele was the first person to isolate lactic acid in 1780 from sour milk.
The name reflects the lact- combining form derived from the Latin word lac, meaning "milk".
In 1808, Jöns Jacob Berzelius discovered that lactic acid (actually l-lactate) also is produced in muscles during exertion.
Its structure was established by Johannes Wislicenus in 1873.

In 1856, the role of Lactobacillus in the synthesis of lactic acid was discovered by Louis Pasteur.
This pathway was used commercially by the German pharmacy Boehringer Ingelheim in 1895.
In 2006, global production of lactic acid reached 275,000 tonnes with an average annual growth of 10%.

PRODUCTION OF LACTIC ACID (MILK ACID):
Lactic acid is produced industrially by bacterial fermentation of carbohydrates, or by chemical synthesis from acetaldehyde.
As of 2009, lactic acid was produced predominantly (70–90%) by fermentation.

Production of racemic lactic acid consisting of a 1:1 mixture of d and l stereoisomers, or of mixtures with up to 99.9% l-lactic acid, is possible by microbial fermentation.
Industrial scale production of d-lactic acid by fermentation is possible, but much more challenging.

FERMENTATIVE PRODUCTION OF LACTIC ACID (MILK ACID):
Fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria: Lactobacillus acidophilus, Lacticaseibacillus casei (Lactobacillus casei), Lactobacillus delbrueckii subsp. bulgaricus (Lactobacillus bulgaricus), Lactobacillus helveticus, Lactococcus lactis , Bacillus amyloliquefaciens, and Streptococcus salivarius subsp. thermophilus (Streptococcus thermophilus).

As a starting material for industrial production of lactic acid, almost any carbohydrate source containing C5 (Pentose sugar) and C6 (Hexose sugar) can be used.

Pure sucrose, glucose from starch, raw sugar, and beet juice are frequently used.
Lactic acid producing bacteria can be divided in two classes: homofermentative bacteria like Lactobacillus casei and Lactococcus lactis, producing two moles of lactate from one mole of glucose, and heterofermentative species producing one mole of lactate from one mole of glucose as well as carbon dioxide and acetic acid/ethanol.

CHEMICAL PRODUCTION OF LACTIC ACID (MILK ACID):
Racemic lactic acid is synthesized industrially by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile.
When hydrolysis is performed by hydrochloric acid, ammonium chloride forms as a by-product; the Japanese company Musashino is one of the last big manufacturers of lactic acid by this route.
Synthesis of both racemic and enantiopure lactic acids is also possible from other starting materials (vinyl acetate, glycerol, etc.) by application of catalytic procedures.

BIOLOGY OF LACTIC ACID (MILK ACID):
Molecular biology
l-Lactic acid is the primary endogenous agonist of hydroxycarboxylic acid receptor 1 (HCA1), a Gi/o-coupled G protein-coupled receptor (GPCR).

During power exercises such as sprinting, when the rate of demand for energy is high, glucose is broken down and oxidized to pyruvate, and lactate is then produced from the pyruvate faster than the body can process it, causing lactate concentrations to rise.
The production of lactate is beneficial for NAD+ regeneration (pyruvate is reduced to lactate while NADH is oxidized to NAD+), which is used up in oxidation of glyceraldehyde 3-phosphate during production of pyruvate from glucose, and this ensures that energy production is maintained and exercise can continue.
During intense exercise, the respiratory chain cannot keep up with the amount of hydrogen ions that join to form NADH, and cannot regenerate NAD+ quickly enough.

The resulting lactate can be used in two ways:

Oxidation back to pyruvate by well-oxygenated muscle cells, heart cells, and brain cells
Pyruvate is then directly used to fuel the Krebs cycle
Conversion to glucose via gluconeogenesis in the liver and release back into circulation

If blood glucose concentrations are high, the glucose can be used to build up the liver's glycogen stores.
However, lactate is continually formed at rest and during all exercise intensities.
Lactate serves as a metabolic fuel being produced and oxidatively disposed in resting and exercising muscle.

Some causes of this are metabolism in red blood cells that lack mitochondria, and limitations resulting from the enzyme activity that occurs in muscle fibers having high glycolytic capacity.
Lactic acidosis is a physiological condition characterized by accumulation of lactate (especially l-lactate), with formation of an excessively low pH in the tissues – a form of metabolic acidosis.

Lactic acidosis during exercise may occur due to the H+ from ATP hydrolysis (ATP4− + H2O → ADP3− + HPO2−4 + H+), and that reducing pyruvate to lactate (pyruvate− + NADH + H+ → lactate− + NAD+) actually consumes H+.
The causative factors of the increase in [H+] result from the production of lactate− from a neutral molecule, increasing [H+] to maintain electroneutrality.
A contrary view is that lactate− is produced from pyruvate−, which has the same charge.
It is pyruvate− production from neutral glucose that generates H+:
C6H12O6 + 2 NAD+ + 2 ADP3− + 2 HPO2−4 →2 CH3COCO−2 + 2 H+ + 2 NADH + 2 ATP4− + 2 H2O
Subsequent lactate− production absorbs these protons:
2 CH3COCO−2 + 2 H+ + 2 NADH → 2 CH3CH(OH)CO−2 + 2 NAD+

Overall:
C6H12O6 + 2 NAD+ + 2 ADP3− + 2 HPO2−4 → 2 CH3COCO−2 + 2 H+ + 2 NADH + 2 ATP4− + 2 H2O→ 2 CH3CH(OH)CO−2 + 2 NAD+ + 2 ATP4− + 2 H2O
Although the reaction glucose → 2 lactate− + 2 H+ releases two H+ when viewed on its own, the H+ are absorbed in the production of ATP.
On the other hand, the absorbed acidity is released during subsequent hydrolysis of ATP: ATP4− + H2O → ADP3− + HPO2−4 + H+.

So once the use of ATP is included, the overall reaction is
C6H12O6 → 2 CH3COCO−2 + 2 H+
The generation of CO2 during respiration also causes an increase in [H+].

Neural tissue energy source
Although glucose is usually assumed to be the main energy source for living tissues, there are a few reports that indicate that it is lactate, and not glucose, that is preferentially metabolized by neurons in the brain of several mammalian species (the notable ones being mice, rats, and humans).
According to the lactate-shuttle hypothesis, glial cells are responsible for transforming glucose into lactate, and for providing lactate to the neurons.
Because of this local metabolic activity of glial cells, the extracellular fluid immediately surrounding neurons strongly differs in composition from the blood or cerebrospinal fluid, being much richer with lactate, as was found in microdialysis studies.

Brain development metabolism:
Some evidence suggests that lactate is important at early stages of development for brain metabolism in prenatal and early postnatal subjects, with lactate at these stages having higher concentrations in body liquids, and being utilized by the brain preferentially over glucose.
It was also hypothesized that lactate may exert a strong action over GABAergic networks in the developing brain, making them more inhibitory than it was previously assumed, acting either through better support of metabolites, or alterations in base intracellular pH levels, or both.

Studies of brain slices of mice show that β-hydroxybutyrate, lactate, and pyruvate act as oxidative energy substrates, causing an increase in the NAD(P)H oxidation phase, that glucose was insufficient as an energy carrier during intense synaptic activity and, finally, that lactate can be an efficient energy substrate capable of sustaining and enhancing brain aerobic energy metabolism in vitro.

The study "provides novel data on biphasic NAD(P)H fluorescence transients, an important physiological response to neural activation that has been reproduced in many studies and that is believed to originate predominantly from activity-induced concentration changes to the cellular NADH pools."

Lactate can also serve as an important source of energy for other organs, including the heart and liver.
During physical activity, up to 60% of the heart muscle's energy turnover rate derives from lactate oxidation.

Blood testing:
Reference ranges for blood tests, comparing lactate content (shown in violet at center-right) to other constituents in human blood
Blood tests for lactate are performed to determine the status of the acid base homeostasis in the body.
Blood sampling for this purpose is often arterial (even if it is more difficult than venipuncture), because lactate levels differ substantially between arterial and venous, and the arterial level is more representative for this purpose.


USES OF LACTIC ACID (MILK ACID):
Polymer precursor
Two molecules of lactic acid can be dehydrated to the lactone lactide. In the presence of catalysts lactide polymerize to either atactic or syndiotactic polylactide (PLA), which are biodegradable polyesters.
PLA is an example of a plastic that is not derived from petrochemicals.

Pharmaceutical and cosmetic applications:
Lactic acid is also employed in pharmaceutical technology to produce water-soluble lactates from otherwise-insoluble active ingredients.
It finds further use in topical preparations and cosmetics to adjust acidity and for its disinfectant and keratolytic properties.

Lactic acid containing bacteria have shown promise in reducing oxaluria with its descaling properties on calcium compounds.

Foods:
Fermented food:
Lactic acid is found primarily in sour milk products, such as kumis, laban, yogurt, kefir, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by lactic acid.
Lactic acid is also responsible for the sour flavor of sourdough bread.

In lists of nutritional information lactic acid might be included under the term "carbohydrate" (or "carbohydrate by difference") because this often includes everything other than water, protein, fat, ash, and ethanol.
If this is the case then the calculated food energy may use the standard 4 kilocalories (17 kJ) per gram that is often used for all carbohydrates.

But in some cases lactic acid is ignored in the calculation.
The energy density of lactic acid is 362 kilocalories (1,510 kJ) per 100 g.

Some beers (sour beer) purposely contain lactic acid, one such type being Belgian lambics.
Most commonly, this is produced naturally by various strains of bacteria.
These bacteria ferment sugars into acids, unlike the yeast that ferment sugar into ethanol.

After cooling the wort, yeast and bacteria are allowed to "fall" into the open fermenters.
Brewers of more common beer styles would ensure that no such bacteria are allowed to enter the fermenter.
Other sour styles of beer include Berliner weisse, Flanders red and American wild ale.

In winemaking, a bacterial process, natural or controlled, is often used to convert the naturally present malic acid to lactic acid, to reduce the sharpness and for other flavor-related reasons.
This malolactic fermentation is undertaken by lactic acid bacteria.
While not normally found in significant quantities in fruit, lactic acid is the primary organic acid in akebia fruit, making up 2.12% of the juice.

As a food additive it is approved for use in the EU,United States and Australia and New Zealand; it is listed by its INS number 270 or as E number E270.
Lactic acid is used as a food preservative, curing agent, and flavoring agent.
Lactic acid is an ingredient in processed foods and is used as a decontaminant during meat processing.

Lactic acid is produced commercially by fermentation of carbohydrates such as glucose, sucrose, or lactose, or by chemical synthesis.
Carbohydrate sources include corn, beets, and cane sugar.


CHEMICAL AND PHYSICAL PROPERTIES OF LACTIC ACID (MILK ACID):
Chemical formula C3H6O3
Molar mass 90.078 g•mol−1
Melting point 18 °C (64 °F; 291 K)
Boiling point 122 °C (252 °F; 395 K) at 15 mmHg
Solubility in water Miscible
Acidity (pKa) 3.86, 15.1
Thermochemistry
Std enthalpy of combustion (ΔcH⦵298) 1361.9 kJ/mol, 325.5 kcal/mol, 15.1 kJ/g, 3.61 kcal/g




SAFETY INFORMATION ABOUT LACTIC ACID (MILK ACID):
First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product


LACTIC ACID (MILK ACID)

Lactic acid (Milk acid), also known as milk acid, is a chemical compound with the molecular formula C3H6O3.
Lactic acid (Milk acid) is classified as an alpha-hydroxy acid (AHA) due to its structure containing a hydroxyl group adjacent to the carboxylic acid group.
Lactic acid (Milk acid) exists in two optical isomers: L-Lactic acid (Milk acid) and D-Lactic acid (Milk acid).

CAS Number: 50-21-5
EC Number: 200-018-0

Lactate, 2-Hydroxypropanoic acid, 2-Hydroxypropionic acid, alpha-Hydroxypropionic acid, 2-Hydroxypropanoate, alpha-Hydroxypropanoate, Ethylidene Lactic acid (Milk acid), Hydroxyacetic acid, SarcoLactic acid (Milk acid), 2-Hydroxypropanedioic acid, alpha-Hydroxypropanedioic acid, 2-Hydroxypropanedioate



APPLICATIONS


Lactic acid (Milk acid) is widely used in the food and beverage industry as an acidulant, flavoring agent, and preservative.
Lactic acid (Milk acid) is commonly added to dairy products, such as yogurt and cheese, to enhance flavor and acidity.
Lactic acid (Milk acid) serves as a key ingredient in the production of sourdough bread, giving it its characteristic tangy taste.
In the pharmaceutical industry, Lactic acid (Milk acid) is utilized as an excipient in drug formulations and as a pH adjuster in topical preparations.

Lactic acid (Milk acid) is employed in cosmetic products, including skin creams, lotions, and peels, for its exfoliating and moisturizing properties.
Lactic acid (Milk acid) is used in the textile industry for dyeing and finishing processes, acting as a mordant to improve color fastness.

In the agricultural sector, Lactic acid (Milk acid) is used as a crop preservative and soil conditioner to improve nutrient uptake and soil structure.
Lactic acid (Milk acid) fermentation is utilized in the production of fermented foods and beverages, such as kimchi, sauerkraut, and kombucha.

Lactic acid (Milk acid) is added to animal feed as a growth promoter and to improve digestibility in livestock.
Lactic acid (Milk acid) is employed in the production of biodegradable plastics and polymers as a precursor in polymerization reactions.
In the medical field, Lactic acid (Milk acid) is used as a diagnostic marker for conditions such as Lactic acid (Milk acid)osis and sepsis.

Lactic acid (Milk acid) serves as a chelating agent in metal cleaning and descaling formulations, aiding in the removal of mineral deposits.
Lactic acid (Milk acid) is utilized in the manufacture of biodegradable solvents and cleaning agents for industrial and household applications.

Lactic acid (Milk acid) is added to personal care products, including shampoos, conditioners, and soaps, for its antimicrobial and pH-balancing properties.
Lactic acid (Milk acid) is employed in the production of biodegradable polymers for use in agricultural mulches and packaging materials.

Lactic acid (Milk acid) serves as a corrosion inhibitor in metalworking fluids and cooling water treatments to prevent rust and scale formation.
Lactic acid (Milk acid) is utilized in the production of lactate esters, which are used as plasticizers, solvents, and surfactants in various applications.
In the brewing industry, Lactic acid (Milk acid) bacteria are used to produce sour beers, imparting tartness and complexity to the final product.

Lactic acid (Milk acid) is added to detergents and cleaning products as a pH adjuster and to enhance their effectiveness against grease and stains.
Lactic acid (Milk acid) is employed in the textile industry for dyeing and finishing processes, improving color retention and fabric softness.
In the paper and pulp industry, Lactic acid (Milk acid) is used as a pulping aid to improve fiber bonding and paper strength.

Lactic acid (Milk acid) serves as a fermentation substrate in the production of biofuels, such as ethanol and butanol, from renewable feedstocks.
Lactic acid (Milk acid) is utilized in the production of biodegradable polymers for use in medical implants and drug delivery systems.

Lactic acid (Milk acid) is added to wastewater treatment systems to enhance biological nutrient removal and reduce odor emissions.
Lactic acid (Milk acid) serves as a flavoring agent and acidity regulator in the production of confectionery, beverages, and processed foods.

Lactic acid (Milk acid) is utilized in the leather industry as a tanning agent to soften and preserve hides.
Lactic acid (Milk acid) serves as a pH regulator and buffering agent in cosmetic formulations, ensuring product stability and skin compatibility.
Lactic acid (Milk acid) is added to household cleaning products, such as bathroom cleaners and disinfectants, for its antimicrobial properties.

Lactic acid (Milk acid) is used in the production of biodegradable polymers for use in 3D printing and additive manufacturing processes.
Lactic acid (Milk acid) serves as a feedstock in the synthesis of lactide, a precursor to polyLactic acid (Milk acid) (PLA), a biodegradable plastic.
In the fermentation industry, Lactic acid (Milk acid) bacteria are used to produce probiotic supplements and fermented health drinks.

Lactic acid (Milk acid) is employed in the production of biodegradable films and coatings for food packaging applications.
Lactic acid (Milk acid) is utilized in the formulation of dietary supplements and sports nutrition products for its potential health benefits.

Lactic acid (Milk acid) serves as a corrosion inhibitor in metal finishing processes, protecting metal surfaces from oxidation and rust.
Lactic acid (Milk acid) is added to horticultural products, such as soil amendments and plant growth stimulants, to improve crop yields and soil health.
In the textile industry, Lactic acid (Milk acid) is used as a dyeing assistant to enhance color uptake and fiber penetration.

Lactic acid (Milk acid) is employed in the production of lactate-based polymers for use in biomedical applications, such as tissue engineering and drug delivery.
Lactic acid (Milk acid) serves as a flavor enhancer and preservative in the fermentation of vegetables and pickled products.

Lactic acid (Milk acid) is used in the production of biodegradable detergents and soaps for both household and industrial cleaning applications.
Lactic acid (Milk acid) is added to pet care products, such as shampoos and grooming sprays, for its moisturizing and conditioning properties.

Lactic acid (Milk acid) serves as a reducing agent in the synthesis of pharmaceutical intermediates and fine chemicals.
Lactic acid (Milk acid) is employed in the production of biodegradable lubricants and hydraulic fluids for eco-friendly applications.

Lactic acid (Milk acid) is utilized in the manufacture of biodegradable plastics for disposable food service items, such as utensils and packaging.
Lactic acid (Milk acid) serves as a pH adjuster in water treatment systems to control acidity and alkalinity levels.

Lactic acid (Milk acid) is added to skincare products, such as facial masks and serums, for its exfoliating and brightening effects on the skin.
Lactic acid (Milk acid) is used in the production of biodegradable adhesives and sealants for construction and woodworking applications.

Lactic acid (Milk acid) serves as a fermentation substrate in the production of organic acids, such as acetic acid and propionic acid, through microbial fermentation.
Lactic acid (Milk acid) is employed in the production of biodegradable detergents and cleaning agents for industrial and institutional use.
Lactic acid (Milk acid) serves as a stabilizer and pH adjuster in the formulation of beverages, including fruit juices, sports drinks, and flavored water.
Lactic acid (Milk acid) is utilized in the preservation of agricultural crops and fresh produce to extend shelf life and maintain quality.

Lactic acid (Milk acid) is used in the production of biodegradable paints and coatings for architectural and industrial applications.
Lactic acid (Milk acid) serves as a natural preservative and flavor enhancer in the fermentation of kimchi, sauerkraut, and other fermented vegetables.
Lactic acid (Milk acid) is added to cosmetic formulations, such as facial masks and serums, for its skin brightening and anti-aging properties.

Lactic acid (Milk acid) is employed in the production of biodegradable polymers for use in 3D printing and additive manufacturing.
Lactic acid (Milk acid) serves as a fermentation substrate for the production of bio-based chemicals, such as acrylic acid and succinic acid.

Lactic acid (Milk acid) is used in the production of biodegradable detergents and dishwashing liquids for household and commercial use.
Lactic acid (Milk acid) is added to animal feed as a dietary supplement to improve digestion and nutrient absorption in livestock.

Lactic acid (Milk acid) serves as a pH adjuster and flavor enhancer in the formulation of non-alcoholic beverages, such as fruit juices and soft drinks.
Lactic acid (Milk acid) is employed in the production of biodegradable polymers for use in medical implants and surgical sutures.

Lactic acid (Milk acid) is used in the production of biodegradable mulches and soil conditioners for organic farming and gardening.
Lactic acid (Milk acid) serves as a chelating agent in the formulation of metal cleaners and descalers for industrial applications.

Lactic acid (Milk acid) is added to skincare products, such as exfoliating scrubs and toners, for its gentle yet effective exfoliation properties.
Lactic acid (Milk acid) is used in the production of biodegradable solvents and cleaning agents for industrial and household applications.

Lactic acid (Milk acid) serves as a fermentation substrate for the production of biofuels, such as ethanol and butanol, from renewable feedstocks.
Lactic acid (Milk acid) is employed in the production of biodegradable plastics for use in packaging materials and disposable products.

Lactic acid (Milk acid) is used in the production of biodegradable fertilizers and soil conditioners for sustainable agriculture practices.
Lactic acid (Milk acid) serves as a pH regulator in the formulation of personal care products, such as shampoos and body washes.

Lactic acid (Milk acid) is added to dairy products, such as sour cream and cottage cheese, to enhance flavor and prolong shelf life.
Lactic acid (Milk acid) is employed in the production of biodegradable lubricants and hydraulic fluids for eco-friendly applications.

Lactic acid (Milk acid) serves as a fermentation substrate for the production of bio-based polymers, such as polyhydroxyalkanoates (PHA), for use in bioplastics.
Lactic acid (Milk acid) is used in the production of biodegradable detergents and cleaning agents for institutional and industrial use.

Lactic acid (Milk acid) serves as a pH adjuster and flavor enhancer in the formulation of fermented beverages, such as kombucha and kefir.
Lactic acid (Milk acid) is added to pet care products, such as grooming wipes and dental chews, for its antimicrobial properties.

Lactic acid (Milk acid) is employed in the production of biodegradable adhesives and sealants for construction and packaging applications.
Lactic acid (Milk acid) serves as a fermentation substrate in the production of organic acids, such as citric acid and malic acid, through microbial fermentation.



DESCRIPTION


Lactic acid (Milk acid), also known as milk acid, is a chemical compound with the molecular formula C3H6O3.
Lactic acid (Milk acid) is classified as an alpha-hydroxy acid (AHA) due to its structure containing a hydroxyl group adjacent to the carboxylic acid group.
Lactic acid (Milk acid) exists in two optical isomers: L-Lactic acid (Milk acid) and D-Lactic acid (Milk acid).
The L-Lactic acid form is the most common and is found in various natural sources, including sour milk, yogurt, and fermented foods.

Lactic acid (Milk acid) is produced through the fermentation of carbohydrates, primarily in the muscles during intense exercise when oxygen availability is limited (anaerobic metabolism).
Lactic acid (Milk acid) is also produced by bacteria, such as Lactobacillus species, during the fermentation of sugars in foods, leading to the characteristic sour taste of fermented dairy products.

Lactic acid (Milk acid) has several industrial applications, including its use as a food additive (E270) for acidity regulation, flavor enhancement, and preservation.
Lactic acid (Milk acid) is also utilized in the pharmaceutical and cosmetic industries for its exfoliating and moisturizing properties.
Additionally, Lactic acid (Milk acid) is used in the production of biodegradable polymers, as a precursor in the synthesis of lactate esters for plasticizers, and in the textile industry for dyeing and finishing processes.

In the body, Lactic acid (Milk acid) plays a crucial role in various metabolic processes.
Lactic acid (Milk acid) serves as an energy source during anaerobic metabolism, helps regulate pH balance in tissues, and contributes to gluconeogenesis (the synthesis of glucose) in the liver.
However, accumulation of Lactic acid (Milk acid) beyond the body's capacity to metabolize it can lead to a condition known as Lactic acid (Milk acid)osis, which is associated with symptoms such as muscle weakness, fatigue, and metabolic acidosis.



PROPERTIES


Chemical Formula: C3H6O3
Molecular Weight: Approximately 90.08 g/mol
Appearance: Clear, colorless to slightly yellow liquid or white crystalline solid
Odor: Slightly acidic or sour odor
Taste: Acidic or sour taste
Density: 1.206 g/cm³ (liquid), 1.213 g/cm³ (solid)
Melting Point: Approximately 16-18°C (61-64°F)
Boiling Point: Approximately 122-130°C (252-266°F) at 760 mmHg
Solubility in Water: Miscible in water, forms a clear solution
Solubility in Other Solvents: Soluble in ethanol, methanol, and other polar solvents
pH: Approximately 2.4 (for a 1% aqueous solution)
Acidity: Weak acid, with a pKa value of around 3.86 for the carboxylic acid group
Refractive Index: 1.422 (20°C)
Viscosity: Low viscosity liquid
Hygroscopicity: Hygroscopic, absorbs moisture from the air
Flash Point: Not applicable (non-flammable)
Flammability: Non-flammable
Autoignition Temperature: Not applicable
Vapor Pressure: Negligible
Partition Coefficient (Log P): -0.39
Surface Tension: Approximately 59 mN/m (at 25°C)
Vapor Density: Heavier than air
Freezing Point Depression: Reduces the freezing point of water due to its presence in aqueous solutions
Boiling Point Elevation: Increases the boiling point of water in aqueous solutions
Dielectric Constant: Approximately 69.8 (at 20°C)
Hydrogen Bond Acceptor: Yes, due to the presence of the hydroxyl group
Hydrogen Bond Donor: Yes, due to the presence of the carboxylic acid and hydroxyl groups
Optical Rotation: Approximately -0.5° (for L-Lactic acid (Milk acid))
Magnetic Susceptibility: Diamagnetic
Thermal Conductivity: Approximately 0.5 W/m·K (at 25°C)
Heat Capacity: Approximately 155 J/mol·K (at 25°C)
Molar Refractivity: Approximately 18.9 cm^3/mol
Heat of Vaporization: Approximately 43.1 kJ/mol (at boiling point)
Heat of Fusion: Approximately 11.3 kJ/mol (at melting point)
Specific Heat Capacity: Approximately 2.42 J/g·K (for solid), 2.29 J/g·K (for liquid)
Dielectric Loss Factor: Approximately 0.011 (at 25°C)
Viscous Dissipation Factor: Approximately 0.0008 (at 25°C)
Surface Energy: Approximately 42.2 mJ/m^2
Fluorescence: Weak fluorescence in the ultraviolet region
UV Absorbance: Absorbs UV light with a peak absorbance around 210 nm
Radioactivity: Not radioactive
Hazardous Polymerization: Does not undergo hazardous polymerization
Biodegradability: Biodegradable under aerobic and anaerobic conditions
Toxicity: Low acute toxicity, but concentrated solutions may cause irritation to skin, eyes, and mucous membranes



FIRST AID


Inhalation:

Move to Fresh Air:
If Lactic acid (Milk acid) vapors are inhaled, immediately move the affected person to an area with fresh air.

Ensure Breathing:
Check the person's airway, breathing, and circulation.
If breathing is difficult, ensure an open airway and provide rescue breathing if necessary.

Seek Medical Attention:
If symptoms such as difficulty breathing, coughing, or respiratory distress persist, seek medical attention promptly.

Provide Oxygen:
If available and trained to do so, administer oxygen to the affected person while awaiting medical assistance.

Keep Calm and Reassure:
Keep the affected person calm and reassure them while waiting for medical help.


Skin Contact:

Remove Contaminated Clothing:
If Lactic acid (Milk acid) comes into contact with the skin, promptly remove any contaminated clothing.

Wash Skin Thoroughly:
Wash the affected area with soap and water for at least 15 minutes, ensuring thorough rinsing to remove any traces of Lactic acid (Milk acid).

Use Mild Soap:
Use a mild soap or detergent to gently cleanse the skin, avoiding harsh chemicals that may exacerbate irritation.

Apply Moisturizer:
After washing, apply a soothing moisturizer or emollient to the affected area to help soothe and hydrate the skin.

Seek Medical Advice:
If skin irritation persists or worsens, seek medical advice or consult a healthcare professional for further evaluation and treatment.


Eye Contact:

Flush with Water:
Immediately flush the eyes with lukewarm water for at least 15 minutes, holding the eyelids open to ensure thorough rinsing.

Remove Contact Lenses:
If wearing contact lenses, remove them as soon as possible to facilitate irrigation of the eyes.

Seek Medical Attention:
Seek immediate medical attention or contact an eye specialist if irritation, pain, or redness persists after flushing.


Ingestion:

Do Not Induce Vomiting:
Do not induce vomiting if Lactic acid (Milk acid) has been ingested, as it may lead to further complications.

Do Not Drink Water:
Refrain from giving anything by mouth to the affected person unless instructed by medical personnel.

Seek Medical Assistance:
Immediately contact a poison control center or seek medical assistance for further guidance and treatment.

Provide Information:
Provide medical personnel with details regarding the amount ingested, the time of ingestion, and any symptoms experienced by the affected person.



HANDLING AND STORAGE


Handling:

Personal Protective Equipment (PPE):
Wear appropriate PPE, including chemical-resistant gloves, safety goggles or face shield, and protective clothing (such as long sleeves and pants), when handling Lactic acid (Milk acid) to minimize skin and eye contact.

Ventilation:
Use local exhaust ventilation or work in a well-ventilated area to prevent the buildup of vapors or fumes.
Avoid breathing in Lactic acid (Milk acid) vapors or mists.

Avoid Contact:
Avoid skin contact with Lactic acid (Milk acid).
In case of skin contact, promptly wash affected areas with soap and water.
Remove contaminated clothing and wash it before reuse.

Eye Protection:
Wear safety goggles or a face shield to protect eyes from potential splashes or mists of Lactic acid (Milk acid).
In case of eye contact, immediately flush eyes with water for at least 15 minutes and seek medical attention if irritation persists.

Handling Equipment:
Use equipment made of compatible materials, such as stainless steel, glass, or plastic, for handling and transferring Lactic acid (Milk acid).
Avoid the use of reactive metals like aluminum or copper.

Prevent Spills:
Handle Lactic acid (Milk acid) containers with care to prevent spills or leaks.
Use appropriate containment measures, such as secondary containment trays or spill kits, in areas where spills may occur.

Do Not Mix:
Avoid mixing Lactic acid (Milk acid) with incompatible substances, such as strong bases, oxidizing agents, or reactive metals, as it may result in hazardous chemical reactions or releases of toxic gases.

Labeling:
Clearly label containers of Lactic acid (Milk acid) with the product name, hazard symbols, handling instructions, and storage conditions to ensure proper identification and safe handling.

Avoid Ingestion:
Do not ingest Lactic acid (Milk acid). Keep food, beverages, and tobacco products away from areas where Lactic acid (Milk acid) is handled or stored.

Training:
Provide training to personnel handling Lactic acid (Milk acid) on safe handling procedures, emergency response protocols, and the use of personal protective equipment.

Storage:

Container Selection:
Store Lactic acid (Milk acid) in tightly sealed containers made of compatible materials, such as high-density polyethylene (HDPE), polypropylene (PP), or glass, to prevent moisture ingress and contamination.

Temperature Control:
Store Lactic acid (Milk acid) in a cool, dry place away from direct sunlight and heat sources. Maintain storage temperatures between 15°C to 25°C (59°F to 77°F).

Avoid Freezing:
Protect Lactic acid (Milk acid) from freezing temperatures, as freezing may result in crystallization or solidification of the solution. If frozen, allow the solution to thaw completely before use.

Separation:
Store Lactic acid (Milk acid) away from incompatible substances, including strong oxidizing agents, bases, and reactive metals, to prevent chemical reactions or hazards.

Stability:
Lactic acid (Milk acid) solutions may oxidize slowly over time, especially in the presence of air or light. Store containers tightly closed to minimize air exposure and degradation.

Handling Precautions:
Handle containers with care to prevent damage or leakage. Store containers on shelves or racks with adequate support and spacing to prevent tipping or falling.

Security Measures:
Implement security measures, such as locked storage areas or restricted access, to prevent unauthorized handling or tampering with Lactic acid (Milk acid).

Emergency Response:
Have appropriate spill containment and cleanup materials readily available in case of spills or leaks.
Train personnel on proper spill response procedures and emergency protocols.
LACTIC ACID 80%
Lactic Acid 80% is an alpha hydroxy acid that comes from milk.
As a result of its relatively greater molecular weight, Lactic Acid 80%'s keratolytic action is milder than that of glycolic acid, thus preventing skin irritations.


CAS Number: 50-21-5
EC Number: 200-018-0
Molecular Formula: C3H6O3


Lactic Acid 80%, also known as milk acid, is a chemical compound that plays a role in several biochemical processes.
Lactic Acid 80% is an alpha hydroxy acid that comes from milk.
As a result of its relatively greater molecular weight, Lactic Acid 80%'s keratolytic action is milder than that of glycolic acid, thus preventing skin irritations.


Lactic Acid 80% is a liquid solution in water of about 80% purity.
Lactic Acid 80% is an AHA.
Lactic Acid 80% is sufficient to add a few drops to 100 ml shampoo to adjust the pH.


Even as a moisturizing additive Lactic Acid 80% should not be applied more than 0,5%.
Dilute Lactic Acid 80% before use.
As with all of the acids, Lactic Acid 80% is important to let your skin acclimate to their use.


Lactic Acid 80% is an anti-wrinkle and anti-pigmentation component available in both over-the-counter and professional-grade skincare products.
Lactic Acid 80% is derived from milk and belongs to the alpha-hydroxy acid (AHAs) class of anti-ageing compounds.
Glycolic acid and citric acid are two further examples of AHAs.


Lactic Acid 80% is a strong Alpha-Hydroxy Acid and hence will have excellent exfoliant properties, although these are weaker than, but second only to, Glycolic Acid.
AHA products should be a stand alone treatment product and not included in another product.


While AHA can be included in other products there are certain incompatibilities that may arise plus AHAs (because of the pH required for best effectiveness) may not allow other products (such as cleansing masks) to work properly, and vice versa.
Lactic Acid 80% is also a widely used organic acidulate, probably because it is classified as a weak acid.


As with all manufacturing processes, we recommend lab scale trials in order to determine appropriate quantities.
Lactic Acid 80% is a liquid solution in water of about 80% purity.
Lactic Acid 80%, is an organic acid with applications in beer production as well as the cosmetic, pharmaceutical, food and chemical industries.


Lactic Acid 80% comes in both R (D-) and S (L+) enantiomers which can be manufactured individually to near perfect optical purity.
This means Lactic Acid 80% is great in the production of other products which require a specific stereochemistry.
Lactic Acid 80% is a liquid solution in water of about 80% purity.


Lactic Acid 80% is a strong Alpha-Hydroxy Acid and hence will have excellent exfoliant properties, although these are weaker than, but second only to, Glycolic Acid.
AHA products should be a stand alone treatment product and not included in another product.


While AHA can be included in other products there are certain incompatibilities that may arise plus AHAs (because of the pH required for best effectiveness) may not allow other products (such as cleansing masks) to work properly, and vice versa.
Lactic Acid 80% is also a widely used organic acidulate, probably because it is classified as a weak acid.


As with all manufacturing processes, we recommend lab scale trials in order to determine appropriate quantities.
Normally Lactic Acid 80% is titrated with a dilute solution of Lactic Acid (10 or 20% in water) until the desired pH is achieved.
Lactic Acid 80% is preferred as an acidulate as it tends to have less of a destabilizing effect on emulsions than Citric Acid.


Lactic Acid 80% is a non dairy version that is part of a family of acids called Alpha Hydroxy Acids (AHA’s).
Lactic Acid 80% is produced from natural corn starch by advanced bio-fermentation and refining technology.
Lactic Acid 80% is a yellowish to colorless liquid, with a mildly acidic odour and taste.


Lactic Acid 80% is a naturally occurring alpha hydroxy acids (or AHAs) produced by fermentation of sugars.
Lactic Acid 80% is the alpha hydroxy acid most frequently used for peel products.
Lactic Acid 80%, also known as milk acid, is an organic compound with the chemical formula C3H6O3.


In its liquid state Lactic Acid 80% is colourless.
Lactic Acid 80% is one of the alpha-hydroxy acids (AHA’s).
These acids occur naturally in fruits, sugar cane and milk.


Lactic Acid 80% increasing wort's acidity and improving both mashing and fermentation.
The exact dosage depends on the alkalinity of the water used, the salts added and the malts used in the recipe.
Lactic Acid 80% is recommended to carry out a pH measurement of the mash before adding the product.


If the pH is not within the range of 5.3 - 5.8, make gradual additions (0.10 - 0.15 mL/L) of Lactic Acid 80%, mix and measure again.
Lactic Acid 80%, from Jungbunzlauer, is an organic acid, occurring naturally in the human body and in fermented foods.
Lactic Acid 80% is a natural preservative and pH regulator.


Lactic Acid 80% is an organic acid with wide-reaching industrial applications.
Lactic Acid's 80% Food Grade specification makes it especially useful for food and beverage production, as well as pharmaceutical and cosmetic products.
Lactic Acid 80% is a versatile organic acid.


Lactic Acid 80% is an Alpha Hydroxy Acid (AHA) and can be used to promote higher rates of desquamation and cell renewal.
Lactic Acid 80% is also a moistening compound.
Lactic Acid 80% belongs to a group of alpha hydroxy acids (AHA) which show exfoliating, moistening and anti-aging properties.


In nature Lactic Acid 80% exists in sour milk, yoghurts, sour rye soups and silages.
Lactic Acid 80% appears in two optical forms L and D, out of which only L-lactic acid is biologically active and is a natural element of the skin and hair.
Lactic Acid 80% is one of the main part of NMF – natural moistening factor, which is responsible for proper hydration of the epidermis.


Lactic Acid 80% stabilizes process of epidermis exfoliation in a very delicate way.
Lactic Acid 80% is an alpha hydroxy acid with both exfoliant and humectant properties.
Lactic Acid 80% is produced naturally in the body (it's the stuff that gives you a ‘stitch’ during a workout) and is also found in yogurt and milk.


Lactic Acid 80% can help stimulate collagen and strengthen the skin, which equals fewer fine lines and wrinkles.
The hydroxy acids exfoliate the top layer of skin, helping smooth and even complexion, keep pores unclogged, brighten skin and even fade dark marks and discoloration.


Lactic Acid 80% is a versatile organic acid.
Lactic Acid 80% is soluble in water and in ethanol.
The inclusion of additional Lactic Acid 80% prior to rennetting overcomes this shortage and improves the curd yield.


Lactic Acid 80% is presented in a dropper bottles holding 4fl oz, to ensure an accurate dosing of milk and achieve consistent results when cheese making.
In production, Lactic Acid 80% is usually added up so that the pH of the milk is 5.0.
The casein in fermented milk is coagulated (curdled) by Lactic Acid 80% and it is also responsible for the sour flavor of sourdough breads.


Lactic Acid 80% is a colorless to yellow/brown liquid.
Store Lactic Acid 80% in a tightly closed container.
Store Lactic Acid 80% in a cool, dry, well-ventilated area away from incompatible substances.


Lactic Acid 80% can also be used for minor corrections in brewing PH can be used at higher levels for beer souring.
Lactic Acid 80% reduces the alkalinity levels of brewing liquor, stimulating maximum enzyme activity in the wort and enabling optimum pH levels throughout the whole brewing process.


Lactic Acid 80% improves extract yield and fermentation ability.
Lactic Acid 80% is suitable for beers where no other anions are needed, for example, lagers.
Lactic Acid 80% improves the clarity and stability of the finished product


Lactic Acid 80% is a ready-for-use acid used to reduce alkalinity in brewing liquor.
Lactic Acid 80% is Food Grade and made by fermentation of natural (beet or cane) sugar.
Lactic Acid 80% is a product of natural origin, obtained by fermentation of glucose.


Lactic Acid 80% is used in cosmetic compositions for pH adjustment and has good affinity for skin and hair.
Lactic Acid 80% improves skin hydration, removes dead cells and hair films (dandruff) having keratolytic action, hair shines.
Lactic Acid 80% is responsible for the tang that hits the mouth when eating dry aged beef.


Lactic Acid 80% is produced as natural L-Lactic acid by fermentation of carbohydrates like sugar or starch.
Lactic Acid 80%'s Chemical Formula is C3H6O3.
An organic acid, Lactic Acid 80%, is used to reduce alkalinity without adding sulphate and chloride ions.



USES and APPLICATIONS of LACTIC ACID 80%:
In many food products usually serves, Lactic Acid 80% is used as either as a pH regulator, as a preservative, or as a flavoring agent.
Lactic Acid 80% is used as an acidity regulator.
Lactic Acid 80% is effective in preventing the spoilage of vegetabels.


Lactic Acid 80% is used as an excellent acidification agent for many dairy products.
Lactic Acid 80% is used as an enhance savory flavors.
In pharmaceutical technology, Lactic Acid 80% is used as a starting material for other substances.


Lactic Acid 80% is used as a valuable component in biomaterials.
Lactic Acid 80% is used as a natural anti-bacterial agent in disinfecting products.
Lactic Acid 80% is used in the industrial processes.


Lactic Acid 80% is used as an additive in animal nutrition.
Lactic Acid 80% has health promoting properties.
Lactic Acid 80% is used as a humectant, or moisturizer, in some cosmetics.


Lactic Acid 80% ia used as a mordant, a chemical that helps fabrics accept dyes, in textiles.
Lactic Acid 80% is also used in tanning leather.
Lactic Acid 80% is used in the manufacturing of lacquers and inks.


Lactic Acid 80% is the principal building block for Poly Lactic Acid (PLA).
PLA is a biobased and bio-degradable polymer that can be used for producing renewable and compostable plastics.
Lactic Acid 80% is used to adjust the pH of the mash or the sparge water.


Lactic Acid 80% is used for Pilsner style lagers to reduce alkalinity.
Lactic Acid 80% used to reduce alkalinity without adding sulphate and chloride ions.
Lactic Acid 80% can also be used for minor corrections in brewing


PH can be used at higher levels for beer souring.
Lactic Acid 80% has a good moisturising effect on the skin and can be used in water based serums, gels, toners, creams and lotions.
Lactic Acid 80% can help the skin to look fresher and younger.


Lactic Acid 80% is especially beneficial in night creams and anti aging products.
When Lactic Acid 80% is used at higher concentrations, it can have an exfoliating effect.
Lactic Acid 80% will improve the skin's appearance and help to remove surface debris and dead skin cells.


Hair Care: Used in a hair pack, Lactic Acid 80% will cleanse a congested scalp for example, after a weave has been removed, having been on for several months.
Never use Lactic Acid 80% directly on the skin.


Best Lactic Acid 80% is added in stage 3 (cool down) when making creams and lotions.
Be aware that Lactic Acid 80% can make creams and lotions thinner or unstable so you need to start with a very strong and stable cream or lotion.
As a pH regulator, Lactic Acid 80% can be used to move the pH number lower (more acidic) for when using Preservative K which only functions correctly in a narrow pH range.


Often, Lactic Acid 80% is derived from milk, however, ours is made from maize or corn, and free from GMO.
Lactic Acid 80% is sold at an 80% concentration i.e. Lactic Acid 80% with 20% Water as an aqueous solution.
According to the Cosmetic Ingredient Database (CosIng), the functions of Lactic Acid 80% are: Buffering, Humectant, Skin Conditioning.


Skin Care: Depending on the strength of the dilution used, Lactic Acid 80% can be used as a pH regulator, a moisturiser or as a skin peel.
In the lower percentages, Lactic Acid 80% reduces Trans Epidermal Water Loss (TEWL) by supporting the skin's barrier function.
When applied, Lactic Acid 80% cleaves the bonds between keratinocytes on the external layer, thus reducing them and leading to gradual regeneration.


This results in a mild but effective exfoliation of the horny layer and in the simultaneous regeneration of cells.
Lactic Acid 80% stimulates the production of collagen and glycosaminoglycans that make up the intercellular material.
Another advantage provided by Lactic Acid 80% is that it naturally hydrates the skin; this action results in increased formation of ceramides, thus enhancing the function of the keratin barrier.


The combination of mild peeling, regeneration and hydration that Lactic Acid 80% offers, makes it an ideal peeling treatment for sensitive and dehydrated skin and a good choice for skin that will undergo chemical peeling for the first time.
The Lactic Acid 80% in combination with the pH result in targeted actions and indications.


Lactic Acid 80% is applied to adjust the pH of cosmetic products such as shampoo and shower gel or creams and lotions.
As Lactic Acid 80% is evident from the name, it reduces the pH of a product.
In addition to pH-regulation Lactic Acid 80% has excellent moisturizing effects.


An exception is the application in chemical peels.
Lactic Acid 80% is widely used in a range of food, industrial and manufacturing processes.
Lactic Acid 80% can be used for adjusting pH in the mash or sparge water.


Lactic Acid 80% may vary in colour from transparent to pale yellow.
Lactic Acid 80% is used a pH meter or test strips to control the pH.
Lactic Acid 80% may also be used in the final beer or wine for adding acidity.


Lactic Acid 80% is used to treat dry, rough & scaly skin.
Lactic Acid 80% may also be used for other conditions as determined by your doctor.
Normally Lactic Acid 80% is titrated with a dilute solution of Lactic Acid (10 or 20% in water) until the desired pH is achieved.


It is preferred as an acidulate as Lactic Acid 80% tends to have less of a destabilizing effect on emulsions than Citric Acid.
Lactic Acid 80% is used treating dry, rough & scaly skin.
Lactic Acid 80% may also be used for other conditions as determined by your doctor.


Lactic Acid 80% is one of the popular food additives and ingredients in most countries.
Commonly Lactic Acid 80% is used as a preservative and antioxidant.
Lactic Acid 80% also has uses as a fuel additive, chemical intermediate, acidity regulator, and disinfectant.


Lactic Acid 80% is also used in dialysis solutions, which results in a lower incidence of side effects compared to Sodium Acetate which can also be used.
Lactic Acid 80% is used frequently in the cosmetic industry due to the effect of promoting collagen production, helping to firm the skin against wrinkles and sagging.


Lactic Acid 80% can also cause micro peeling, which can help reduce various scars and age spots.
This is a great solution for people with sensitive or dry skin where exfoliants don’t work.
Lactic Acid 80% is used to treat dry, rough & scaly skin.


Lactic Acid 80% may also be used for other conditions as determined by your doctor.
Dilute Lactic Acid 80% before use.
As with all of the acids, Lactic Acid 80% is important to let your skin acclimate to their use.


For those whose skin is not used to the acids a slight stinging and redness may result.
If this occurs, Lactic Acid 80% reduce usage.
Lactic Acid 80% contains an alpha hydroxy acid (AHA) that may increase your skin's sensitivity to the sun and particularly the possibility of sunburn.


Lactic Acid 80% is used a sunscreen, wear protective clothing, and limit sun exposure while using this product and for a week afterwards.
Lactic Acid 80% reduces the alkalinity levels of brewing liquor stimulating maximum enzyme activity in the wort enabling optimum pH levels throughout the whole brewing process.


Lactic Acid 80% improves extract yield and fermentation ability
Lactic Acid 80% is suitable for beers where no other anions are needed for example lagers.
Lactic Acid 80% improves clarity and stability of the finished product.


Lactic acid in 80% concentration for chemical exfoliation, suitable for all skin types.
Lactic Acid 80% offers cellular regeneration, hydration and reduction of the appearance of wrinkles on the skin.
Typical use level of Lactic Acid 80% is between 1-20% in peels, creams, lotions, masks, cleansers.


Due to Lactic Acid 80%'s acidity the final product needs to be tested for safe pH.
Optimal pH range of Lactic Acid 80% is from 3.5-5.0.
Some over the counter products, after adding Lactic Acid 80%, will separate as a result of the low pH, and need to be stabilized.


Within the Personal Care sector, Lactic Acid 80% functions as an acidifier with moisturising, exfoliating and antibacterial properties.
When used topically, Lactic Acid 80% can assist with the removal of dead skin cells helping to renew the skin, improve skin texture and tone along with functioning as a humectant.


Lactic Acid 80% is often used as a milder alternative to glycolic acid in cosmetic formulations and can also be used to lower pH during manufacturing.
Lactic Acid 80% is produced by fermentation of glucose syrup from maize by using a bacterial strain.
Lactic Acid 80% is an acid and should never be used undiluted.


Lactic Acid 80% is classed as an advanced skincare ingredient and should not be used unless you understand the usage and applications of Lactic Acid.
Lactic Acid 80% is used acne Treatments & Skin Peels, Bee Keeping, In food production, To Extend shelf life of Meat,Fish & Poultry, Acidity regulator in drinks, In dairy products, Baking, Detergent, Animal Nutrition Supplement, and General Industry.


Lactic Acid 80% is widely used as an acidulent in the food industry, as well as for preservation and flavouring.
Lactic Acid 80% is used very useful to rejuvenate the skin by encouraging the shedding of old surface skin cells.
Lactic Acid 80% can reduce the appearance of fine lines, irregular pigmentation, age spots & decreases enlarged pores.


Lactic Acid 80% is often used in creams & lotions at a lower concentration for a more gentle acid-based peel.
Lactic Acid 80% is used in cosmetic to biolifting for it makes the skin elastic, evens wrinkles, brightens discolorations and narrows pores.
Lactic Acid 80% is also used in conditioners and shampoos because it activates hair bulbs, accelerating hair growth.


Lactic Acid 80% has moistening effect as a result of its properties to bind water in upper layers of the epidermis.
When used in proper concentrations (up to 5.0%), Lactic Acid 80% loosens intercellular cement.
Regular use of cosmetics with Lactic Acid 80% rejuvenates the epidermis and makes wrinkles even by means of a gradual exfoliation of dead cells of horny layer.


Faster exfoliation of cells results in the growth of new ones.
Preparations with Lactic Acid 80% support the treatment of acne.
When using masques with Lactic Acid 80% pointwise (7.0-15.0%) one can try removing sun, acne and aging maculae.


After using preparations with Lactic Acid 80% one should protect the skin against sun.
Without the layers of cornified cells, “young” epidermis absorbs nourishing cosmetics considerably better.
Therefore, tonics, scrubs and masques with Lactic Acid 80% belong to basic cosmetics for the care of oily, mixed, acne and mature complexions.


The cosmetics with Lactic Acid 80% should be used with the utmost care for dry complexion.
Lactic Acid 80% regulates cellular skin regeneration, and improves skin structure and colour.
Lactic Acid 80% enhances the effects of other cosmetic preparations.


Lactic Acid 80% improves skin moistening for the skin becomes more soft and elastic.
Lactic Acid 80% influences the production of skin collagen by increasing thickness and strengthening the dermis.
Lactic Acid 80% increases the level of glycosaminoglycans that is compounds that absorb water as a sponge and provide hydration of deeper layers of the skin.


Lactic Acid 80% makes small surface wrinkles even and improves skin elasticity as well as firmness; it is an anti-aging ingredient; it helps in case of discolorations and small acne scars.
Lactic Acid 80% makes pores clear and shows antibacterial properties, hence, it prevents the creation of trouble spots that are all kinds of eczemas and blackheads; it helps in the treatment of acne.


Lactic Acid 80% is also recommended for body and scalp-care for it helps in case of dry skin as well as skin exfoliation and cornification.
Lactic Acid 80% has been used in the production of beer for decades, contributing a unique tartness to this popular beverage.
With its 80% concentration of Lactic Acid 80%, this specially formulated solution allows you to easily control the level of tartness in your product.


Whether you’re using lactic acid to adjust the flavour of your beer or in other food production needs, Lactic Acid 80% is the perfect choice for creating a finished product that meets all quality standards while delighting consumers.
Lactic Acid 80% can be used to adjust the pH of many formulations and can be used as a milder alternative to glycolic acid.


Lactic Acid 80% and its salt, Sodium Lactate, can be used as humectants.
Lactic Acid 80% is used skincare pH adjustment, humectancy, skin brightening, desquamation, exfoliation.
Lactic Acid 80% is used haircare pH adjustment, humectancy.


Lactic Acid 80% is used soapmaking pH adjustment, increased firmness of bars and solid format products (especially if pre-neutralised with Lye).
Lactic Acid 80% is used Skincare pH adjustment, humectancy, skin brightening, desquamation, exfoliation.
Lactic Acid 80% is used Haircare pH adjustment, humectancy.


Lactic Acid 80% is used Soapmaking pH adjustment, increased firmness of bars and solid format products (especially if pre-neutralised with Lye).
Lactic Acid 80% is used to produce serial products or widely used in food, vintage, beverage, drugs, polymerization, textile, leather, tobacco, feed, plastic chemicals, pesticide, polymer solution and other industry.


Lactic Acid 80% is also used as an acidifying agent.
Lactic Acid 80% is food grade and is used for the production of several types of cheeses.
Lactic Acid 80% is particularly useful when UHT, ultra-pasturized or powdered milk are used as the starting materials, since the heat treatments used in the production of these milks deactivates the lactose and prevents the cheese culture from being able to turn it fully into Lactic Acid 80%.


Lactic Acid 80% is a vital ingredient in Ricotta Impastata, Mozzarella, Queso Blanco and other speciality cheeses and can be used in the production of sour milk products, such as Koumiss, Laban, Kefir, as well as some cottage cheeses.
Lactic Acid 80% is an Alpha Hydroxy Acid (AHA) and can be used to promote higher rates of desquamation and cell renewal.


Lactic Acid 80% can be used to adjust the pH of many formulations and can be used as a milder alternative to glycolic acid.
Lactic Acid 80% and its salt, Sodium Lactate, can be used as humectants.
Lactic Acid 80% is used in facial products and also body lotions and moisturisers, never directly on skin.


Lactic Acid 80% is easy to use in liquid form.
Lactic Acid 80% works well with hyaluronic acid and Vitamins A, B and C.
Lactic Acid 80% can also be used as a pH regulator: lactic acid will lower the pH.


Lactic Acid 80% has an anti-microbial effect and is the basis for preservation by fermentation in many food products.
Lactic Acid 80% serves as a preservative, pH regulator and flavouring agent.
Lactic Acid 80% is primarily found in sour milk products, such as: koumiss, leban, yogurt, kefir, and some cottage cheeses.


The casein in fermented milk is coagulated (curdled) by Lactic Acid 80%.
Lactic Acid 80% is produced natutally in the Lacto-fermentation of foods.
Some examples of these types of foods are Kimchi, Sauerkraut, sour beer, tsukemono, suan cai, atsara and yoghurt.


Lactic Acid 80% is used directly as the acidulant.
Pickled Vegetables uses of Lactic Acid 80%: Lactic Acid is effective in preventing the spoilage of olives, gherkins, pearl onions and other vegetables preserved in brine.


Confectionery products uses of Lactic Acid 80%: such as hard boiled candy, fruit gums with Lactic Acid 80% results in a mild acid taste, improved quality and longer shelf life.


-Beer brewing uses of Lactic Acid 80%:
Lactic Acid 80% is to lower the pH and add a bit of tartness.
Naturally add in small amounts or Lactic Acid 80% will become quite sour.


-Cheese making & Whipped Butter uses of Lactic Acid 80%:
Ricotta in particular and whipped butter in combination with GDL.
Ricotta Impastata, Mozzarella and Queso Blanco.


-Interesting non food uses for Lactic Acid 80%:
Lactic Acid 80% is the principal building block for Poly Lactic Acid (PLA) biodegradable plastics.
PLA is a biobased and bio-degradable polymer that can be used for producing renewable and compostable plastics.
Lactic Acid 80% is also being used in the cosmetics industry for acne treatment.



USE IN FOOD, LACTIC ACID 80%:
Lactic Acid 80% is a natural preservative found in several foods, including pickled vegetables, yoghurt, and baked goods.
Lactic Acid 80% is a cheap and minimally processed
Lactobacillus and Streptococcus cultures produce Lactic Acid 80% through fermentation.
The bacteria break down sugar to extract energy and produce Lactic Acid 80% as a byproduct.
Lactic Acid 80% helps regulate pH levels and prevents the growth of microorganisms, extending shelf life.



THE PROPERTIES OF LACTIC ACID 80%:
The properties of Lactic Acid 80%
- Keratolytic exfoliates the skin by removing dead skin and scalp cells
- Stimulates collagen and elastin synthesis, promoting cell renewal
- Lactic Acid 80% improves skin grain and appearance pH
- Activates the emulsifier conditioner used in the manufacture of hair care compositions



HOW TO USE LACTIC ACID 80% IN COSMETICS:
- Lactic Acid 80% is a product that does not apply to pure skin
- Lactic Acid 80% can be included as an ingredient in cosmetic compositions containing acidulant and water: serums, gels, tonics, masks, lotions, creams, shampoos, cleanses, etc.



BENEFITS OF LACTIC ACID 80%:
*Brightens a dull complexion
*Humectant and skin firmer
*Exfoliant
*Improves skin tone and texture
*Vegan Friendly
*GMO-free



BENEFITS AND APPLICATIONS OF LACTIC ACID 80%:
Lactic Acid 80% is used to treat hyperpigmentation, age spots, and other conditions that contribute to a dull, uneven complexion.
Lactic Acid 80% also enhances skin tone and minimises the appearance of pores.

Lactic Acid 80% promotes cell turnover and cell renewal, which are the processes through which your skin loses old cells and replaces them with new ones.
Lactic Acid 80% works really well for sensitive skin because of its milder nature as compared to other alpha-hydroxy acids.

Lactic Acid 80% is also a key component of over-the-counter lotions and creams for "chicken skin," i.e., pimples on the backs of the arms.
Lactic Acid 80% aids in the dissolution of the clog of skin cells that form around the hair follicle, smoothing out the bumpiness.
Lactic Acid 80% is commonly found in topical therapies for eczema, psoriasis, and rosacea.



HOW LACTIC ACID 80% WORKS:
Lactic Acid 80% works by removing the upper layer of skin cells, which is usually composed of dead skin cells.
Lactic Acid 80% also works by increasing the natural moisture retention capabilities of the skin to give your skin a hydrated look.



CONCENTRATION AND SOLUBILITY OF LACTIC ACID 80%:
Lactic Acid 80% is recommended that it should be used at a concentration of 1–5%.
Lactic Acid 80% is soluble in water, alcohol, and glycerol but is insoluble in oil.



HOW TO USE LACTIC ACID 80%:
Prepare the oil and water phases of your formulation separately.
Heat the oil and water phases using a double boiler.
Add Lactic Acid 80% to the water phase, accompanied by constant stirring.
Blend both the phases together using a mini-mixer or a large mixing brush.



FUNCTION OF LACTIC ACID 80%:
In food, apart from its nutritional function for normal growth, Lactic Acid 80% improves flavor and taste, improves quality of food and beverage products such as confectionery, cake, milk powder, yogurt etc. as firming agent, buffering agent and flour regulator.
Lactic Acid 80% increases effectiveness of antioxidants, prevents decolorization of fruits and vegetables.



BENEFITS OF LACTIC ACID 80%:
Lactic Acid 80% reduces the alkalinity levels of brewing liquor, stimulating maximum enzyme activity in the wort enabling optimum pH levels throughout the whole brewing process.
Lactic Acid 80% improves extract yield and fermentability.
Lactic Acid 80% is suitable for beers where no other anions are needed, for example, pilsner lagers.
Lactic Acid 80% can also be used to reduce the pH of final wort or products.



SUGGESTED BLENDS OF LACTIC ACID 80%:
Lactic Acid 80% works well in conjunction with Vitamin A, B and C.
Be sure to check the final pH level is not less than 3.5 when combining several acidic ingredients together.



PHYSICAL and CHEMICAL PROPERTIES of LACTIC ACID 80%:
CAS: 50-21-5
MF: C3H6O3
MW: 90.08
EINECS: 200-018-0
Mol File: 50-21-5.mol
Lactic acid Chemical Properties
Melting point: 18°C
alpha: -0.05 º (c= neat 25 ºC)
Boiling point: 122 °C/15 mmHg (lit.)
density: 1.209 g/mL at 25 °C (lit.)
vapor density: 0.62 (vs air)
vapor pressure: 19 mm of Hg (@ 20°C)
FEMA: 2611 | LACTIC ACID
refractive index: n20/D 1.4262

Fp: >230 °F
storage temp.: 2-8°C
solubility: Miscible with water and with ethanol (96 per cent).
form: syrup
pka: 3.08(at 100℃)
Specific Gravity: 1.209
color: Colorless to yellow
Water Solubility: SOLUBLE
Merck: 145,336
JECFA Number: 930
BRN: 1209341
Stability: Stable.
Physical state: viscous
Color: colorless

Odor: odorless
Melting point/freezing point:
Melting point: 18 °C at 1.013 hPa
Initial boiling point and boiling range: 122 °C at 18,66 - 19,99 hPa
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits: No data available
Flash point: 113 °C - closed cup
Autoignition temperature: 400 °C at 1.011,4 - 1.018,9 hPa
Decomposition temperature: No data available
pH: No data available
Viscosity
Viscosity, kinematic: No data available
Viscosity, dynamic: No data available
Water solubility: 100 g/l at 20 °C - soluble

Partition coefficient: n-octanol/water:
log Pow: ca.-0,54 at 25 °C - Bioaccumulation is not expected.
Vapor pressure: No data available
Density: 1,25 g/cm3 at 15 °C
Relative density: No data available
Relative vapor density: No data available
Particle characteristics: No data available
Explosive properties: No data available
Oxidizing properties: none
Other safety information:
Surface tension 70,7 mN/m at 1g/l at 20 °C
Formula: H₃CCH(OH)COOH
MW: 90.08 g/mol
Boiling Pt: 122 °C (20 hPa)
Density: 1.11…1.21 g/cm³ (20 °C)
Storage Temperature: Ambient
MDL Number: MFCD00004520
CAS Number: 50-21-5
EINECS: 200-018-0



FIRST AID MEASURES of LACTIC ACID 80%:
-Description of first-aid measures:
*General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LACTIC ACID 80%:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up with liquid-absorbent material.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of LACTIC ACID 80%:
-Extinguishing media:
*Suitable extinguishing media:
Water
Foam
Carbon dioxide (CO2)
Dry powder
*Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LACTIC ACID 80%:
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles
*Body Protection:
protective clothing
*Respiratory protection
Recommended Filter type: Filter type ABEK
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LACTIC ACID 80%:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.



STABILITY and REACTIVITY of LACTIC ACID 80%:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Possibility of hazardous reactions:
No data available.
-Incompatible materials:
No data available



SYNONYMS:
α-hydroxypropionic acid, 2-hydroxypropanoic acid
2-Hydroxypropionic acid , 2-Hydroxypropanoic acid
DL-Lactic acid
DL-Lactic acid
2-Hydroxypropionic acid
Acidum lacticum
Lactic Acid 80% Pdr w/silca
Lactic Acid 80%
Unilac LA80
Tisulac
Espiritin
HiPure 90
l-lacticaci
Lactic L-Milchsàure



LACTIC ACID 80% (E270)
Lactic Acid 80% (E270)'s Chemical Formula is C3H6O3.
Lactic Acid 80% (E270) is produced as natural L-Lactic acid by fermentation of carbohydrates like sugar or starch.


CAS Number: 50-21-5
EC Number: 200-018-0
Molecular Formula: C3H6O3



α-hydroxypropionic acid, 2-Hydroxypropanoic acid, DL-Lactic acid, DL-Lactic acid, 2-Hydroxypropionic acid, Acidum lacticum, Lactic Acid 80% Pdr w/silca, Lactic Acid 80%, Unilac LA80, Tisulac, Espiritin, HiPure 90, l-lacticaci Lactic L-Milchsàure, α-Hydroxypropanoic acid, lactic acid, 2-hydroxypropanoic acid, DL-Lactic acid, 50-21-5, 2-hydroxypropionic acid,



Lactic Acid 80% (E270) is a colorless to yellow/brown liquid.
Store Lactic Acid 80% (E270) in a tightly closed container.
Store Lactic Acid 80% (E270) in a cool, dry, well-ventilated area away from incompatible substances.


Lactic Acid 80% (E270) can also be used for minor corrections in brewing PH can be used at higher levels for beer souring.
Lactic Acid 80% (E270) reduces the alkalinity levels of brewing liquor, stimulating maximum enzyme activity in the wort and enabling optimum pH levels throughout the whole brewing process.


Lactic Acid 80% (E270) improves extract yield and fermentation ability.
Lactic Acid 80% (E270) is suitable for beers where no other anions are needed, for example, lagers.
Lactic Acid 80% (E270) improves the clarity and stability of the finished product


Lactic Acid 80% (E270) is a ready-for-use acid used to reduce alkalinity in brewing liquor.
Lactic Acid 80% (E270) is Food Grade and made by fermentation of natural (beet or cane) sugar.
Lactic Acid 80% (E270) is a product of natural origin, obtained by fermentation of glucose.


Lactic Acid 80% (E270) is used in cosmetic compositions for pH adjustment and has good affinity for skin and hair.
Lactic Acid 80% (E270) improves skin hydration, removes dead cells and hair films (dandruff) having keratolytic action, hair shines.
Lactic Acid 80% (E270) is responsible for the tang that hits the mouth when eating dry aged beef.


Lactic Acid 80% (E270) is produced as natural L-Lactic acid by fermentation of carbohydrates like sugar or starch.
Lactic Acid 80% (E270)'s Chemical Formula is C3H6O3.
An organic acid, Lactic Acid 80% (E270), is used to reduce alkalinity without adding sulphate and chloride ions.


Lactic Acid 80% (E270) can help stimulate collagen and strengthen the skin, which equals fewer fine lines and wrinkles.
The hydroxy acids exfoliate the top layer of skin, helping smooth and even complexion, keep pores unclogged, brighten skin and even fade dark marks and discoloration.


Lactic Acid 80% (E270) is a versatile organic acid.
Lactic Acid 80% (E270) is soluble in water and in ethanol.
The inclusion of additional Lactic Acid 80% (E270) prior to rennetting overcomes this shortage and improves the curd yield.


Lactic Acid 80% (E270) is presented in a dropper bottles holding 4fl oz, to ensure an accurate dosing of milk and achieve consistent results when cheese making.
In production, Lactic Acid 80% (E270) is usually added up so that the pH of the milk is 5.0.
The casein in fermented milk is coagulated (curdled) by Lactic Acid 80% (E270) and it is also responsible for the sour flavor of sourdough breads.


If the pH is not within the range of 5.3 - 5.8, make gradual additions (0.10 - 0.15 mL/L) of Lactic Acid 80% (E270), mix and measure again.
Lactic Acid 80% (E270), from Jungbunzlauer, is an organic acid, occurring naturally in the human body and in fermented foods.
Lactic Acid 80% (E270) is a natural preservative and pH regulator.


Lactic Acid 80% (E270) is an organic acid with wide-reaching industrial applications.
Lactic Acid's 80% Food Grade specification makes it especially useful for food and beverage production, as well as pharmaceutical and cosmetic products.
Lactic Acid 80% (E270) is a versatile organic acid.


In its liquid state Lactic Acid 80% (E270) is colourless.
Lactic Acid 80% (E270) is one of the alpha-hydroxy acids (AHA’s).
These acids occur naturally in fruits, sugar cane and milk.


Lactic Acid 80% (E270) increasing wort's acidity and improving both mashing and fermentation.
The exact dosage depends on the alkalinity of the water used, the salts added and the malts used in the recipe.
Lactic Acid 80% (E270) is recommended to carry out a pH measurement of the mash before adding the product.


Lactic Acid 80% (E270) is a non dairy version that is part of a family of acids called Alpha Hydroxy Acids (AHA’s).
Lactic Acid 80% (E270) is produced from natural corn starch by advanced bio-fermentation and refining technology.
Lactic Acid 80% (E270) is a yellowish to colorless liquid, with a mildly acidic odour and taste.


Lactic Acid 80% (E270) is a naturally occurring alpha hydroxy acids (or AHAs) produced by fermentation of sugars.
Lactic Acid 80% (E270) is the alpha hydroxy acid most frequently used for peel products.
Lactic Acid 80% (E270), also known as milk acid, is an organic compound with the chemical formula C3H6O3.


Lactic Acid 80% (E270) is a strong Alpha-Hydroxy Acid and hence will have excellent exfoliant properties, although these are weaker than, but second only to, Glycolic Acid.
AHA products should be a stand alone treatment product and not included in another product.


While AHA can be included in other products there are certain incompatibilities that may arise plus AHAs (because of the pH required for best effectiveness) may not allow other products (such as cleansing masks) to work properly, and vice versa.
Lactic Acid 80% (E270) is also a widely used organic acidulate, probably because it is classified as a weak acid.


While AHA can be included in other products there are certain incompatibilities that may arise plus AHAs (because of the pH required for best effectiveness) may not allow other products (such as cleansing masks) to work properly, and vice versa.
Lactic Acid 80% (E270) is also a widely used organic acidulate, probably because it is classified as a weak acid.


As with all manufacturing processes, we recommend lab scale trials in order to determine appropriate quantities.
Lactic Acid 80% (E270) is a liquid solution in water of about 80% purity.
Lactic Acid 80% (E270), is an organic acid with applications in beer production as well as the cosmetic, pharmaceutical, food and chemical industries.


Lactic Acid 80% (E270) is an anti-wrinkle and anti-pigmentation component available in both over-the-counter and professional-grade skincare products.
Lactic Acid 80% (E270) is derived from milk and belongs to the alpha-hydroxy acid (AHAs) class of anti-ageing compounds.
Glycolic acid and citric acid are two further examples of AHAs.


Lactic Acid 80% (E270) is a liquid solution in water of about 80% purity.
Lactic Acid 80% (E270) is an AHA.
Lactic Acid 80% (E270) is sufficient to add a few drops to 100 ml shampoo to adjust the pH.


Even as a moisturizing additive Lactic Acid 80% (E270) should not be applied more than 0,5%.
Dilute Lactic Acid 80% (E270) before use.
As with all of the acids, Lactic Acid 80% (E270) is important to let your skin acclimate to their use.


Lactic Acid 80% (E270), also known as milk acid, is a chemical compound that plays a role in several biochemical processes.
Lactic Acid 80% (E270) is an alpha hydroxy acid that comes from milk.
As a result of its relatively greater molecular weight, Lactic Acid 80% (E270)'s keratolytic action is milder than that of glycolic acid, thus preventing skin irritations.


Lactic Acid 80% (E270) is an alpha hydroxy acid that comes from milk.
As a result of its relatively greater molecular weight, Lactic Acid 80% (E270)'s keratolytic action is milder than that of glycolic acid, thus preventing skin irritations.


Lactic Acid 80% (E270) is a strong Alpha-Hydroxy Acid and hence will have excellent exfoliant properties, although these are weaker than, but second only to, Glycolic Acid.
AHA products should be a stand alone treatment product and not included in another product.


Lactic Acid 80% (E270) comes in both R (D-) and S (L+) enantiomers which can be manufactured individually to near perfect optical purity.
This means Lactic Acid 80% (E270) is great in the production of other products which require a specific stereochemistry.
Lactic Acid 80% (E270) is a liquid solution in water of about 80% purity.


As with all manufacturing processes, we recommend lab scale trials in order to determine appropriate quantities.
Normally Lactic Acid 80% (E270) is titrated with a dilute solution of Lactic Acid (10 or 20% in water) until the desired pH is achieved.
Lactic Acid 80% (E270) is preferred as an acidulate as it tends to have less of a destabilizing effect on emulsions than Citric Acid.


Lactic Acid 80% (E270) is an Alpha Hydroxy Acid (AHA) and can be used to promote higher rates of desquamation and cell renewal.
Lactic Acid 80% (E270) is also a moistening compound.
Lactic Acid 80% (E270) belongs to a group of alpha hydroxy acids (AHA) which show exfoliating, moistening and anti-aging properties.


In nature Lactic Acid 80% (E270) exists in sour milk, yoghurts, sour rye soups and silages.
Lactic Acid 80% (E270) appears in two optical forms L and D, out of which only L-lactic acid is biologically active and is a natural element of the skin and hair.
Lactic Acid 80% (E270) is one of the main part of NMF – natural moistening factor, which is responsible for proper hydration of the epidermis.


Lactic Acid 80% (E270) stabilizes process of epidermis exfoliation in a very delicate way.
Lactic Acid 80% (E270) is an alpha hydroxy acid with both exfoliant and humectant properties.
Lactic Acid 80% (E270) is produced naturally in the body (it's the stuff that gives you a ‘stitch’ during a workout) and is also found in yogurt and milk.


Lactic Acid 80% (E270) dissolves very well in water.
Lactic Acid 80% (E270) is natural.
Lactic Acid 80% (E270) is approved as food additive E 270.


Lactic Acid 80% (E270) is used organic acid for industrial purposes.
Lactic Acid 80% (E270) is a hydroxycarboxylic acid, so it contains both a carboxyl group and a hydroxyl group.
Lactic Acid 80% (E270) is therefore also referred to as 2-hydroxypropionic acid, but according to IUPAC nomenclature recommendations, the name 2-hydroxypropionic acid should be used.


The salts and esters of Lactic Acid 80% (E270) are called lactates.
A concentrated solution of Lactic Acid 80% (E270) is typically a mixture of lactic acid lactate and lactic acid.
Lactic Acid 80% (E270) appears as a colorless to yellow odorless syrupy liquid.


Lactic Acid 80% (E270) is produced from natural cornstarch by advanced bio-fermentation and refining technology.
Lactic Acid 80% (E270) is a yellowish to colorless liquid, having a mild acid odor and taste.
Lactic acid appears as a colorless to yellow odorless syrupy liquid.



USES and APPLICATIONS of LACTIC ACID 80% (E270):
The casein in fermented milk is coagulated (curdled) by Lactic Acid 80% (E270).
Lactic Acid 80% (E270) is produced natutally in the Lacto-fermentation of foods.
Some examples of these types of foods are Kimchi, Sauerkraut, sour beer, tsukemono, suan cai, atsara and yoghurt.


Lactic Acid 80% (E270) is used directly as the acidulant.
Pickled Vegetables uses of Lactic Acid 80% (E270): Lactic Acid is effective in preventing the spoilage of olives, gherkins, pearl onions and other vegetables preserved in brine.


Lactic Acid 80% (E270) is a vital ingredient in Ricotta Impastata, Mozzarella, Queso Blanco and other speciality cheeses and can be used in the production of sour milk products, such as Koumiss, Laban, Kefir, as well as some cottage cheeses.
Lactic Acid 80% (E270) is an Alpha Hydroxy Acid (AHA) and can be used to promote higher rates of desquamation and cell renewal.


Lactic Acid 80% (E270) can be used to adjust the pH of many formulations and can be used as a milder alternative to glycolic acid.
Lactic Acid 80% (E270) and its salt, Sodium Lactate, can be used as humectants.
Lactic Acid 80% (E270) is used in facial products and also body lotions and moisturisers, never directly on skin.


Lactic Acid 80% (E270) is also used as an acidifying agent.
Lactic Acid 80% (E270) is food grade and is used for the production of several types of cheeses.
Lactic Acid 80% (E270) is particularly useful when UHT, ultra-pasturized or powdered milk are used as the starting materials, since the heat treatments used in the production of these milks deactivates the lactose and prevents the cheese culture from being able to turn it fully into Lactic Acid 80% (E270).


Lactic Acid 80% (E270) is easy to use in liquid form.
Lactic Acid 80% (E270) works well with hyaluronic acid and Vitamins A, B and C.
Lactic Acid 80% (E270) can also be used as a pH regulator: lactic acid will lower the pH.


Lactic Acid 80% (E270) is used Soapmaking pH adjustment, increased firmness of bars and solid format products (especially if pre-neutralised with Lye).
Lactic Acid 80% (E270) is used to produce serial products or widely used in food, vintage, beverage, drugs, polymerization, textile, leather, tobacco, feed, plastic chemicals, pesticide, polymer solution and other industry.


Lactic Acid 80% (E270) is also recommended for body and scalp-care for it helps in case of dry skin as well as skin exfoliation and cornification.
Lactic Acid 80% (E270) has been used in the production of beer for decades, contributing a unique tartness to this popular beverage.
With its 80% concentration of Lactic Acid 80% (E270), this specially formulated solution allows you to easily control the level of tartness in your product.


Whether you’re using lactic acid to adjust the flavour of your beer or in other food production needs, Lactic Acid 80% (E270) is the perfect choice for creating a finished product that meets all quality standards while delighting consumers.
Lactic Acid 80% (E270) can be used to adjust the pH of many formulations and can be used as a milder alternative to glycolic acid.


Lactic Acid 80% (E270) and its salt, Sodium Lactate, can be used as humectants.
Lactic Acid 80% (E270) is used skincare pH adjustment, humectancy, skin brightening, desquamation, exfoliation.
Lactic Acid 80% (E270) is used haircare pH adjustment, humectancy.


Lactic Acid 80% (E270) has an anti-microbial effect and is the basis for preservation by fermentation in many food products.
Lactic Acid 80% (E270) serves as a preservative, pH regulator and flavouring agent.
Lactic Acid 80% (E270) is primarily found in sour milk products, such as: koumiss, leban, yogurt, kefir, and some cottage cheeses.


Faster exfoliation of cells results in the growth of new ones.
Preparations with Lactic Acid 80% (E270) support the treatment of acne.
When using masques with Lactic Acid 80% (E270) pointwise (7.0-15.0%) one can try removing sun, acne and aging maculae.


After using preparations with Lactic Acid 80% (E270) one should protect the skin against sun.
Without the layers of cornified cells, “young” epidermis absorbs nourishing cosmetics considerably better.
Therefore, tonics, scrubs and masques with Lactic Acid 80% (E270) belong to basic cosmetics for the care of oily, mixed, acne and mature complexions.


The cosmetics with Lactic Acid 80% (E270) should be used with the utmost care for dry complexion.
Lactic Acid 80% (E270) regulates cellular skin regeneration, and improves skin structure and colour.
Lactic Acid 80% (E270) enhances the effects of other cosmetic preparations.


Lactic Acid 80% (E270) improves skin moistening for the skin becomes more soft and elastic.
Lactic Acid 80% (E270) influences the production of skin collagen by increasing thickness and strengthening the dermis.
Lactic Acid 80% (E270) increases the level of glycosaminoglycans that is compounds that absorb water as a sponge and provide hydration of deeper layers of the skin.


Lactic Acid 80% (E270) is classed as an advanced skincare ingredient and should not be used unless you understand the usage and applications of Lactic Acid.
Lactic Acid 80% (E270) is used acne Treatments & Skin Peels, Bee Keeping, In food production, To Extend shelf life of Meat,Fish & Poultry, Acidity regulator in drinks, In dairy products, Baking, Detergent, Animal Nutrition Supplement, and General Industry.


Lactic Acid 80% (E270) is widely used as an acidulent in the food industry, as well as for preservation and flavouring.
Lactic Acid 80% (E270) is used very useful to rejuvenate the skin by encouraging the shedding of old surface skin cells.
Lactic Acid 80% (E270) can reduce the appearance of fine lines, irregular pigmentation, age spots & decreases enlarged pores.


Lactic Acid 80% (E270) is often used in creams & lotions at a lower concentration for a more gentle acid-based peel.
Lactic Acid 80% (E270) is used in cosmetic to biolifting for it makes the skin elastic, evens wrinkles, brightens discolorations and narrows pores.
Lactic Acid 80% (E270) is also used in conditioners and shampoos because it activates hair bulbs, accelerating hair growth.


The combination of mild peeling, regeneration and hydration that Lactic Acid 80% (E270) offers, makes it an ideal peeling treatment for sensitive and dehydrated skin and a good choice for skin that will undergo chemical peeling for the first time.
The Lactic Acid 80% (E270) in combination with the pH result in targeted actions and indications.


Lactic Acid 80% (E270) is applied to adjust the pH of cosmetic products such as shampoo and shower gel or creams and lotions.
As Lactic Acid 80% (E270) is evident from the name, it reduces the pH of a product.
In addition to pH-regulation Lactic Acid 80% (E270) has excellent moisturizing effects.


An exception is the application in chemical peels.
Lactic Acid 80% (E270) is widely used in a range of food, industrial and manufacturing processes.
Lactic Acid 80% (E270) can be used for adjusting pH in the mash or sparge water.


Lactic Acid 80% (E270) may vary in colour from transparent to pale yellow.
Lactic Acid 80% (E270) is used a pH meter or test strips to control the pH.
Lactic Acid 80% (E270) may also be used in the final beer or wine for adding acidity.


Lactic Acid 80% (E270) is used to treat dry, rough & scaly skin.
Lactic Acid 80% (E270) may also be used for other conditions as determined by your doctor.
Normally Lactic Acid 80% (E270) is titrated with a dilute solution of Lactic Acid (10 or 20% in water) until the desired pH is achieved.


It is preferred as an acidulate as Lactic Acid 80% (E270) tends to have less of a destabilizing effect on emulsions than Citric Acid.
Lactic Acid 80% (E270) is used treating dry, rough & scaly skin.
Lactic Acid 80% (E270) may also be used for other conditions as determined by your doctor.


Lactic Acid 80% (E270) is one of the popular food additives and ingredients in most countries.
Commonly Lactic Acid 80% (E270) is used as a preservative and antioxidant.
Lactic Acid 80% (E270) also has uses as a fuel additive, chemical intermediate, acidity regulator, and disinfectant.


Lactic Acid 80% (E270) is also used in dialysis solutions, which results in a lower incidence of side effects compared to Sodium Acetate which can also be used.
Lactic Acid 80% (E270) is used frequently in the cosmetic industry due to the effect of promoting collagen production, helping to firm the skin against wrinkles and sagging.


Lactic Acid 80% (E270) is used as an additive in animal nutrition.
Lactic Acid 80% (E270) has health promoting properties.
Lactic Acid 80% (E270) is used as a humectant, or moisturizer, in some cosmetics.


Lactic Acid 80% (E270) ia used as a mordant, a chemical that helps fabrics accept dyes, in textiles.
Lactic Acid 80% (E270) is also used in tanning leather.
Lactic Acid 80% (E270) is used in the manufacturing of lacquers and inks.


Lactic Acid 80% (E270) is the principal building block for Poly Lactic Acid (PLA).
PLA is a biobased and bio-degradable polymer that can be used for producing renewable and compostable plastics.
Lactic Acid 80% (E270) is used to adjust the pH of the mash or the sparge water.


Lactic Acid 80% (E270) is used for Pilsner style lagers to reduce alkalinity.
Lactic Acid 80% (E270) used to reduce alkalinity without adding sulphate and chloride ions.
Lactic Acid 80% (E270) can also be used for minor corrections in brewing


Lactic Acid 80% (E270) can also cause micro peeling, which can help reduce various scars and age spots.
This is a great solution for people with sensitive or dry skin where exfoliants don’t work.
Lactic Acid 80% (E270) is used to treat dry, rough & scaly skin.


Lactic Acid 80% (E270) may also be used for other conditions as determined by your doctor.
Dilute Lactic Acid 80% (E270) before use.
As with all of the acids, Lactic Acid 80% (E270) is important to let your skin acclimate to their use.


For those whose skin is not used to the acids a slight stinging and redness may result.
If this occurs, Lactic Acid 80% (E270) reduce usage.
Lactic Acid 80% (E270) contains an alpha hydroxy acid (AHA) that may increase your skin's sensitivity to the sun and particularly the possibility of sunburn.


Lactic Acid 80% (E270) is used a sunscreen, wear protective clothing, and limit sun exposure while using this product and for a week afterwards.
Lactic Acid 80% (E270) reduces the alkalinity levels of brewing liquor stimulating maximum enzyme activity in the wort enabling optimum pH levels throughout the whole brewing process.


Lactic Acid 80% (E270) improves extract yield and fermentation ability
Lactic Acid 80% (E270) is suitable for beers where no other anions are needed for example lagers.
Lactic Acid 80% (E270) improves clarity and stability of the finished product.


Lactic acid in 80% concentration for chemical exfoliation, suitable for all skin types.
Lactic Acid 80% (E270) offers cellular regeneration, hydration and reduction of the appearance of wrinkles on the skin.
Typical use level of Lactic Acid 80% (E270) is between 1-20% in peels, creams, lotions, masks, cleansers.


Due to Lactic Acid 80% (E270)'s acidity the final product needs to be tested for safe pH.
Optimal pH range of Lactic Acid 80% (E270) is from 3.5-5.0.
Some over the counter products, after adding Lactic Acid 80% (E270), will separate as a result of the low pH, and need to be stabilized.


In many food products usually serves, Lactic Acid 80% (E270) is used as either as a pH regulator, as a preservative, or as a flavoring agent.
Lactic Acid 80% (E270) is used as an acidity regulator.
Lactic Acid 80% (E270) is effective in preventing the spoilage of vegetabels.


Lactic Acid 80% (E270) is used as an excellent acidification agent for many dairy products.
Lactic Acid 80% (E270) is used as an enhance savory flavors.
In pharmaceutical technology, Lactic Acid 80% (E270) is used as a starting material for other substances.


Lactic Acid 80% (E270) is used as a valuable component in biomaterials.
Lactic Acid 80% (E270) is used as a natural anti-bacterial agent in disinfecting products.
Lactic Acid 80% (E270) is used in the industrial processes.


PH can be used at higher levels for beer souring.
Lactic Acid 80% (E270) has a good moisturising effect on the skin and can be used in water based serums, gels, toners, creams and lotions.
Lactic Acid 80% (E270) can help the skin to look fresher and younger.


Lactic Acid 80% (E270) is especially beneficial in night creams and anti aging products.
When Lactic Acid 80% (E270) is used at higher concentrations, it can have an exfoliating effect.
Lactic Acid 80% (E270) will improve the skin's appearance and help to remove surface debris and dead skin cells.


Hair Care: Used in a hair pack, Lactic Acid 80% (E270) will cleanse a congested scalp for example, after a weave has been removed, having been on for several months.
Never use Lactic Acid 80% (E270) directly on the skin.


Best Lactic Acid 80% (E270) is added in stage 3 (cool down) when making creams and lotions.
Be aware that Lactic Acid 80% (E270) can make creams and lotions thinner or unstable so you need to start with a very strong and stable cream or lotion.
As a pH regulator, Lactic Acid 80% (E270) can be used to move the pH number lower (more acidic) for when using Preservative K which only functions correctly in a narrow pH range.


Often, Lactic Acid 80% (E270) is derived from milk, however, ours is made from maize or corn, and free from GMO.
Lactic Acid 80% (E270) is sold at an 80% concentration i.e. Lactic Acid 80% (E270) with 20% Water as an aqueous solution.
According to the Cosmetic Ingredient Database (CosIng), the functions of Lactic Acid 80% (E270) are: Buffering, Humectant, Skin Conditioning.


Lactic Acid 80% (E270) is often used as a milder alternative to glycolic acid in cosmetic formulations and can also be used to lower pH during manufacturing.
Lactic Acid 80% (E270) is produced by fermentation of glucose syrup from maize by using a bacterial strain.
Lactic Acid 80% (E270) is an acid and should never be used undiluted.


When used in proper concentrations (up to 5.0%), Lactic Acid 80% (E270) loosens intercellular cement.
Regular use of cosmetics with Lactic Acid 80% (E270) rejuvenates the epidermis and makes wrinkles even by means of a gradual exfoliation of dead cells of horny layer.


Lactic Acid 80% (E270) makes small surface wrinkles even and improves skin elasticity as well as firmness; it is an anti-aging ingredient; it helps in case of discolorations and small acne scars.
Lactic Acid 80% (E270) makes pores clear and shows antibacterial properties, hence, it prevents the creation of trouble spots that are all kinds of eczemas and blackheads; it helps in the treatment of acne.


Lactic Acid 80% (E270) is used soapmaking pH adjustment, increased firmness of bars and solid format products (especially if pre-neutralised with Lye).
Lactic Acid 80% (E270) is used Skincare pH adjustment, humectancy, skin brightening, desquamation, exfoliation.
Lactic Acid 80% (E270) is used Haircare pH adjustment, humectancy.


Skin Care: Depending on the strength of the dilution used, Lactic Acid 80% (E270) can be used as a pH regulator, a moisturiser or as a skin peel.
In the lower percentages, Lactic Acid 80% (E270) reduces Trans Epidermal Water Loss (TEWL) by supporting the skin's barrier function.
When applied, Lactic Acid 80% (E270) cleaves the bonds between keratinocytes on the external layer, thus reducing them and leading to gradual regeneration.


This results in a mild but effective exfoliation of the horny layer and in the simultaneous regeneration of cells.
Lactic Acid 80% (E270) stimulates the production of collagen and glycosaminoglycans that make up the intercellular material.
Another advantage provided by Lactic Acid 80% (E270) is that it naturally hydrates the skin; this action results in increased formation of ceramides, thus enhancing the function of the keratin barrier.


Within the Personal Care sector, Lactic Acid 80% (E270) functions as an acidifier with moisturising, exfoliating and antibacterial properties.
When used topically, Lactic Acid 80% (E270) can assist with the removal of dead skin cells helping to renew the skin, improve skin texture and tone along with functioning as a humectant.


Confectionery products uses of Lactic Acid 80% (E270): such as hard boiled candy, fruit gums with Lactic Acid 80% (E270) results in a mild acid taste, improved quality and longer shelf life.
Lactic Acid 80% (E270) has moistening effect as a result of its properties to bind water in upper layers of the epidermis.


Lactic Acid 80% (E270) is used to make cultured dairy products, as a food preservative, and to make chemicals.
Lactic Acid 80% (E270) is used as a solvent and acidulant in the production of foods, drugs, and dyes.
Lactic Acid 80% (E270) is also used as a mordant in woolen goods printing, a soldering flux, a dehairing agent, and a catalyst for phenolic resins.


Lactic Acid 80% (E270) is also used in leather tanning, oil well acidizing, and as a plant growth regulator.
Lactic Acid 80% (E270) is applied in Petroleum Production and Refining, Soldering, Farming (Pesticides) ,Leather Tanning and Processing, Fur Dressing and Dyeing, Textiles (Printing, Dyeing, or Finishing).


The fastest growing use for Lactic Acid 80% (E270) is its use as a monomer for the production of polylactic acid or polylactide (PLA).
Applications for PLA include containers for the food and beverage industries, films and rigid containers for packaging, and serviceware (cups, plates, utensils).


The PLA polymer can also be spun into fibers and used in apparel, fiberfill (pillows, comforters), carpet, and nonwoven applications such as wipes.
Lactic Acid 80% (E270) is used in dyeing baths, as mordant in printing woolen goods, solvent for water-insoluble dyes (alcohol-soluble induline, nigrosine, spirit-blue).


Lactic Acid 80% (E270) is used reducing chromates in mordanting wool.
Lactic Acid 80% (E270) is used manufacturing cheese, confectionery.
Lactic Acid 80% (E270) is used component of babies' milk formulas; acidulant in beverages; for acidulating worts in brewing.


Lactic Acid 80% (E270) is used in preparation of sodium lactate injections. Ingredient of cosmetics.
Lactic Acid 80% (E270) is used component of spermatocidal jellies.
Lactic Acid 80% (E270) is used for removing Clostridium butyricum in manufacturing of yeast; dehairing, plumping, and decalcifying hides.


Lactic Acid 80% (E270) is used solvent for cellulose formate.
Lactic Acid 80% (E270) is used flux for soft solder.
Lactic Acid 80% (E270) is used manufacturing lactates which are used in food products, in medicine, and as solvents.


Lactic Acid 80% (E270) is used plasticizer, catalyst in the casting of phenolaldehyde resins.
Lactic Acid 80% (E270) can be used as acidulent, flavoring agent and pH regulator in beverages, meat, sourdough, salads and dressings, confectionery and pickled vegetables.


Lactic Acid 80% (E270) is used in food and technical applications.
Liquid Lactic Acid 80% (E270), as a 1:1 mixture of levorotatory and dextrorotatory lactic acid, is very commonly used for acid regulation in bakery and confectionery products or in beverages and for preservation.


Likewise, Lactic Acid 80% (E270) is used in lactofermentation and is used to preserve silages in feed production.
In technical applications, Lactic Acid 80% (E270) provides support through its biocidal effect and is therefore a component of disinfectant solutions and other cleaners.


In addition, Lactic Acid 80% (E270) is used for gentle decalcification.
Lactic Acid 80% (E270) is food grade and is used for the production of several types of cheeses.
Lactic Acid 80% (E270) is particularly useful when UHT, ultra-pasteurised or powdered milk are used as the starting materials, since the heat treatments used in the production of these milks deactivates the lactose and prevents the cheese culture from being able to turn it fully into Lactic Acid 80% (E270).


The inclusion of additional Lactic Acid 80% (E270) prior to rennetting overcomes this shortage and improves the curd yield.
Lactic Acid 80% (E270) is a vital ingredient in Ricotta Impastata, Mozzarella, Queso Blanco and other speciality cheeses and can be used in the production of sour milk products, such as Koumiss, Laban, Kefir, as well as some cottage cheeses.


In production, Lactic Acid 80% (E270) is usually added so that the pH of the milk reaches around 5.0.
The casein in fermented milk is coagulated (curdled) by Lactic Acid 80% (E270) and it is also responsible for the sour flavour of sourdough breads.
Lactic Acid 80% (E270) is mainly used to adjust the pH of cosmetic products and is added during the production of shampoos to increase the shine of the hair.


Lactic Acid 80% (E270) is used to adjust the pH of cosmetic products
When making shampoos, Lactic Acid 80% (E270) is added to make the hair shiner
Often used as food or feed additives, Lactic Acid 80% (E270) can improve the flavor of food and prolong the shelf life.


Lactic Acid 80% (E270) is widely used in canned food, bread, flour, pastry, feed and other industries as a food flavor improver.
Lactic Acid 80% (E270) is especially suitable for the acidity adjustment of various solid and powdered foods.
Lactic Acid 80% (E270)'s excellent pH adjustment function and antibacterial ability can effectively inhibit the growth of microorganisms and prolong the shelf life of food.


Pharmaceutical technology uses Lactic Acid 80% (E270) to convert water-insoluble medicinal substances into salts of lactic acid (lactates); these are more soluble in water (example: ciprofloxacin).
In cosmetics, Lactic Acid 80% (E270) is used in skin creams and other products to treat acne.


Lactic Acid 80% (E270) is used to make cultured dairy products, as a food preservative, and to make chemicals.
Lactic Acid 80% (E270) has a role as a Daphnia magna metabolite and an algal metabolite.
Lactic Acid 80% (E270) is functionally related to a propionic acid.


Lactic Acid 80% (E270) is a conjugate acid of a lactate.
A normal intermediate in the fermentation (oxidation, metabolism) of sugar.
The concentrated form is used internally to prevent gastrointestinal fermentation.


Sodium lactate is the sodium salt of Lactic Acid 80% (E270), and has a mild saline taste.
It is produced by fermentation of a sugar source, such as corn or beets, and then, by neutralizing the resulting Lactic Acid 80% (E270) to create a compound having the formula NaC3H5O3.
Lactic Acid 80% (E270) was one of active ingredients in Phexxi, a non-hormonal contraceptive agent.


-Power supply uses of Lactic Acid 80% (E270):
A number of foods are made directly through Lactic Acid 80% (E270) fermentation.
This mainly includes sour milk products such as sour milk, yogurt, kefir and buttermilk.
These are produced by infecting pasteurized milk with starter cultures of Lactic Acid 80% (E270) bacteria.

Other products include lacto-fermented vegetables such as sauerkraut, beetroot in some varieties of borscht, or kimchi, as well as sourdough and sourdough products.
Silage, fresh feed made sustainable by fermentation, is also based on Lactic Acid 80% (E270) fermentation.
As a food additive, Lactic Acid 80% (E270) carries the designation E 270.

Lactic Acid 80% (E270) is used in many different ways as an acidity regulator in the food and luxury goods industries, for example in baked goods, confectionery and occasionally in lemonades.
By changing the pH value in the food to a pH of about 4, the food is preserved, since colonization with other microorganisms is largely excluded.
In the form of the salts calcium lactate or calcium lactate gluconate Lactic Acid 80% (E270) can also be added for calcium enrichment.


-Material uses of Lactic Acid 80% (E270):
Lactic Acid 80% (E270) is the monomer of polylactides or polylactic acids (PLA), which are used in various ways as biodegradable and biobased plastics.
Lactic Acid 80% (E270) has an antibacterial effect and is therefore added to liquid soaps, cleaners and detergents.

They develop their disinfecting effect optimally at a pH value of 3 to 4.
Lactic Acid 80% (E270) was and is also used as a contraceptive.
Lactic Acid 80% (E270) is used as a descaling agent in the tannery for descaling hides.

Lactic Acid 80% (E270) is also used for this purpose in the textile industry and printing companies.
Some cleaning tablets for coffee machines, soft drinks machines and similar appliances contain Lactic Acid 80% (E270) as a descaling agent.
Beekeepers use Lactic Acid 80% (E270) to treat bees against the Varroa mite, ensuring that the treated hives or honeycombs are brood free.
Arachnologists use Lactic Acid 80% (E270) to illuminate the prepared epigyne of female spiders or other chitin structures and to dissolve tissue debris.


-Beer brewing uses of Lactic Acid 80% (E270):
Lactic Acid 80% (E270) is to lower the pH and add a bit of tartness.
Naturally add in small amounts or Lactic Acid 80% (E270) will become quite sour.


-Cheese making & Whipped Butter uses of Lactic Acid 80% (E270):
Ricotta in particular and whipped butter in combination with GDL.
Ricotta Impastata, Mozzarella and Queso Blanco.


-Interesting non food uses for Lactic Acid 80% (E270):
Lactic Acid 80% (E270) is the principal building block for Poly Lactic Acid (PLA) biodegradable plastics.
PLA is a biobased and bio-degradable polymer that can be used for producing renewable and compostable plastics.
Lactic Acid 80% (E270) is also being used in the cosmetics industry for acne treatment.



FEATURES AND BENEFITS OF LACTIC ACID 80% (E270):
*Lactic Acid 80% (E270) is very useful to rejuvenate the skin by encouraging the shedding of old surface skin cells
*Lactic Acid 80% (E270) can reduce the appearance of fine lines, irregular pigmentation, age spots & decreases enlarged pores
*Lactic Acid 80% (E270) is used good choice for first-time peel users or for those with sensitive skin
*Lactic Acid 80% (E270) is often used in creams & lotions at a lower concentration for a more gentle acid-based peel.



USE IN FOOD, LACTIC ACID 80% (E270):
Lactic Acid 80% (E270) is a natural preservative found in several foods, including pickled vegetables, yoghurt, and baked goods.
Lactic Acid 80% (E270) is a cheap and minimally processed
Lactobacillus and Streptococcus cultures produce Lactic Acid 80% (E270) through fermentation.
The bacteria break down sugar to extract energy and produce Lactic Acid 80% (E270) as a byproduct.
Lactic Acid 80% (E270) helps regulate pH levels and prevents the growth of microorganisms, extending shelf life.



HOW TO USE LACTIC ACID 80% (E270) IN COSMETICS:
- Lactic Acid 80% (E270) is a product that does not apply to pure skin
- Lactic Acid 80% (E270) can be included as an ingredient in cosmetic compositions containing acidulant and water: serums, gels, tonics, masks, lotions, creams, shampoos, cleanses, etc.



BENEFITS AND APPLICATIONS OF LACTIC ACID 80% (E270):
Lactic Acid 80% (E270) is used to treat hyperpigmentation, age spots, and other conditions that contribute to a dull, uneven complexion.
Lactic Acid 80% (E270) also enhances skin tone and minimises the appearance of pores.

Lactic Acid 80% (E270) promotes cell turnover and cell renewal, which are the processes through which your skin loses old cells and replaces them with new ones.
Lactic Acid 80% (E270) works really well for sensitive skin because of its milder nature as compared to other alpha-hydroxy acids.

Lactic Acid 80% (E270) is also a key component of over-the-counter lotions and creams for "chicken skin," i.e., pimples on the backs of the arms.
Lactic Acid 80% (E270) aids in the dissolution of the clog of skin cells that form around the hair follicle, smoothing out the bumpiness.
Lactic Acid 80% (E270) is commonly found in topical therapies for eczema, psoriasis, and rosacea.



THE PROPERTIES OF LACTIC ACID 80% (E270):
The properties of Lactic Acid 80% (E270)
- Keratolytic exfoliates the skin by removing dead skin and scalp cells
- Stimulates collagen and elastin synthesis, promoting cell renewal
- Lactic Acid 80% (E270) improves skin grain and appearance pH
- Activates the emulsifier conditioner used in the manufacture of hair care compositions



BENEFITS OF LACTIC ACID 80% (E270):
*Brightens a dull complexion
*Humectant and skin firmer
*Exfoliant
*Improves skin tone and texture
*Vegan Friendly
*GMO-free



FUNCTION OF LACTIC ACID 80% (E270):
In food, apart from its nutritional function for normal growth, Lactic Acid 80% (E270) improves flavor and taste, improves quality of food and beverage products such as confectionery, cake, milk powder, yogurt etc. as firming agent, buffering agent and flour regulator.
Lactic Acid 80% (E270) increases effectiveness of antioxidants, prevents decolorization of fruits and vegetables.



BENEFITS OF LACTIC ACID 80% (E270):
Lactic Acid 80% (E270) reduces the alkalinity levels of brewing liquor, stimulating maximum enzyme activity in the wort enabling optimum pH levels throughout the whole brewing process.
Lactic Acid 80% (E270) improves extract yield and fermentability.
Lactic Acid 80% (E270) is suitable for beers where no other anions are needed, for example, pilsner lagers.
Lactic Acid 80% (E270) can also be used to reduce the pH of final wort or products.



SUGGESTED BLENDS OF LACTIC ACID 80% (E270):
Lactic Acid 80% (E270) works well in conjunction with Vitamin A, B and C.
Be sure to check the final pH level is not less than 3.5 when combining several acidic ingredients together.



HOW LACTIC ACID 80% (E270) WORKS:
Lactic Acid 80% (E270) works by removing the upper layer of skin cells, which is usually composed of dead skin cells.
Lactic Acid 80% (E270) also works by increasing the natural moisture retention capabilities of the skin to give your skin a hydrated look.



CONCENTRATION AND SOLUBILITY OF LACTIC ACID 80% (E270):
Lactic Acid 80% (E270) is recommended that it should be used at a concentration of 1–5%.
Lactic Acid 80% (E270) is soluble in water, alcohol, and glycerol but is insoluble in oil.



HOW TO USE LACTIC ACID 80% (E270):
Prepare the oil and water phases of your formulation separately.
Heat the oil and water phases using a double boiler.
Add Lactic Acid 80% (E270) to the water phase, accompanied by constant stirring.
Blend both the phases together using a mini-mixer or a large mixing brush



PHYSICAL and CHEMICAL PROPERTIES of LACTIC ACID 80% (E270):
Odor: odorless
Melting point/freezing point:
Melting point: 18 °C at 1.013 hPa
Initial boiling point and boiling range: 122 °C at 18,66 - 19,99 hPa
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits: No data available
Flash point: 113 °C - closed cup
Autoignition temperature: 400 °C at 1.011,4 - 1.018,9 hPa
Decomposition temperature: No data available
pH: No data available
Viscosity
Viscosity, kinematic: No data available
Viscosity, dynamic: No data available
Water solubility: 100 g/l at 20 °C - soluble

Partition coefficient: n-octanol/water:
log Pow: ca.-0,54 at 25 °C - Bioaccumulation is not expected.
Vapor pressure: No data available
Density: 1,25 g/cm3 at 15 °C
Relative density: No data available
Relative vapor density: No data available
Particle characteristics: No data available
Explosive properties: No data available
Oxidizing properties: none
Other safety information:
Surface tension 70,7 mN/m at 1g/l at 20 °C
Formula: H₃CCH(OH)COOH
MW: 90.08 g/mol
Boiling Pt: 122 °C (20 hPa)
Density: 1.11…1.21 g/cm³ (20 °C)
Storage Temperature: Ambient
MDL Number: MFCD00004520
CAS Number: 50-21-5
EINECS: 200-018-0

CAS: 50-21-5
MF: C3H6O3
MW: 90.08
EINECS: 200-018-0
Mol File: 50-21-5.mol
Lactic acid Chemical Properties
Melting point: 18°C
alpha: -0.05 º (c= neat 25 ºC)
Boiling point: 122 °C/15 mmHg (lit.)
density: 1.209 g/mL at 25 °C (lit.)
vapor density: 0.62 (vs air)
vapor pressure: 19 mm of Hg (@ 20°C)
FEMA: 2611 | LACTIC ACID
refractive index: n20/D 1.4262

Fp: >230 °F
storage temp.: 2-8°C
solubility: Miscible with water and with ethanol (96 per cent).
form: syrup
pka: 3.08(at 100℃)
Specific Gravity: 1.209
color: Colorless to yellow
Water Solubility: SOLUBLE
Merck: 145,336
JECFA Number: 930
BRN: 1209341
Stability: Stable.
Physical state: viscous
Color: colorless



FIRST AID MEASURES of LACTIC ACID 80% (E270):
-Description of first-aid measures:
*General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LACTIC ACID 80% (E270):
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up with liquid-absorbent material.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of LACTIC ACID 80% (E270):
-Extinguishing media:
*Suitable extinguishing media:
Water
Foam
Carbon dioxide (CO2)
Dry powder
*Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LACTIC ACID 80% (E270):
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles
*Body Protection:
protective clothing
*Respiratory protection
Recommended Filter type: Filter type ABEK
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LACTIC ACID 80% (E270):
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.



STABILITY and REACTIVITY of LACTIC ACID 80% (E270):
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Possibility of hazardous reactions:
No data available.
-Incompatible materials:
No data available

LACTIC ACID ETHYL ESTER
Lactic acid ethyl ester is an environmentally benign solvent with effectiveness comparable to petroleum-based solvents.
Lactic acid ethyl ester is found naturally in small quantities in a wide variety of foods including wine, chicken, and various fruits.
Lactic acid ethyl ester, also known as lactic acid ethyl ester, is the organic compound with the formula CH3CH(OH)CO2CH2CH3.

CAS Number: 687-47-8
EC Number: 202-598-0
Molecular Formula: C5H10O3
Molecular Weight (g/mol): 118.13

ETHYL LACTATE, 97-64-3, Ethyl 2-hydroxypropanoate, Solactol, Actylol, Acytol, Lactic acid, ethyl ester, Ethyl 2-hydroxypropionate, Propanoic acid, 2-hydroxy-, ethyl ester, Lactate d'ethyle, 2-Hydroxypropanoic acid ethyl ester, Lactic Acid Ethyl Ester, Ethyl alpha-hydroxypropionate, FEMA No. 2440, Eusolvan, Ethyl lactate (natural), Ethylester kyseliny mlecne, Lactate d'ethyle [French], NSC 8850, HSDB 412, Ethylester kyseliny mlecne [Czech], 2-Hydroxypropionic Acid Ethyl Ester, EINECS 202-598-0, UN1192, Ethyl ester of lactic acid, BRN 1209448, UNII-F3P750VW8I, AI3-00395, F3P750VW8I, Ethyl .alpha.-hydroxypropionate, DTXSID6029127, CHEBI:78321, NSC-8850, 4-03-00-00643 (Beilstein Handbook Reference), ethyl d-lactate, Ethyl lactate,C5H10O3,97-64-3, EthylL-(-)-Lactate, ethyl-lactate, ethyl DL-lactate, DL-Ethyl Lactate, Milchsaureathylester, Nat. Ethyl Lactate, MFCD00065359, Ethyl racemic-lactate, lactic acid ethylester, (S)-(-)-2-Hydroxypropionic acid ethyl ester, PURASOLV ELS, VERTECBIO EL, Lactic acid-ethyl ester, ELT (CHRIS Code), Mono-Ethyl mono-lactate, ETHYL LACTATE [MI], (.+/-.)-Ethyl lactate, Ethyl 2-hydroxypropanoate #, ETHYL LACTATE [FCC], SCHEMBL22598, ETHYL LACTATE [FHFI], ETHYL LACTATE [HSDB], ETHYL LACTATE [INCI], ETHYL LACTATE [MART.], DTXCID509127, WLN: QVY1 & O2, ETHYL LACTATE [WHO-DD], CHEMBL3186323, (+-)-Ethyl 2-hydroxypropanoate, (+-)-Ethyl 2-hydroxypropionate, FEMA 2440, NSC8850, Tox21_200889, 2-hydroxy-propionic acid ethyl ester, NA1192, Ethyl lactate, >=98%, FCC, FG, AKOS009157222, LS-2733, UN 1192, (+/-)-LACTIC ACID ETHYL ESTER, CAS-97-64-3, NCGC00248866-01, NCGC00258443-01, (+/-)-ETHYL 2-HYDROXYPROPIONATE, AS-13500, SY030456, A9137, Ethyl lactate [UN1192] [Flammable liquid], Ethyl lactate, natural, >=98%, FCC, FG, Ethyl lactate, SAJ first grade, >=97.5%, FT-0626259, FT-0627926, FT-0651151, L0003, Ethyl lactate [UN1192] [Flammable liquid], EN300-115258, A845735, Q415418, J-521263, 2-[(4-benzylpiperazin-1-yl)methyl]isoindoline-1,3-dione, (±)-Ethyl 2 hydroxypropanoate, (±)-Ethyl 2-hydroxypropionate, (±)-Ethyl lactate, 2-Hydroxypropanoate d'éthyle [French] [ACD/IUPAC Name], 2-Hydroxypropanoic acid ethyl ester, 97-64-3 [RN], Ethyl 2-hydroxypropanoate [ACD/IUPAC Name], Ethyl ester of lactic acid, Ethyl lactate [ACD/Index Name] [Wiki], Ethyl α-hydroxypropionate, Ethyl α-hydroxypropionate, Ethyl-2-hydroxypropanoat [German] [ACD/IUPAC Name], MFCD00065359 [MDL number], OD5075000, Propanoic acid, 2-hydroxy-, ethyl ester [ACD/Index Name], QY1&VO2 [WLN], 2-hydroxypropionic acid ethyl ester, 4-03-00-00643 [Beilstein], Actylol, Acytol, DL-Ethyl Lactate, DL-Ethyllactate, DL-LACTIC ACID, ETHYL ESTER, Ethyl 2-hydroxy propanoate, Ethyl lactate,C5H10O3,97-64-3, Ethyl racemic-lactate, Ethylester kyseliny mlecne [Czech], ethyllactate, Ethyl-lactate, Eusolvan, Lactate d'ethyle [French], lactic acid ethyl ester, Lactic acid, ethyl ester, Lactic acid-ethyl ester, L-lactic acid ethyl ester, MFCD00077825 [MDL number], Milchs??ure??thylester, Propanoic acid, 2-hydroxy-, ethyl ester (9CI), Solactol, UN 1192

Lactic acid ethyl ester is found naturally in small quantities in a wide variety of foods including wine, chicken, and various fruits.
The odor of Lactic acid ethyl ester when dilute is mild, buttery, creamy, with hints of fruit and coconut.

Lactic acid ethyl ester is registered under the REACH Regulation and is manufactured in and / or imported to the European Economic Area, at ≥ 10 to < 100 tonnes per annum.
Lactic acid ethyl ester is used by consumers, by professional workers (widespread uses), in formulation or re-packing and at industrial sites.

Lactic acid ethyl ester, also known as actylol, is the organic compound with the formula CH3CH(OH)CO2CH2CH3.
Lactic acid ethyl ester is the ethyl ester of lactic acid.

A colorless liquid, Lactic acid ethyl ester is a chiral ester.
Being naturally derived, Lactic acid ethyl ester is readily available as a single enantiomer.

Lactic acid ethyl ester is commonly used as a solvent.
Lactic acid ethyl ester is considered biodegradable and can be used as a water-rinsible degreaser.

Lactic acid ethyl ester is an environmentally benign solvent with effectiveness comparable to petroleum-based solvents.
The worldwide solvent market is about 30 million pounds per year, where Lactic acid ethyl ester can have an important share.

Lactic acid ethyl ester is considered a chemical commodity and has attracted much attention in recent years, since Lactic acid ethyl ester is formed by the esterification reaction of ethanol and lactic acid, which can be generated from biomass raw materials through fermentation.
In this work, an overview regarding the main properties and applications of Lactic acid ethyl ester, as well as Lactic acid ethyl ester synthesis and production processes, with a particular emphasis on reactive/separation processes, is presented.

Lactic acid ethyl ester, lactic acid ethyl ester or 2-hydroxypropanoic acid ethyl ester is the chemical compound of lactic acid with ethanol in the form of an ester.
Depending on Lactic acid ethyl ester synthesis, Lactic acid ethyl ester is available as racemate or pure substance.

If Lactic acid ethyl ester is split back into Lactic acid ethyl ester starting materials ethanol and lactic acid (e.g. by a chemical reaction), Lactic acid ethyl ester can be decomposed in nature.
Esterases, naturally occurring enzymes, can also carry out the split back into the original materials.

Lactic acid ethyl ester is therefore considered a "green solvent", as Lactic acid ethyl ester does not leave any toxic decomposition products in the ecosystem.
This provides an advantage over chlorinated solvents or glycols or glycol ethers, which have a higher biological toxicity.

Also known as lactic acid ethyl ester, is a monobasic ester formed from lactic acid and ethanol, commonly used as a solvent hence the name “lactic acid ethyl ester”.
Lactic acid ethyl ester is considered biodegradable and can be used as a water-risible degreaser.
Lactic acid ethyl ester is found naturally in small quantities in a wide variety of foods including wine, chicken, and various fruits.

Lactic acid ethyl ester is produced from biological sources and can be either the Levo (S) form or Dextro (R) form, depending on the organism that is the source of the lactic acid.
The most biologically sourced Lactic acid ethyl ester is ethyl (−)-L-lactate (ethyl (S)-lactate).

Lactic acid ethyl ester is also produced industrially from petrochemical stocks, and this Lactic acid ethyl ester consists of the racemic mixture of Levo and Dextro forms.
In some jurisdictions, the natural product is exempt from many restrictions placed upon the use and disposal of solvents.
Because both enantiomers are found in nature, and because Lactic acid ethyl ester is easily biodegradable, Lactic acid ethyl ester is considered to be a “green solvent.”

Uses of Lactic acid ethyl ester:
Lactic acid ethyl ester is used as a solvent substitute for glycol ethers in photolithography in the semiconductor manufacturing industry.
Lactic acid ethyl ester is used in some nail polish removers.

Lactic acid ethyl ester is used as a solvent for resins, dyes, and coatings; has FDA approval for use as a food flavoring agent
Lactic acid ethyl ester is the active ingredient in many anti-acne preparations.

Uses at industrial sites:
Lactic acid ethyl ester is used in the following products: semiconductors, photo-chemicals, polymers, metal surface treatment products, non-metal-surface treatment products and washing & cleaning products.
Lactic acid ethyl ester is used in the following areas: formulation of mixtures and/or re-packaging.

Lactic acid ethyl ester is used for the manufacture of: electrical, electronic and optical equipment and machinery and vehicles.
Release to the environment of Lactic acid ethyl ester can occur from industrial use: in processing aids at industrial sites.

Industry Uses:
Processing aids, not otherwise listed
Solvent
Solvents (which become part of product formulation or mixture)

Consumer Uses:
Lactic acid ethyl ester is used in the following products: air care products, biocides (e.g. disinfectants, pest control products), perfumes and fragrances, polishes and waxes, washing & cleaning products and cosmetics and personal care products.
Other release to the environment of Lactic acid ethyl ester is likely to occur from: indoor use as processing aid and outdoor use as processing aid.

Widespread uses by professional workers:
Lactic acid ethyl ester is used in the following products: polishes and waxes and washing & cleaning products.
Other release to the environment of Lactic acid ethyl ester is likely to occur from: indoor use as processing aid.

Industrial Processes with risk of exposure:
Semiconductor Manufacturing
Painting (Solvents)
Plastic Composites Manufacturing

Applications of Lactic acid ethyl ester:
Lactic acid ethyl ester is an excellent ingredient for formulating printing inks, coatings, resin cleaners, paint strippers, graffiti removers, ink cleaners, etc.
Lactic acid ethyl ester alone and is an ideal wipe solvent.

Lactic acid ethyl ester can be used in industrial coatings applications, primarily in coil, extrusion, wood furniture and fixtures, containers and closures, automotive finishes and machinery.
Lactic acid ethyl ester is 100% biodegradable, easy and inexpensive to recycle.

Due to Lactic acid ethyl ester low toxicity, Lactic acid ethyl ester is a popular choice across many different production scenarios.
Lactic acid ethyl ester is also used as a solvent with various types of polymers.
In the presence of water, acids and bases the chemical will hydrolyse into ethanol and lactic acid.

Because both enantiomers are found in nature, and because Lactic acid ethyl ester is easily biodegradable, Lactic acid ethyl ester is considered to be a "green solvent."
Lactic acid ethyl ester and Lactic acid ethyl ester aqueous solutions are used as sustainable media for organic synthesis.

Due to Lactic acid ethyl ester relatively low toxicity, Lactic acid ethyl ester is used commonly in pharmaceutical preparations, food additives, and fragrances.
Lactic acid ethyl ester is also used as solvent for nitrocellulose, cellulose acetate, and cellulose ethers.

Production of Lactic acid ethyl ester:
Lactic acid ethyl ester is produced from biological sources, and can be either the levo (S) form or dextro (R) form, depending on the organism that is the source of the lactic acid.
Most biologically sourced Lactic acid ethyl ester is ethyl (−)-L-lactate (ethyl (S)-lactate).
Lactic acid ethyl ester is also produced industrially from petrochemical stocks, and this Lactic acid ethyl ester consists of the racemic mixture of levo and dextro forms.

Methods of Manufacturing of Lactic acid ethyl ester:

Derivation: (a) By the esterification of lactic acid with ethanol; (b) by combining acetaldehyde with hydrogen cyanide to form acetaldehyde cyanohydrin, which is converted into Lactic acid ethyl ester by treating with ethanol and an inorganic acid.

d-Lactic acid ethyl ester is obtained from d-lactic acid by azeotropic distillation with ethyl alcohol or benzene in the presence of concentrated H2SO4.
The l-form is prepared in similar fashion starting from l-lactic acid.
The racemic product is prepared by boiling for 24 hours optically inactive lactic acid with ethyl alcohol in carbon tetrachloride, or with an excess of ethyl alcohol in the presence of chlorosulfonic acid, or in the presence of benzenesulfonic acid in benzene solution.

Handling and Storage of Lactic acid ethyl ester:

Nonfire Spill Response:
ELIMINATE all ignition sources (no smoking, flares, sparks or flames) from immediate area.
All equipment used when handling Lactic acid ethyl ester must be grounded.

Do not touch or walk through spilled material.
Stop leak if you can do Lactic acid ethyl ester without risk.

Prevent entry into waterways, sewers, basements or confined areas.
A vapor-suppressing foam may be used to reduce vapors.

Absorb or cover with dry earth, sand or other non-combustible material and transfer to containers.
Use clean, non-sparking tools to collect absorbed material.

LARGE SPILL:
Dike far ahead of liquid spill for later disposal.
Water spray may reduce vapor, but may not prevent ignition in closed spaces.

Reactivity Profile of Lactic acid ethyl ester:

Lactic acid ethyl ester is an ester.
Esters react with acids to liberate heat along with alcohols and acids.
Strong oxidizing acids may cause a vigorous reaction that is sufficiently exothermic to ignite the reaction products.

Heat is also generated by the interaction of esters with caustic solutions.
Flammable hydrogen is generated by mixing esters with alkali metals and hydrides.

Fire Fighting of Lactic acid ethyl ester:
The majority of these products have a very low flash point.
Use of water spray when fighting fire may be inefficient.

SMALL FIRE:
Dry chemical, CO2, water spray or alcohol-resistant foam.
Do not use dry chemical extinguishers to control fires involving nitromethane (UN1261) or nitroethane (UN2842).

LARGE FIRE:
Water spray, fog or alcohol-resistant foam.
Avoid aiming straight or solid streams directly onto Lactic acid ethyl ester.
If Lactic acid ethyl ester can be done safely, move undamaged containers away from the area around the fire.

FIRE INVOLVING TANKS OR CAR/TRAILER LOADS:
Fight fire from maximum distance or use unmanned master stream devices or monitor nozzles.
Cool containers with flooding quantities of water until well after fire is out.

Withdraw immediately in case of rising sound from venting safety devices or discoloration of tank.
ALWAYS stay away from tanks engulfed in fire.
For massive fire, use unmanned master stream devices or monitor nozzles; if this is impossible, withdraw from area and let fire burn.

Accidental Release Measures of Lactic acid ethyl ester:

Isolation and Evacuation:

IMMEDIATE PRECAUTIONARY MEASURE:
Isolate spill or leak area for at least 50 meters (150 feet) in all directions.

LARGE SPILL:
Consider initial downwind evacuation for at least 300 meters (1000 feet).

FIRE:
If tank, rail car or tank truck is involved in a fire, ISOLATE for 800 meters (1/2 mile) in all directions; also, consider initial evacuation for 800 meters (1/2 mile) in all directions.

Cleanup Methods:
Use personal protective equipment.
Avoid breathing vapors, mist or gas.

Ensure adquate ventilation.
Remove all sources of ignition.

Evacuate personnel to safe areas.
Beware of vapors accumulating to form explosive concentrations.
Vopors can accumulate in low areas.

Disposal Methods of Lactic acid ethyl ester:
Recycle any unused portion of the material for Lactic acid ethyl ester approved use or return Lactic acid ethyl ester to the manufacturer or supplier.

Ultimate disposal of the chemical must consider:
Lactic acid ethyl ester's impact on air quality; potential migration in air, soil or water; effects on animal, aquatic and plant life; and conformance with environmental and public health regulations.
If Lactic acid ethyl ester is possible or reasonable use an alternative chemical product with less inherent propensity for occupational harm/injury/toxicity or environmental contamination.

Identifiers of Lactic acid ethyl ester:
CAS Number:
687-47-8 (L-isomer)
97-64-3 (racemate)
7699-00-5 (D-isomer)

ChemSpider: 13837423
ECHA InfoCard: 100.002.363
EC Number: 202-598-0
PubChem CID: 7344
RTECS number: OD5075000
UNII: F3P750VW8I
UN number: 1192
CompTox Dashboard (EPA): DTXSID6029127
InChI: InChI=1S/C5H10O3/c1-3-8-5(7)4(2)6/h4,6H,3H2,1-2H3
Key: LZCLXQDLBQLTDK-UHFFFAOYSA-N
InChI=1/C5H10O3/c1-3-8-5(7)4(2)6/h4,6H,3H2,1-2H3
Key: LZCLXQDLBQLTDK-UHFFFAOYAV
SMILES: CCOC(=O)C(C)O

Synonym(s): (S)-(-)-Lactic acid ethyl ester, L(-)-Lactic acid ethyl ester, (S)-(-)-2-Hydroxypropionic acid ethyl ester
Linear Formula: CH3CH(OH)COOC2H5
CAS Number: 687-47-8
Molecular Weight: 118.13
MDL number: MFCD00004518
EC Index Number: 211-694-1

CAS: 687-47-8
Molecular Formula: C5H10O3
Molecular Weight (g/mol): 118.13
MDL Number: MFCD00004518
InChI Key: LZCLXQDLBQLTDK-BYPYZUCNSA-N
PubChem CID: 92831
ChEBI: CHEBI:78322
IUPAC Name: ethyl (2S)-2-hydroxypropanoate
SMILES: CCOC(=O)C(C)O

Properties of Lactic acid ethyl ester:
Chemical formula: C5H10O3
Molar mass: 118.132 g·mol−1
Appearance: Colorless liquid
Density: 1.03 g/cm3
Melting point: −26 °C (−15 °F; 247 K)
Boiling point: 151 to 155 °C (304 to 311 °F; 424 to 428 K)
Solubility in water: Miscible
Solubility in ethanol
and most alcohols: Miscible
Chiral rotation ([α]D): −11.3°
Magnetic susceptibility (χ): -72.6·10−6 cm3/mol

vapor pressure: 1.6 hPa ( 20 °C)
Quality Level: 200
Assay: ≥99% (GC)
form: liquid
autoignition temp.: 400 °C
potency: >2000 mg/kg LD50, oral (Rat)
expl. lim.: 1.5-16.4 % (v/v)
pH: 4 (20 °C, 50 g/L in H2O)
kinematic viscosity: 2.7 cSt(25 °C)
bp: 154 °C/1013 hPa
mp: -25 °C
transition temp: flash point 53 °C
density: 1.03 g/cm3 at 20 °C
storage temp.: 2-30°C
InChI: 1S/C5H10O3/c1-3-8-5(7)4(2)6/h4,6H,3H2,1-2H3/t4-/m0/s1
InChI key: LZCLXQDLBQLTDK-BYPYZUCNSA-N

Molecular Weight: 118.13 g/mol
XLogP3-AA: 0.2
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 3
Rotatable Bond Count: 3
Exact Mass:
118.062994177 g/mol
Monoisotopic Mass:
118.062994177 g/mol
Topological Polar Surface Area: 46.5Ų
Heavy Atom Count: 8
Complexity: 79.7
Isotope Atom Count: 0
Defined Atom Stereocenter Count: 0
Undefined Atom Stereocenter Count: 1
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes

Specifications of Lactic acid ethyl ester:
Acidity: 0.1% max. (as lactic acid)
Melting Point: -26.0°C
Density: 1.0340g/mL
Boiling Point: 154.0°C
Flash Point: 46°C
Infrared Spectrum: Authentic
Assay Percent Range: 96% min. (GC)
Packaging: Glass bottle
Linear Formula: CH3CH(OH)CO2C2H5
Refractive Index: 1.4100 to 1.4160
Quantity: 250 mL
Beilstein: 03,264
Fieser: 17,135
Merck Index: 14,3817
Specific Gravity: 1.034
Specific Rotation Condition: − 10.00 (20.00°C neat)
Specific Rotation: − 10.00
Solubility Information: Solubility in water: soluble. Other solubilities: miscible with alcohols,ketones and esters
Formula Weight: 118.13
Percent Purity: 97%
Physical Form: Liquid
Chemical Name or Material: Ethyl L(-)-lactate

Structure of Lactic acid ethyl ester:
Dipole moment: 3.46 D

Related compounds of Lactic acid ethyl ester:
Lactic acid, MLactic acid ethyl ester

Related Products of Lactic acid ethyl ester:
Dimethyl Glutaconate (~10% Cis)
(E,E)-4,6-Dimethyl-2,4-heptadienoic Acid
3,6-Dimethyl-3-heptanol
1,1-Dimethoxybutane
(E)-6,6-Dimethyl-2-hept-1-en-4-yn-1-amine

Names of Lactic acid ethyl ester:

Regulatory process names:
2-Hydroxypropanoic acid ethyl ester
Actylol
Acytol
Ethyl 2-hydroxypropionate
Ethyl alpha-hydroxypropionate
ethyl DL-lactate
Ethyl lactate
ETHYL LACTATE
Ethyl lactate
ethyl lactate
Ethyl lactate (natural)
ethyl lactate ethyl DL-lactate
ethyl lactate; ethyl DL-lactate
Ethylester kyseliny mlecne
Lactate d'ethyle
Lactic acid, ethyl ester
Propanoic acid, 2-hydroxy-, ethyl ester
Solactol

Translated names:
DL-mleczan etylu (pl)
ester etylowy kwasu mlekowego (pl)
Ethyl DL-lactat (de)
ethyl-DL-laktát (cs)
ethyl-laktát (cs)
ethyl-laktát ethyl-DL-laktát (cs)
ethyllacta (da)
ethyllactaat (nl)
Ethyllactat (de)
Ethyllactat Ethyl DL-lactat (de)
etil DL-lactat (ro)
etil DL-laktat (sl)
etil lactat (ro)
etil lactat etil DL-lactat (ro)
etil laktat (sl)
etil laktat etil DL-laktat (sl)
etil-DL-laktat (hr)
etil-DL-laktatas (lt)
etil-DL-laktát (hu)
etil-DL-laktāts (lv)
etil-laktat (hr)
etil-laktát (hu)
etil-laktát etil-DL-laktát (hu)
etillaktatas (lt)
etillaktatas etil-DL-laktatas (lt)
etillaktāts (lv)
etyl-(RS)-laktát (sk)
etyl-laktát (sk)
etyllaktat (no)
etyllaktat (sv)
etyylilaktaatti (fi)
Etüül-DL-laktaat (et)
Etüüllaktaat (et)
lactate d'éthyle; DL-lactate d'éthyle; (fr)
lactato de etilo (es)
lactato de etilo (pt)
lattato di etile (it)
mleczan etylu (pl)
mleczan etylu DL-mleczan etylu ester etylowy kwasu mlekowego (pl)
γαλακτικό αιθυλο (el)
етил DL-лактат (bg)
етил лактат (bg)
етил лактат етил DL-лактат (bg)

IUPAC names:
2-ethoxypropanoic acid
ethyl (2R)-2-hydroxypropanoate
Ethyl (S)-2-hydroxypropanoate
ethyl 2-hydroxypropanoat
ETHYL 2-HYDROXYPROPANOATE
Ethyl 2-hydroxypropanoate
ethyl 2-hydroxypropanoate
Ethyl alpha hydroxypropionate
Ethyl DL Lactate
ethyl DL-lactate
ETHYL LACTATE
Ethyl Lactate
Ethyl lactate
ethyl lactate
ethyl lactate
ethyl lactate;
Ethyllactat
Ethyl 2-hydroxypropanoate

Other names:
Ethyl lactate
Lactic acid ethyl ester
2-Hydroxypropanoic acid ethyl ester
Actylol
Acytol

Other identifiers:
2676-33-7
607-129-00-7
97-64-3
LACTIC ACID FOOD GRADE
Lactic Acid Food Grade is a colorless or yellowish liquid with the characteristic smell of sour milk.
Lactic Acid Food Grade is an organic acid involved in various biochemical processes.


CAS Number: 50-21-5
EC Number: 200-018-0
Molecular Formula: C3H6O3



SYNONYMS:
α-hydroxypropionic acid, or 2-hydroxypropanoic acid, Milk acid



Lactic Acid Food Grade is also used as a flavoring agent.
Lactic Acid Food Grade can be used as acidulant, flavoring agent and pH regulator in beverage, beer, fruit wine, meat, sourdough, salads, dressings, confectionery (such as hard- boiled candy, fruit gums) and pickled vegetables.


Lactic Acid Food Grade is also employed in pharmaceutical technology to produce water-soluble lactates from otherwise-insoluble active ingredients.
Lactic Acid Food Grade finds further use in topical preparations and cosmetics to adjust acidity and for its disinfectant and keratolytic properties.
Lactic Acid Food Grade is an organic acid occurring naturally in the human body and in fermented foods.


The commercial production of lactic acid is typically done by fermentation.
Lactic Acid Food Grade is an organic acid.
Lactic Acid Food Grade has the molecular formula CH3CHOOH.


In its solid state, Lactic Acid Food Grade is white and miscible with water.
When it is in its dissolved state, Lactic Acid Food Grade forms a colourless solution.
Naturally, Lactic Acid Food Grade occurs as a chemical byproduct of anaerobic respiration in humans, this is the process by which cells produce energy without oxygen.


Lactic Acid Food Grade is also produced by bacteria in yoghurts and is also found in blood, where it is deposited by muscle and red blood cells.
Industrially, Lactic Acid Food Grade is produced by the bacterial fermentation of carbohydrates; fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria.


There is another method of production, through the chemical synthesis from acetaldehyde.
This is done by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile.
Lactic Acid Food Grade can be used in pharmaceutical products because it produces water-soluble lactates from otherwise insoluble ingredients.


In the food industry, Lactic Acid Food Grade is found primarily in sour milk products, these include kumis, laban, yogurt, kefir, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade.
Lactic Acid Food Grade is also responsible for the sour flavour of sourdough bread.


Lactic Acid Food Grade is sourced from fermentation of plant sugars.
Lactic Acid Food Grade is a perfect for use in vegan cheese recipes.
Lactic Acid Food Grade adds a natural sour flavor to sourdough breads.


Lactic Acid Food Grade is an organic acid with applications in beer production as well as the cosmetic, pharmaceutical, food and chemical industries.
Lactic Acid Food Grade, also known as milk acid, is found primarily in sour milk products, such as yogurt, kefir, koumiss, laban, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade.


Lactic Acid Food Grade is also responsible for the sour flavor of sourdough breads.
As an ingredient in personal care products, Lactic Acid Food Grade has the ability to boost skin’s moisture levels—even as it exfoliates.
At higher concentrations, Lactic Acid Food Grade acts as an exfoliator helping to dissolve connections between skin cells, while at lower levels it is used as a humectant, meaning it can actually help hydrate skin by pulling in water to the outer skin layer.


Lactic Acid Food Grade is one of the popular food additives and ingredients in most countries.
Lactic Acid Food Grade is an organic acid that is naturally occurring in the human body and fermented foods.
Fermentation occurs when natural bacteria feed on the sugar and starch of a food, producing Lactic Acid Food Grade.


The process creates B-vitamins, beneficial enzymes, and more.
L(+) form is preferred for better metabolism and natural carbohydrates.
Lactic Acid Food Grade is a versatile ingredient used in the food industry as an acidity regulator and acidulant.


Lactic Acid Food Grade helps stabilize acidity, maintain pH levels, and prevent microbial contaminations.
Increase the shelf life of your dairy products, fermented preserves, processed meats, beverages, egg-based products, and infant foods with Lactic Acid Food Grade.


Not only does Lactic Acid Food Grade act as a preservative, but it also enhances the taste and aroma of your creations.
Lactic Acid Food Grade is an organic acid occurring naturally in the human body and in fermented foods.
The commercial production of Lactic Acid Food Grade is typically done by traditional fermentation of natural carbohydrates.


Lactic Acid Food Grade standard is produced from natural corn starch by advanced bio-fermentation and refining technology.
Lactic Acid Food Grade is a yellowish to colorless liquid, having a mild acid odor and taste.
Lactic Acid Food Grade is an organic compound with the formula CH3CH(OH)CO2H.


In its solid state, Lactic Acid Food Grade is white and water-soluble.
In its liquid state, Lactic Acid Food Grade is clear.
Lactic Acid Food Grade is produced both naturally and synthetically.


As a food additive Lactic Acid Food Grade is approved for use in the EU, USA and Australia and New Zealand; it is listed by its INS number 270 or as E number E270.
Lactic Acid Food Grade is produced commercially by fermentation of carbohydrates such as glucose, sucrose, or lactose, or by chemical synthesis.


Carbohydrate sources of Lactic Acid Food Grade include corn, beets, and cane sugar.
Lactic Acid Food Grade is an alpha hydroxy acid with both exfoliant and humectant properties.
Lactic Acid Food Grade is produced naturally in the body (it's the stuff that gives you a ‘stitch’ during a workout) and is also found in yogurt and milk.


Lactic Acid Food Grade may exist either as a white solid in pure form, or a clear to yellowish liquid when dissolved in water.
Lactic Acid Food Grade can be produced via fermentation of carbohydrates, or synthesized from acetaldehyde.
Produced from natural corn starch through the traditional fermentation of natural carbohydrates, Lactic Acid Food Grade is a highly versatile solution used in various food applications.


One of the critical benefits of Lactic Acid Food Grade is its ability to help control pH levels.
Balancing pH levels improves flavor and texture and ensures the final product is safe and stable.
Due to regulating and lowering pH levels, Lactic Acid Food Grade serves as a microbial inhibitor with the growth of potentially harmful bacteria.


As a highly effective preservative, Lactic Acid Food Grade can help to extend product shelf life and reduce the risk of spoilage or contamination.
Lactic Acid Food Grade is ideal for bakery, dairy, beverages, meat, and many other applications.
Lactic Acid Food Grade is non-GMO.


Lactic Acid Food Grade is a chemical compound classified as an organic acid.
Lactic Acid Food Grade is a type of carboxylic acid, specifically known as 2-hydroxypropanoic acid.
Lactic Acid Food Grade is produced in the body as a byproduct of anaerobic metabolism, primarily in muscle tissues, during periods of intense physical activity or when oxygen supply is limited.


Lactic Acid Food Grade plays a crucial role in energy production and can serve as an alternative energy source when glucose availability is reduced.
In terms of its chemical structure, Lactic Acid Food Grade consists of a three-carbon molecule with a hydroxyl group (-OH) and a carboxyl group (-COOH) attached to the second carbon.


Lactic Acid Food Grade exists in two stereoisomeric forms: L-lactic acid and D-lactic acid.
L-lactic acid is the most common and biologically active form found in humans.
Overall, Lactic Acid Food Grade is an important compound with diverse biological and industrial significance, contributing to various physiological processes and serving as a versatile chemical building block in numerous applications.


Industrially, Lactic Acid Food Grade is produced by the bacterial fermentation of carbohydrates; fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria.
There is another method of production, through the chemical synthesis from acetaldehyde.


This is done by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile.
Lactic Acid Food Grade, particularly in its food-grade form, has a variety of uses in the food and beverage industry.
Lactic Acid Food Grade is a natural organic acid produced through fermentation, often from sources like sugars and starches.


Lactic Acid Food Grade has a mild, tart flavor and is generally recognized as safe (GRAS) when used in food applications.
Lactic Acid Food Grade is an organic acid.
Lactic Acid Food Grade has the molecular formula CH3CHOOH.


In its solid state, Lactic Acid Food Grade is white and miscible with water.
When it is in its dissolved state, Lactic Acid Food Grade forms a colourless solution.
Lactic Acid Food Grade is an alpha hydroxy acid with both exfoliant and humectant properties.


Naturally, Lactic Acid Food Grade occurs as a chemical byproduct of anaerobic respiration in humans, this is the process by which cells produce energy without oxygen.
Lactic Acid Food Grade is also produced by bacteria in yoghurts and is also found in blood, where it is deposited by muscle and red blood cells.



USES and APPLICATIONS of LACTIC ACID FOOD GRADE:
Lactic Acid Food Grade is also used in a wide range of food applications such as bakery products, beverages, meat products, confectionery, dairy products, salads, dressings, ready meals, etc.
Lactic Acid Food Grade in food products usually serves as either as a pH regulator or as a preservative.


Lactic Acid Food Grade is produced from natural corn starch by advanced bio-fermentation and refining technology.
Lactic Acid Food Grade is a yellowish to colorless liquid, having a mild acid odor and taste.
Lactic Acid Food Grade is a carboxylic acid widely used as acidity regulator in food and beverage.


Lactic Acid Food Grade is able to preserve and flavor; however, that is not its only feature.
In the food industry Lactic Acid Food Grade is used as a preservative, acidity regulator, flavor enhancer and has an INS number of 270 or an E number of E270.


Lactic Acid Food Grade is used as a food preservative, hardener and flavoring.
Lactic Acid Food Grade is an ingredient in processed foods and is used in meat processing as a tenderiser and flavor enhancer.
Some beers (sour beers) deliberately contain added Lactic Acid Food Grade, one such type being Belgian lambics.


In most cases, Lactic Acid Food Grade in beer is produced from various bacterial strains.
These bacteria ferment sugars into acids, unlike yeasts which ferment sugars into ethanol.
Once the wort has cooled, the yeast and bacteria are allowed to 'fall' into the open fermenters.


Brewers of more conventional beers would ensure that such bacteria do not enter the fermenter.
Other styles of sour beer include 'Berliner weisse', 'Flanders red' and 'American wild ale'.
In wine production, natural malic acid is converted to Lactic Acid Food Grade to reduce spiciness and for other taste reasons, a natural or controlled bacterial process is often used.


If the bacterial action is unstable, additional Lactic Acid Food Grade is added to maintain stable product parameters.
In the washing industry, an antimicrobial agent, Lactic Acid Food Grade is used as a natural ingredient for descaling, which is natural and environmentally friendly.


Lactic Acid Food Grade is commonly found in organic descalers for coffee machines.
Many products can be found for the care of the skin of livestock (therapeutic ointments, disinfectants, post-milking teat wipes, pre-milking cleansers etc.).


Lactic Acid Food Grade is also used as a respiratory and acidity regulator, thus making feed more palatable and odorous and thus increasing the digestibility of feed.
Animals gain weight faster and produce more milk.


Lactic Acid Food Grade in animal nutrition is characterized by lowering the pH of the stomach, reducing the buffering properties of the feed, increasing the activity of proteolytic enzymes/improving the secretion of pancreatic secretions, stimulating the activity of digestive enzymes, stimulating the growth of beneficial bacterial growth, reducing the survival of pathogens in the stomach/maintaining the balance of microbial populations, and directly killing bacteria.


Lactic Acid Food Grade is also found as a nutritional additive for livestock, which improves the digestion of herbivorous animals, as the acid helps to ferment feed faster.
Lactic Acid Food Grade is widely used in brewing to adjust pH In the mash in small quantities to adjust the room temperature mash to 5.4-5.6 range.


Lactic Acid Food Grade is also used in beer making, wine production and as a food additive.
Lactic Acid Food Grade is naturally present in many foodstuffs.
Lactic Acid Food Grade is formed by natural fermentation in products such as cheese, yogurt, soy sauce, sourdough, meat products and pickled vegetables.


Lactic Acid Food Grade is also used in a wide range of food applications such as bakery products, beverages, meat products, confectionery, dairy products, salads, dressings, ready meals, etc.
Lactic Acid Food Grade in food products usually serves as either as a pH regulator or as a preservative.


Lactic Acid Food Grade is also used as a flavouring agent.
Meat, Poultry & Fish: Lactic Acid Food Grade can be used in meat, poultry and fish in the form of sodium or potassium lactate to extend shelf life, control pathogenic bacteria (improve food safety), enhance and protect meat flavour, improve water binding capacity and reduce sodium.


Beverages uses of Lactic Acid Food Grade: Because of its mild taste, Lactic Acid Food Grade is used as an acidity regulator in beverages such as soft drinks and fruit juices.
Lactic Acid Food Grade is widely used in brewing to adjust pH In the mash in small quantities to adjust the room temperature mash to 5.4-5.6 range.


Lactic Acid Food Grade commonly used as a pH modifier in beer brewing.
Lactic Acid Food Grade is used in beer brewing to lower the pH and increase the body of the beer.
Lactic Acid Food Grade is also used in various beverages and cocktails to impart a sour taste.


Lactic Acid Food Grade is commonly used as a preservative and antioxidant.
Lactic Acid Food Grade also has uses as a fuel additive, chemical intermediate, acidity regulator, and disinfectant.
Lactic Acid Food Grade is used frequently in the cosmetic industry due to the effect of promoting collagen production, helping to firm the skin against wrinkles and sagging.


Lactic Acid Food Grade can also cause micro peeling, which can help reduce various scars and age spots.
Lactic Acid Food Grade is a great solution for people with sensitive or dry skin where exfoliants don’t work.
Lactic Acid Food Grade is used for food and personal care products.


Lactic Acid Food Grade can be used as acidulant, flavoring agent and pH regulator in beverages, meat, sourdough, salads and dressings, confectionery and pickled vegetables.
Lactic Acid Food Grade is used as in acidification agent for beverages.


Lactic Acid Food Grade is used as a preservative and flavoring in dressings and salads.
Lactic Acid Food Grade is used in fermentation and pH regulator in beer, wine, and spirits.
Lactic Acid Food Grade is used as in antimicrobial agent and shelf life extender in bakery, meat products.


Lactic Acid Food Grade is food grade and is used for the production of several types of cheeses.
Lactic Acid Food Grade is particularly useful when UHT, ultra-pasteurised or powdered milk are used as the starting materials, since the heat treatments used in the production of these milks deactivates the lactose and prevents the cheese culture from being able to turn it fully into lactic acid.


The inclusion of additional lactic acid prior to rennetting overcomes this shortage and improves the curd yield.
Lactic Acid Food Grade is a vital ingredient in Ricotta Impastata, Mozzarella, Queso Blanco and other speciality cheeses and can be used in the production of sour milk products, such as Koumiss, Laban, Kefir, as well as some cottage cheeses.


In production, Lactic Acid Food Grade is usually added so that the pH of the milk reaches around 5.0.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade and it is also responsible for the sour flavour of sourdough breads.
Lactic Acid Food Grade is responsible for the tangy flavor of fermented milk products (e.g. yogurt, kefir), sour beers, and sourdough bread.


Fermentation usually results in the racemate, although some fermenting bacteria produce the D-enantiomer only.
In winemaking, some wines may go through a natural or induced process called malolactic fermentation, which converts malic acid to Lactic Acid Food Grade, to reduce the sharpness of the acidity.


Given its prevalence in nature, Lactic Acid Food Grade is useful for manipulating food chemistry, and is therefore a common additive.
Lactic Acid Food Gradev may be used as a preservative, an acidifier, a dairy culturing agent, or an ingredient in infant formulas.
Lactic Acid Food Grade may also be used in pharmaceuticals and cosmetics as a preservative and acidifier, and in contraceptive jellies as an active ingredient.


Lactic Acid Food Grade is used as a food preservative, curing agent, and flavoring agent.
Lactic Acid Food Grade is an ingredient in processed foods and is used as a decontaminant during meat processing.
Lactic Acid Food Grade has several industrial applications, including its use in food production, pharmaceuticals, and cosmetics.


Lactic Acid Food Grade is often utilized as a preservative, flavoring agent, pH regulator, and moisturizer.
Lactic Acid Food Grade is also employed in various chemical processes, such as the production of biodegradable plastics and environmentally friendly solvents.


Lactic Acid Food Grade is a natural organic acid with a long history of food, leather, wood-dyeing, and cosmetic industries.
Lactic Acid Food Grade was formed by natural fermentation in products such as cheese, yogurt, soy sauce, meat products, pickled vegetables, beer, and wine.
Lactic Acid Food Grade is used as pH regulator in Pharma products, used in nickel plating because of its unique complexion constant for the nickel.


Lactic Acid Food Grade is used Preservative, Dairy culturing agent, Contraceptive jellies, Acidifier, Pharmaceutical ingredient, and Cosmetic ingredient.
Lactic Acid Food Grade has the dual characteristics of Lactic acid and Calcium lactate, which not only possesses mild and lasting sourness of lactic acid, but also an excellent source of calcium.


Because Lactic Acid Food Grade is powder product so it's especially suitable for regulating the acidity and sourness of various kinds of solid food.
Meanwhile because the good ability of bacteriostasis and fresh-keeping, Lactic Acid Food Grade can be used to extend product's shelf life.
Lactic Acid Food Grade is widely used in candy, canned food, bread and other solid foods.


Lactic Acid Food Grade is a colorless transparent liquid that can be mixed with water.
Lactic Acid Food Grade is widely used in applications such as baking and beer.
Lactic Acid Food Grade, in its food-grade form, is commonly used in the food and beverage industry for various purposes.


Lactic Acid Food Grade can also be used as a flavoring agent.
Lactic Acid Food Grade can help stimulate collagen and strengthen the skin, which equals fewer fine lines and wrinkles.
The hydroxy acids exfoliate the top layer of skin, helping smooth and even complexion, keep pores unclogged, brighten skin and even fade dark marks and discoloration.


Pickling: Lactic Acid Food Grade is used in the pickling process to create a sour flavor and lower the pH of pickled vegetables like cucumbers.
Cheese Making: In cheese production, Lactic Acid Food Grade bacteria are used to ferment milk and produce the acidity required for curd formation and flavor development.


Marinades and Sauces: Lactic Acid Food Grade is used in marinades and sauces for meats and seafood to enhance flavor and tenderness.
Fruit Juices: Lactic Acid Food Grade can be added to fruit juices to adjust acidity levels and improve the taste of citrus and other fruit-based beverages.
Confections: Lactic Acid Food Grade is used in the production of confectionery items like gummies and sour candies to provide a sour and tangy flavor.


Fermentation: Lactic Acid Food Grade bacteria are employed in the fermentation of various foods, such as sauerkraut, kimchi, and sourdough bread.
Sports and Energy Drinks: Lactic Acid Food Grade or its salts are added to sports and energy drinks to provide a mild acidity and enhance the flavor profile.


Preservative: Lactic Acid Food Grade and its salts, such as sodium lactate, can help extend the shelf life of certain food products by lowering the pH and creating an environment that inhibits the growth of spoilage microorganisms.
Flavor Enhancer: Lactic Acid Food Grade is used as a flavor enhancer in various foods, including dairy products, candies, and soft drinks, to impart a mildly tangy taste.


pH Regulator: Lactic Acid Food Grade can be used to regulate the pH of certain food products, especially in the dairy industry, to improve product stability.
Lactic Acid Food Grade can be used in pharmaceutical products because it produces water-soluble lactates from otherwise insoluble ingredients.


Lactic Acid Food Grade has many uses and is produced by bacterial fermentation of carbohydrates such as sugars and starches.
In the food industry, Lactic Acid Food Grade is found primarily in sour milk products, these include kumis, laban, yogurt, kefir, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade.


Lactic Acid Food Grade is also responsible for the sour flavour of sourdough bread.
Lactic Acid Food Grade is also used in beer making, wine production and as a food additive.
Lactic Acid Food Grade is also used to adjust the pH level in foods and beverages.


Lactic Acid Food Grade is a natural preservative and is commonly used to preserve dairy products, such as cheese, yogurt, and sour cream, as well as canned fruits and vegetables.
Lactic Acid Food Grade can be used to produce a tart or sour flavor in foods and beverages and can be used to add a unique flavor to craft beer.
Lactic Acid Food Grade is used as a flavoring agent and preservative in processed cheese, salad dressings, pickles, and carbonated beverages.


Lactic Acid Food Grade is also used as a raw material or a catalyst in numerous chemical processes.
Lactic Acid Food Grade is widely used as acidulants and preservatives in food and beverage industries.
Lactic Acid Food Grade is an organic acid that is used as a preservative in food products and as an additive in beverages.


-Acidulant:
Lactic Acid Food Grade is used as an acidulant to adjust the pH level and provide a tangy or sour flavor in various food products.
Lactic Acid Food Grade's commonly used in salad dressings, condiments, and beverages to enhance taste.


-Bakery Products: In baking, Lactic Acid Food Grade is used as a dough conditioner to enhance the texture, rise, and shelf life of bread and other baked goods.
Lactic Acid Food Grade can also contribute to the browning of bread crusts.


-Dairy Products:
Lactic Acid Food Grade is naturally present in fermented dairy products such as yogurt, kefir, and buttermilk.
Lactic Acid Food Grade contributes to the tangy flavor and the thickening of these products.


-Meat and Poultry:
Lactic Acid Food Grade can be used to reduce microbial load and enhance food safety in meat and poultry products.
Lactic Acid Food Grade is sometimes applied as a surface treatment or spray to reduce the risk of bacterial contamination.


-Flavoring and pH regulation:
Lactic Acid Food Grade is employed as a natural flavoring agent and pH regulator in a wide range of food and beverage products.
Lactic Acid Food Grade imparts a tangy or sour taste, similar to the flavor of yogurt or sourdough bread.


-Food preservation:
Lactic Acid Food Grade exhibits antimicrobial properties, and its use as a food preservative helps inhibit the growth of harmful bacteria, molds, and yeasts.
Lactic Acid Food Grade can extend the shelf life of processed foods and prevent spoilage.


-Acidification:
Lactic Acid Food Grade is utilized to acidify and adjust the pH of certain foods and beverages.
Lactic Acid Food Grade is particularly valuable in fermented products such as sauerkraut, pickles, kimchi, and yogurt, where it contributes to the characteristic acidity and tanginess.


-Dairy products:
Lactic Acid Food Grade plays a vital role in the production of various dairy products.
Lactic Acid Food Grade is used in cheese making to facilitate curd formation and enhance the texture, flavor, and shelf life of cheeses.
Lactic Acid Food Grade bacteria are also employed in the fermentation of milk to produce yogurt and cultured buttermilk.


-Meat and poultry processing:
Lactic Acid Food Grade is employed as an antimicrobial treatment in the processing of meat and poultry products.
Lactic Acid Food Grade can help reduce bacterial contamination and enhance food safety.


-Bakery products:
Lactic Acid Food Grade is utilized in the baking industry to regulate dough fermentation and improve the texture and volume of baked goods.
Lactic Acid Food Grade contributes to the development of a desirable crumb structure and imparts a mild tangy flavor.


-Beverages:
Lactic Acid Food Grade finds applications in the production of various beverages, including fruit juices, soft drinks, and alcoholic beverages.
Lactic Acid Food Grade helps adjust acidity levels, improve flavor profiles, and act as a natural preservative.
It is important to note that Lactic Acid Food Grade is generally recognized as safe (GRAS) by regulatory authorities when used in accordance with the approved levels and good manufacturing practices.



SPECIFICATIONS OF LACTIC ACID FOOD GRADE:
Lactic Acid Food Grade is affirmed GRAS by the FDA.
Lactic Acid Food Grade is also certified 21 CFR 184.1061.
Lactic Acid Food Grade does not use genetically modified microorganism for fermentation.
Lactic Acid Food Grade is Kosher under the Orthodox Union and Halal certified.



CHARACTERISTICS OF LACTIC ACID FOOD GRADE:
Lactic Acid Food Grade is a mild-tasting acidity regulator, flavor enhancer, and shows antibacterial properties.
Lactic Acid Food Grade is colorless to yellowish, nearly odorless, and has a syrupy texture.
Lactic Acid Food Grade is an aqueous solution stable under normal conditions and has a pH (50%) value of less than 2 at 25°C.
Lactic Acid Food Grade is easily biodegradable and should not be in environments warmer than 200°C.



PHYSICAL and CHEMICAL PROPERTIES of LACTIC ACID FOOD GRADE:
Odor: odorless
Melting point/freezing point:
Melting point: 18 °C at 1.013 hPa
Initial boiling point and boiling range: 122 °C at 18,66 - 19,99 hPa
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits: No data available
Flash point: 113 °C - closed cup
Autoignition temperature: 400 °C at 1.011,4 - 1.018,9 hPa
Decomposition temperature: No data available
pH: No data available
Molecular Formula: CH3CHOHCOOH.
Molecular Weight: 90.08 g/mol.

Boiling point: 122 °C.
Melting point: 16.8 °C.
Viscosity
Viscosity, kinematic: No data available
Viscosity, dynamic: No data available
Water solubility: 100 g/l at 20 °C - soluble
Partition coefficient: n-octanol/water:
log Pow: ca.-0,54 at 25 °C - Bioaccumulation is not expected.
Vapor pressure: No data available
Density: 1,25 g/cm3 at 15 °C
Relative density: No data available
Relative vapor density: No data available
Particle characteristics: No data available
Explosive properties: No data available

Oxidizing properties: none
Other safety information:
Surface tension 70,7 mN/m at 1g/l at 20 °C
Formula: H₃CCH(OH)COOH
MW: 90.08 g/mol
Boiling Pt: 122 °C (20 hPa)
Density: 1.11…1.21 g/cm³ (20 °C)
Storage Temperature: Ambient
MDL Number: MFCD00004520
CAS Number: 50-21-5
EINECS: 200-018-0
CAS: 50-21-5
MF: C3H6O3
MW: 90.08
EINECS: 200-018-0

Mol File: 50-21-5.mol
Lactic acid Chemical Properties
Melting point: 18°C
alpha: -0.05 º (c= neat 25 ºC)
Boiling point: 122 °C/15 mmHg (lit.)
density: 1.209 g/mL at 25 °C (lit.)
vapor density: 0.62 (vs air)
vapor pressure: 19 mm of Hg (@ 20°C)
FEMA: 2611 | LACTIC ACID
refractive index: n20/D 1.4262
Fp: >230 °F
storage temp.: 2-8°C

solubility: Miscible with water and with ethanol (96 per cent).
form: syrup
pka: 3.08(at 100℃)
Specific Gravity: 1.209
color: Colorless to yellow
Water Solubility: SOLUBLE
Merck: 145,336
JECFA Number: 930
BRN: 1209341
Stability: Stable.
Physical state: viscous
Color: colorless
Chemical Name : 2-hydroxy – propanoic acid
Molecular Weight : 90.08

Stereochemical purity (L isomer) Min 97.0 %
Content Min 80.0 %
Colour Fresh : Max 100 Apha
Appearance: Colorless to yellow.
Assay: 80 to 88%.
Also known as: Milk acid.
CAS No: 50-21-5.
Density: 1.206 g/ml.
Grade Standard: Commercial, Food Grade.
Molecular Formula: C3H6O3.
Molecular Weight: 90.078 g·mol−1.
Physical State: Liquid.
Usage: Food, Pharma Synthesis.
Chemical Name: L(S)-2-hydroxypropionic acid.



FIRST AID MEASURES of LACTIC ACID FOOD GRADE:
-Description of first-aid measures:
*General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LACTIC ACID FOOD GRADE:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up with liquid-absorbent material.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of LACTIC ACID FOOD GRADE:
-Extinguishing media:
*Suitable extinguishing media:
Water
Foam
Carbon dioxide (CO2)
Dry powder
*Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LACTIC ACID FOOD GRADE:
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles
*Body Protection:
protective clothing
*Respiratory protection
Recommended Filter type: Filter type ABEK
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LACTIC ACID FOOD GRADE:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.



STABILITY and REACTIVITY of LACTIC ACID FOOD GRADE:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Possibility of hazardous reactions:
No data available.
-Incompatible materials:
No data available


LACTIC ACID FOOD GRADE

Lactic Acid (food grade) is an organic acid that occurs naturally in various food products and is commonly used as a preservative, flavoring agent, and acidulant in the food and beverage industry.
Lactic Acid food grade is known for its sour taste and is found in fermented products such as yogurt, sauerkraut, and pickles.

CAS Number: 50-21-5
EC Number: 200-018-0

Synonyms: Lactic acid, Milk acid, 2-Hydroxypropanoic acid, α-Hydroxypropionic acid, Lactate, 2-Hydroxypropionic acid, 2-Hydroxypropanoate, 2-Hydroxypropionate, Ethylidene-lactic acid, Lactic acid, 2-hydroxy-1-propanecarboxylic acid, L-Lactic acid, (S)-Lactic acid, DL-Lactic acid, (±)-Lactic acid, Lactobacillic acid, 2-Hydroxypropanoic acid, (R)-, Acesol, Racemic lactic acid, D-(-)-Lactic acid, Lactic acid, (R)-, E270, Lactic acid, L-, α-Hydroxypropionic acid, (R)-, Corilagin, Lactic acid, (S)-, Lactic acid, (R)-, Corilaginic acid, Hydroxypropionic acid, (R)-, D-(-)-Lactic acid, L-Lactic acid, (S)-, Lactic acid, (S)-, α-Hydroxypropanoic acid, (S)-, Lactic acid, (S)-, L-, Lactic acid, (R)-, 2-Hydroxypropanoic acid, Lactic acid, (R)-, 2-Hydroxypropanoic acid, (R)-, DL-Lactic acid, Lactic acid, DL-, Lactic acid, (±)-, DL-2-Hydroxypropanoic acid, Lactic acid, (±)-, 2-Hydroxypropanoic acid, DL-, L-Lactic acid, Lactic acid, L-, Lactic acid, (S)-, D-(-)-Lactic acid, (S)-Lactic acid, Lactic acid, (S)-, L-, (S)-Lactic acid, Lactate, DL-, Lactic acid, L-(+)-, Lactic acid, (R)-, Hydroxypropionic acid, (S)-, Lactic acid, D-(-)-, Lactic acid, D-(-)-, 2-Hydroxypropanoic acid, D-(-)-, Lactic acid, (S)-, 2-Hydroxypropanoic acid, Lactic acid, (S)-, D-(-)-Lactic acid, 2-Hydroxypropanoic acid, Lactic acid, D-(-)-, Lactic acid, (S)-, DL-Lactic acid, 2-Hydroxypropanoic acid, DL-Lactic acid, Lactic acid, DL



APPLICATIONS


Lactic Acid food grade is extensively used in the food and beverage industry as an acidulant and flavor enhancer.
Lactic Acid food grade is commonly found in dairy products such as yogurt, cheese, and sour cream, contributing to their tart flavor.

Lactic Acid food grade is used in the fermentation of vegetables like sauerkraut and pickles, aiding in preservation and flavor development.
In the baking industry, lactic acid is added to doughs to improve texture and extend shelf life.

Lactic Acid food grade is used as a pH regulator and preservative in various processed foods, including meats, sauces, and dressings.
Lactic Acid food grade is employed in the production of beverages such as beer, cider, and soft drinks for its sour taste.

In the pharmaceutical industry, lactic acid is used as an excipient in drug formulations, particularly oral solutions and intravenous fluids.
Lactic Acid food grade is utilized in the manufacture of cosmetics and personal care products as an exfoliant and moisturizing agent.
Lactic Acid food grade is incorporated into skin care products like creams, lotions, and peels to promote skin renewal and hydration.

In agriculture, lactic acid is added to animal feed to improve digestion and enhance nutrient absorption in livestock.
Lactic Acid food grade is used in the production of biodegradable plastics such as polylactic acid (PLA), which is derived from renewable resources.
Lactic Acid food grade is employed in the textile industry for textile dyeing and finishing processes, acting as a pH regulator and color fixative.

Lactic Acid food grade is used in the cleaning and detergent industry for its descaling and antimicrobial properties.
Lactic Acid food grade is added to household cleaning products like bathroom cleaners and dishwashing detergents for effective stain removal.
In the medical field, lactic acid is used as a component of wound dressings and topical medications for its antimicrobial properties.

Lactic Acid food grade is used in the production of biodegradable polymers for medical implants and drug delivery systems.
Lactic Acid food grade is employed in the synthesis of lactate-based polymers used in tissue engineering and regenerative medicine.

Lactic Acid food grade is used in the manufacture of biodegradable packaging materials, reducing the environmental impact of packaging waste.
Lactic Acid food grade is utilized in the production of biodegradable solvents and lubricants as an eco-friendly alternative to petroleum-based products.

Lactic Acid food grade is employed in the production of biodegradable detergents and surfactants for use in household and industrial cleaning applications.
Lactic Acid food grade is used in the leather industry for leather tanning and finishing processes, enhancing the quality and durability of leather goods.
Lactic Acid food grade is employed in the production of adhesives and sealants for its adhesive properties and moisture resistance.
Lactic Acid food grade is utilized in the printing and paper industry for paper sizing and coating applications, improving print quality and durability.

Lactic Acid food grade is added to personal care products such as toothpaste and mouthwash for its tart flavor and antibacterial properties.
Lactic Acid food grade finds applications in a wide range of industries, from food and beverages to pharmaceuticals, cosmetics, and beyond, owing to its diverse functional properties and eco-friendly nature.

Lactic Acid food grade is used in the production of biodegradable plastics for packaging materials, reducing plastic pollution and environmental impact.
Lactic Acid food grade is employed in the textile industry for dyeing and finishing processes to improve color fastness and fabric softness.
Lactic Acid food grade is added to skincare products such as serums and masks to exfoliate dead skin cells and promote a radiant complexion.

In the automotive industry, lactic acid is used in the production of biodegradable lubricants and antifreeze solutions.
Lactic Acid food grade is employed in the manufacturing of dietary supplements and sports nutrition products to support muscle recovery and endurance.

Lactic Acid food grade is utilized in the fermentation of probiotic supplements and cultured dairy products for its beneficial effects on gut health.
Lactic Acid food grade is added to pet care products such as shampoos and grooming sprays for its skin-conditioning properties.
Lactic Acid food grade is used in the production of biofuels such as ethanol and biodiesel as a fermentation substrate.

In the construction industry, lactic acid is used in the production of eco-friendly concrete additives and sealants.
Lactic Acid food grade is employed in the pharmaceutical industry as a chelating agent in metal ion complexation and drug delivery systems.

Lactic acid is used in the production of biodegradable detergents for household and industrial cleaning applications.
Lactic Acid food grade is employed in the treatment of industrial wastewater for its ability to neutralize pH and remove heavy metals.
Lactic Acid food grade is used in the preservation of fresh produce and seafood to extend shelf life and maintain quality.

Lactic Acid food grade is added to cosmetic formulations such as hair care products and deodorants for its antimicrobial and odor-neutralizing properties.
Lactic Acid food grade is used in the production of biodegradable inks and coatings for printing and packaging applications.
Lactic Acid food grade is employed in the manufacturing of eco-friendly pesticides and herbicides for agricultural pest control.

Lactic Acid food grade is added to animal feed as a feed additive to improve digestion and nutrient absorption in livestock.
Lactic Acid food grade is used in the production of biodegradable cleaning wipes and disinfectants for household and industrial use.

Lactic Acid food grade is employed in the production of biodegradable polymers for 3D printing and additive manufacturing.
Lactic Acid food grade is added to oral care products such as mouthwashes and toothpaste for its tart flavor and antimicrobial properties.
Lactic Acid food grade is used in the production of biodegradable film and packaging materials for food and pharmaceutical applications.

Lactic Acid food grade is employed in the production of biodegradable detergents and degreasers for automotive and industrial cleaning.
Lactic Acid food grade is used in the production of biodegradable fertilizers and soil conditioners for sustainable agriculture.
Lactic Acid food grade is added to fermentation media for the production of biopharmaceuticals and bio-based chemicals.



DESCRIPTION


Lactic Acid (food grade) is an organic acid that occurs naturally in various food products and is commonly used as a preservative, flavoring agent, and acidulant in the food and beverage industry.
Lactic Acid food grade is known for its sour taste and is found in fermented products such as yogurt, sauerkraut, and pickles.

Lactic Acid food grade is a colorless to slightly yellow, viscous liquid.
Lactic Acid food grade has a mild, characteristic odor and a sour taste.
Lactic Acid food grade is naturally present in various fermented foods such as yogurt, cheese, and sauerkraut.

Lactic Acid food grade plays a crucial role in the fermentation process, contributing to the tangy flavor of fermented products.
The chemical formula of lactic acid is C3H6O3, and its molecular weight is 90.08 g/mol.
Lactic Acid food grade is classified as a weak organic acid due to its relatively low acidity.

Lactic Acid food grade is soluble in water and miscible with ethanol, acetone, and glycerol.
Lactic acid is commonly used as a food additive in the form of its sodium or calcium salts (lactates).

In the body, lactic acid is produced during anaerobic metabolism, especially during strenuous exercise.
Lactic Acid food grade serves as an important energy source for muscles and tissues during periods of high activity.

Lactic Acid food grade is biodegradable and environmentally friendly, making it suitable for various applications.
Lactic Acid food grade is used as a pH regulator, acidulant, and preservative in the food and beverage industry.

Lactic Acid food grade contributes to the texture, flavor, and shelf life of many food products.
In cosmetics and personal care products, lactic acid is used as an exfoliant and moisturizing agent.
Lactic Acid food grade helps to promote skin renewal and improve skin hydration.

Lactic Acid food grade is also utilized in the pharmaceutical industry as an excipient in drug formulations.
Lactic Acid food grade can be found in topical medications, oral solutions, and intravenous fluids.
Lactic Acid food grade has antimicrobial properties, making it effective in inhibiting the growth of bacteria and fungi.
In agriculture, lactic acid is used as a feed additive to promote digestion and improve animal health.

Lactic Acid food grade is also employed in cleaning products and detergents for its descaling and antibacterial properties.
Lactic Acid food grade is produced industrially through fermentation or chemical synthesis.
Lactic Acid food grade is an important raw material for the production of polylactic acid (PLA), a biodegradable polymer.

Lactic Acid food grade is recognized as Generally Recognized as Safe (GRAS) by the Food and Drug Administration (FDA).
Lactic Acid food grade has a wide range of applications across various industries, including food, pharmaceuticals, cosmetics, and agriculture.
Lactic Acid food grade is a versatile compound with diverse uses and beneficial properties in numerous applications.



PROPERTIES


Physical Properties:

Appearance: Clear to slightly yellow, viscous liquid
Odor: Mild, characteristic odor
Taste: Sour
Density: 1.21 g/cm³ at 20°C
Melting Point: 16.8°C (solidifies below this temperature)
Boiling Point: 122°C at 15 mmHg (decomposes at higher temperatures)
Solubility in Water: Miscible in all proportions
Solubility in Other Solvents: Soluble in ethanol, acetone, and glycerol
pH: Typically around 2.0-3.0 for a 1% aqueous solution
Hygroscopicity: Exhibits some hygroscopic properties, absorbing moisture from the air
Refractive Index: 1.37
Viscosity: Relatively high viscosity as a liquid


Chemical Properties:

Chemical Formula: C3H6O3
Molecular Weight: 90.08 g/mol
Functional Groups: Hydroxyl group (-OH), Carboxyl group (-COOH)
Acid Strength: Weak organic acid with a pKa value of approximately 3.86
Hydrophilicity: Highly hydrophilic due to the presence of hydroxyl and carboxyl groups
Chirality: Exists as both L-lactic acid and D-lactic acid enantiomers, with L-lactic acid being the naturally occurring form
Optical Activity: Exhibits optical activity due to its chiral nature
Isomerization: Can undergo isomerization between the L- and D-forms under certain conditions
Decomposition: Decomposes at elevated temperatures, producing carbon dioxide and water
Polymerization: Can undergo polymerization to form polylactic acid (PLA) under appropriate conditions
Reactivity: Participates in esterification, transesterification, and condensation reactions
Hydrolysis: Undergoes hydrolysis in aqueous solutions to form lactate ions and protons



FIRST AID


Inhalation:

Move to Fresh Air:
Immediately remove the affected person from the contaminated area to an area with fresh air.

Assess Breathing:
Check the person's breathing. If breathing is difficult or absent, seek medical attention immediately.

Provide Oxygen:
If breathing is difficult, provide oxygen if available and trained to do so.

Keep Warm and Rested:
Keep the affected person warm and in a resting position until medical help arrives.


Skin Contact:

Remove Contaminated Clothing:
Quickly and gently remove any contaminated clothing, jewelry, or footwear.

Flush with Water:
Rinse the affected area thoroughly with lukewarm water for at least 15 minutes, ensuring complete removal of the chemical.

Use Mild Soap:
Wash the affected area with mild soap and water to remove any residual chemical.

Seek Medical Attention:
If irritation, redness, or other symptoms develop, seek medical advice promptly.

Apply Emollient:
After rinsing, apply a soothing emollient or moisturizer to the affected area to help soothe irritation and promote healing.

Monitor for Symptoms:
Monitor the affected area for any signs of blistering, swelling, or prolonged irritation, and seek medical attention if necessary.


Eye Contact:

Flush Eyes Immediately:
Immediately flush the affected eye(s) with gently flowing lukewarm water for at least 15 minutes, keeping eyelids open.

Remove Contact Lenses:
If present and easily removable, remove contact lenses after the initial flush.

Continue Flushing:
Continue to flush the eye(s) with water, ensuring thorough rinsing of the eye(s) and eyelids.

Seek Medical Attention:
Seek immediate medical attention, even if symptoms seem minor or if irritation persists after rinsing.

Do Not Rub Eyes:
Avoid rubbing or applying pressure to the eyes, as this may exacerbate irritation or injury.

Protect the Eye:
Cover the affected eye with a clean, sterile dressing or bandage to prevent further contamination or injury.


Ingestion:

Do NOT Induce Vomiting:
Do not induce vomiting unless instructed to do so by medical personnel.

Do NOT Give Anything by Mouth:
Do not give anything by mouth to an unconscious person.

Rinse Mouth:
If the person is conscious and able to swallow, rinse their mouth with water and encourage them to drink water slowly.

Seek Medical Attention:
Seek immediate medical attention or contact a poison control center for further guidance.

Monitor for Symptoms:
Monitor the person for symptoms such as nausea, vomiting, abdominal pain, difficulty swallowing, or other signs of ingestion.



HANDLING AND STORAGE

Handling:

Personal Protective Equipment (PPE):
Wear appropriate personal protective equipment (PPE), including safety goggles, chemical-resistant gloves, and a lab coat or protective clothing, when handling lactic acid.
Ensure that all PPE is properly fitted and in good condition before use.

Avoid Contact:
Avoid skin and eye contact with lactic acid. In case of contact, follow the first aid measures outlined in the SDS (Safety Data Sheet) or chemical label.

Use in Well-Ventilated Areas:
Handle lactic acid in well-ventilated areas to prevent the buildup of vapors or fumes. Use local exhaust ventilation if available.

Prevent Spills and Leaks:
Take precautions to prevent spills and leaks during handling and transfer of lactic acid. Use spill containment measures such as secondary containment trays or spill kits.

Avoid Mixing with Incompatible Substances:
Do not mix lactic acid with strong oxidizing agents, strong bases, or other incompatible substances. Refer to the SDS for a list of incompatible materials.

Use Proper Equipment:
Use appropriate equipment such as chemical-resistant pumps, hoses, and containers for handling and transferring lactic acid.

Labeling:
Ensure that containers of lactic acid are properly labeled with the appropriate product name, concentration, hazard warnings, and handling instructions.


Storage:

Store in Cool, Dry Area:
Store containers of lactic acid in a cool, dry, well-ventilated area away from heat sources and direct sunlight.
Maintain storage temperatures within the recommended range specified on the SDS or chemical label.

Avoid Temperature Extremes:
Avoid exposure to extreme temperatures.
Do not allow lactic acid to freeze, as it may solidify at low temperatures.

Keep Containers Tightly Closed:
Keep containers of lactic acid tightly closed when not in use to prevent contamination and evaporation of the chemical.

Separate from Incompatible Substances:
Store lactic acid away from incompatible substances such as strong oxidizing agents, strong bases, and reactive metals.

Store Away from Food and Feedstuffs:
Do not store lactic acid near food, feedstuffs, or food preparation areas to prevent accidental contamination.

Store Away from Reactive Materials:
Keep lactic acid containers away from reactive materials, combustible materials, and sources of ignition to prevent fire or explosion hazards.

Check for Leaks and Damage:
Regularly inspect containers for signs of leaks, damage, or deterioration. Replace damaged containers promptly to prevent spills or accidents.

Follow Local Regulations:
Adhere to local regulations and guidelines for the storage of lactic acid, including any specific requirements for hazardous chemicals in your region.

LACTIC ACID FOOD GRADE
Lactic Acid Food Grade is an organic acid.
Lactic Acid Food Grade has the molecular formula CH3CHOOH.


CAS Number: 50-21-5
EC Number: 200-018-0
Molecular Formula: C3H6O3



SYNONYMS:
α-hydroxypropionic acid, or 2-hydroxypropanoic acid, Milk acid



Lactic Acid Food Grade is a natural preservative often found in foods like yogurt, baked goods, and pickled vegetables.
Along with making your food last longer, Lactic Acid Food Grade can boost your health by strengthening your immune system.
Lactic Acid Food Grade is an organic acid that forms when certain foods go through the process of fermentation.


Lactic Acid Food Grade’s often found in pickled foods, fermented soy products, salami, yogurt, and more.
Food manufacturers add Lactic Acid Food Grade to packaged food products such as bread, desserts, olives, and jams to give them longer shelf lives.
Lactic Acid Food Grade is a good preservative because it can kill and suppress bacteria in food.


Lactic Acid Food Grade also helps prevent discoloration and works as a gelling agent and a curing agent.
Lactic Acid Food Grade is also employed in pharmaceutical technology to produce water-soluble lactates from otherwise-insoluble active ingredients.
Lactic Acid Food Grade finds further use in topical preparations and cosmetics to adjust acidity and for its disinfectant and keratolytic properties.


Lactic Acid Food Grade is an organic acid occurring naturally in the human body and in fermented foods.
The commercial production of lactic acid is typically done by fermentation.
Lactic Acid Food Grade is an organic acid.


Lactic Acid Food Grade has the molecular formula CH3CHOOH.
In its solid state, Lactic Acid Food Grade is white and miscible with water.
When it is in its dissolved state, Lactic Acid Food Grade forms a colourless solution.


Naturally, Lactic Acid Food Grade occurs as a chemical byproduct of anaerobic respiration in humans, this is the process by which cells produce energy without oxygen.
Lactic Acid Food Grade is also produced by bacteria in yoghurts and is also found in blood, where it is deposited by muscle and red blood cells.


Industrially, Lactic Acid Food Grade is produced by the bacterial fermentation of carbohydrates; fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria.
Lactic Acid Food Grade is a colorless or yellowish liquid with the characteristic smell of sour milk.


Lactic Acid Food Grade is an organic acid involved in various biochemical processes.
Lactic Acid Food Grade is also used as a flavoring agent.
Lactic Acid Food Grade can be used as acidulant, flavoring agent and pH regulator in beverage, beer, fruit wine, meat, sourdough, salads, dressings, confectionery (such as hard- boiled candy, fruit gums) and pickled vegetables.


Lactic Acid Food Grade is an organic acid with applications in beer production as well as the cosmetic, pharmaceutical, food and chemical industries.
Lactic Acid Food Grade, also known as milk acid, is found primarily in sour milk products, such as yogurt, kefir, koumiss, laban, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade.


The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade.
Lactic Acid Food Grade is also responsible for the sour flavour of sourdough bread.
Lactic Acid Food Grade is sourced from fermentation of plant sugars.


Lactic Acid Food Grade is a perfect for use in vegan cheese recipes.
Lactic Acid Food Grade adds a natural sour flavor to sourdough breads.
Lactic Acid Food Grade is one of the popular food additives and ingredients in most countries.


Lactic Acid Food Grade is an organic acid that is naturally occurring in the human body and fermented foods.
Fermentation occurs when natural bacteria feed on the sugar and starch of a food, producing Lactic Acid Food Grade.
Lactic Acid Food Grade helps stabilize acidity, maintain pH levels, and prevent microbial contaminations.


Increase the shelf life of your dairy products, fermented preserves, processed meats, beverages, egg-based products, and infant foods with Lactic Acid Food Grade.
Not only does Lactic Acid Food Grade act as a preservative, but it also enhances the taste and aroma of your creations.


Lactic Acid Food Grade is an organic acid occurring naturally in the human body and in fermented foods.
The commercial production of Lactic Acid Food Grade is typically done by traditional fermentation of natural carbohydrates.
Lactic Acid Food Grade standard is produced from natural corn starch by advanced bio-fermentation and refining technology.


Lactic Acid Food Grade is a yellowish to colorless liquid, having a mild acid odor and taste.
Lactic Acid Food Grade is an organic compound with the formula CH3CH(OH)CO2H.
The process creates B-vitamins, beneficial enzymes, and more.


L(+) form is preferred for better metabolism and natural carbohydrates.
Lactic Acid Food Grade is a versatile ingredient used in the food industry as an acidity regulator and acidulant.
In its solid state, Lactic Acid Food Grade is white and water-soluble.


In its liquid state, Lactic Acid Food Grade is clear.
Lactic Acid Food Grade is produced both naturally and synthetically.
As a food additive Lactic Acid Food Grade is approved for use in the EU, USA and Australia and New Zealand; it is listed by its INS number 270 or as E number E270.


Lactic Acid Food Grade is produced commercially by fermentation of carbohydrates such as glucose, sucrose, or lactose, or by chemical synthesis.
Carbohydrate sources of Lactic Acid Food Grade include corn, beets, and cane sugar.
Lactic Acid Food Grade is an alpha hydroxy acid with both exfoliant and humectant properties.


Lactic Acid Food Grade is produced naturally in the body (it's the stuff that gives you a ‘stitch’ during a workout) and is also found in yogurt and milk.
There is another method of production, through the chemical synthesis from acetaldehyde.
This is done by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile.


Lactic Acid Food Grade can be used in pharmaceutical products because it produces water-soluble lactates from otherwise insoluble ingredients.
In the food industry, Lactic Acid Food Grade is found primarily in sour milk products, these include kumis, laban, yogurt, kefir, and some cottage cheeses.
Lactic Acid Food Grade is also responsible for the sour flavor of sourdough breads.


As an ingredient in personal care products, Lactic Acid Food Grade has the ability to boost skin’s moisture levels—even as it exfoliates.
At higher concentrations, Lactic Acid Food Grade acts as an exfoliator helping to dissolve connections between skin cells, while at lower levels it is used as a humectant, meaning it can actually help hydrate skin by pulling in water to the outer skin layer.


Lactic Acid Food Grade is a chemical compound classified as an organic acid.
Lactic Acid Food Grade is a type of carboxylic acid, specifically known as 2-hydroxypropanoic acid.
Lactic Acid Food Grade is produced in the body as a byproduct of anaerobic metabolism, primarily in muscle tissues, during periods of intense physical activity or when oxygen supply is limited.


Lactic Acid Food Grade plays a crucial role in energy production and can serve as an alternative energy source when glucose availability is reduced.
In terms of its chemical structure, Lactic Acid Food Grade consists of a three-carbon molecule with a hydroxyl group (-OH) and a carboxyl group (-COOH) attached to the second carbon.


Lactic Acid Food Grade may exist either as a white solid in pure form, or a clear to yellowish liquid when dissolved in water.
Lactic Acid Food Grade can be produced via fermentation of carbohydrates, or synthesized from acetaldehyde.
Produced from natural corn starch through the traditional fermentation of natural carbohydrates, Lactic Acid Food Grade is a highly versatile solution used in various food applications.


One of the critical benefits of Lactic Acid Food Grade is its ability to help control pH levels.
Balancing pH levels improves flavor and texture and ensures the final product is safe and stable.
Due to regulating and lowering pH levels, Lactic Acid Food Grade serves as a microbial inhibitor with the growth of potentially harmful bacteria.


As a highly effective preservative, Lactic Acid Food Grade can help to extend product shelf life and reduce the risk of spoilage or contamination.
Lactic Acid Food Grade is ideal for bakery, dairy, beverages, meat, and many other applications.
Lactic Acid Food Grade is non-GMO.


Industrially, Lactic Acid Food Grade is produced by the bacterial fermentation of carbohydrates; fermented milk products are obtained industrially by fermentation of milk or whey by Lactobacillus bacteria.
There is another method of production, through the chemical synthesis from acetaldehyde.


This is done by reacting acetaldehyde with hydrogen cyanide and hydrolysing the resultant lactonitrile.
Lactic Acid Food Grade, particularly in its food-grade form, has a variety of uses in the food and beverage industry.
Lactic Acid Food Grade is a natural organic acid produced through fermentation, often from sources like sugars and starches.


Lactic Acid Food Grade has a mild, tart flavor and is generally recognized as safe (GRAS) when used in food applications.
Lactic Acid Food Grade is an organic acid.
Lactic Acid Food Grade has the molecular formula CH3CHOOH.


Lactic Acid Food Grade exists in two stereoisomeric forms: L-lactic acid and D-lactic acid.
L-lactic acid is the most common and biologically active form found in humans.
Overall, Lactic Acid Food Grade is an important compound with diverse biological and industrial significance, contributing to various physiological processes and serving as a versatile chemical building block in numerous applications.


In its solid state, Lactic Acid Food Grade is white and miscible with water.
When it is in its dissolved state, Lactic Acid Food Grade forms a colourless solution.
Lactic Acid Food Grade is an alpha hydroxy acid with both exfoliant and humectant properties.


Naturally, Lactic Acid Food Grade occurs as a chemical byproduct of anaerobic respiration in humans, this is the process by which cells produce energy without oxygen.
Lactic Acid Food Grade is also produced by bacteria in yoghurts and is also found in blood, where it is deposited by muscle and red blood cells.


Lactic Acid Food Grade has strong antiseptic and fresh-keeping effect.
In terms of seasoning, the unique sour taste of Lactic Acid Food Grade can increase the taste of food.
Adding a certain amount of Lactic Acid Food Grade to salads such as salad, soy sauce and vinegar can maintain the stability and safety of microorganisms in the product while making the taste milder.


Natural Lactic Acid Food Grade is a natural intrinsic ingredient in dairy products.
Lactic Acid Food Grade has the taste of dairy products and good anti-microbial effect.
Lactic Acid Food Grade has been widely used in blending yoghurt cheese, ice cream and other foods, and has become a popular dairy sour agent.


Lactic Acid Food Grade powder is a direct sour conditioner for the production of steamed bread.
Lactic Acid Food Grade is a natural fermented acid, so it can make bread unique.
Lactic Acid Food Grade is a natural sour taste regulator.


Lactic Acid Food Grade is an organic acid that naturally occurs in a variety of foods during the fermentation process.
The digestive tract can easily break down Lactic Acid Food Grade since it’s naturally present in the body.
Lactic Acid Food Grade is known for its tangy flavor profile and nearly colorless appearance, which lends itself to various food applications.


Lactic Acid Food Grade is typically produced by the fermentation of natural carbohydrates.
Lactic Acid Food Grade is available at 80% and is approved as a natural ingredient.
Within the Personal Care sector, Lactic Acid Food Grade functions as an acidifier with moisturising, exfoliating and antibacterial properties.


Lactobacillus and Streptococcus cultures produce Lactic Acid Food Grade through fermentation.
The bacteria break down sugar to extract energy and produce Lactic Acid Food Grade as a byproduct.
Lactic Acid Food Grade helps regulate pH levels and prevents the growth of microorganisms, extending shelf life.



USES and APPLICATIONS of LACTIC ACID FOOD GRADE:
Lactic Acid Food Grade is a precursor for the production of glycolic acid another alpha hydroxy acid used in skincare products.
In cosmetic formulations, Lactic Acid Food Grade is often included in anti-ageing products due to its exfoliating properties and potential to improve skin texture.


Lactic Acid Food Grade is a natural preservative found in several foods, including pickled vegetables, yogurt, and baked goods.
Lactic Acid Food Grade is a cheap and minimally processedTrusted Source preservative.
Lactic Acid Food Grade is a natural preservative and is commonly used to preserve dairy products, such as cheese, yogurt, and sour cream, as well as canned fruits and vegetables.


Lactic Acid Food Grade can be used to produce a tart or sour flavor in foods and beverages and can be used to add a unique flavor to craft beer.
Lactic Acid Food Grade is used as a flavoring agent and preservative in processed cheese, salad dressings, pickles, and carbonated beverages.
Lactic Acid Food Grade is also used as a raw material or a catalyst in numerous chemical processes.


Lactic Acid Food Grade is widely used as acidulants and preservatives in food and beverage industries.
Lactic Acid Food Grade is an organic acid that is used as a preservative in food products and as an additive in beverages.
The slightly sour taste of natural Lactic Acid Food Grade also enhances the flavor profile of baked goods, candies, and culinary cuisines.


You can use Lactic Acid Food Grade for cooking by adding it to marinades, dressings, and sauces.
The all-natural Lactic Acid Food Grade helps to balance pH levels and acidity.
Use our food-grade Lactic Acid Food Grade in recipes that have leavening agents, like yeast and baking soda.


The natural Lactic Acid Food Grade works in conjunction with the leavening agents to help the baked goods rise in a timely manner.
Lactic Acid Food Grade for baking applications helps improve the texture of desserts and bread.
For vegetarian dishes, Lactic Acid Food Grade is used to impart the tangy and slightly sour taste that dairy products lend to recipes.


Lactic Acid Food Grade is used in various cooking and baking applications catering to a diverse range of palates.
When incorporating Lactic Acid Food Grade into cooking and baking applications, start with a small amount and then add more if desired.
The liquid formula of Lactic Acid Food Grade is highly concentrated, and a little goes a long way.


Lactic Acid Food Grade is also used in skincare products, as it’s packed with the gentlest alpha-hydroxy acids beneficial to the skin thanks to its hydrating and exfoliating properties.
Lactic Acid Food Grade is also used in a wide range of food applications such as bakery products, beverages, meat products, confectionery, dairy products, salads, dressings, ready meals, etc.


Lactic Acid Food Grade in food products usually serves as either as a pH regulator or as a preservative.
Lactic Acid Food Grade is produced from natural corn starch by advanced bio-fermentation and refining technology.
Lactic Acid Food Grade is a yellowish to colorless liquid, having a mild acid odor and taste.


Lactic Acid Food Grade is a carboxylic acid widely used as acidity regulator in food and beverage.
Lactic Acid Food Grade is able to preserve and flavor; however, that is not its only feature.
In the food industry Lactic Acid Food Grade is used as a preservative, acidity regulator, flavor enhancer and has an INS number of 270 or an E number of E270.


Lactic Acid Food Grade is used as a food preservative, hardener and flavoring.
Lactic Acid Food Grade is an ingredient in processed foods and is used in meat processing as a tenderiser and flavor enhancer.
Lactic Acid Food Grade is used for baking and baking in bread, cakes, biscuits and other baked foods.


Lactic Acid Food Grade can improve the quality of food and maintain color extend the shelf life.
Since Lactic Acid Food Grade is part of the skin's inherent natural moisturizing factor, it is widely used as a moisturizer for many skin care products.
Lactic Acid Food Grade has strong antiseptic and fresh-keeping effect.


Lactic Acid Food Grade can be used in fruit wine, beverage, meat, food, pastry making, vegetable (olive, cucumber, pearl onion) pickling and canning, food processing, fruit storage, with adjustment pH, bacteriostatic, prolonged shelf life, seasoning, color preservation, and product quality.
Because of the mild acidity of Lactic Acid Food Grade, it can also be used as the preferred sour agent for delicate soft drinks and juices.


When brewing beer, adding proper amount of Lactic Acid Food Grade can adjust the pH value to promote saccharification, facilitate yeast fermentation, improve beer quality, increase beer flavor and extend shelf life.
Lactic Acid Food Grade is used to adjust pH in liquor, sake and fruit wine to prevent the growth of bacteria, enhance the acidity and refreshing taste.


Lactic Acid Food Grade is used in a range of applications and industries such as food, drinks, personal care and cleaning.
Lactic Acid Food Grade has halal and Kosher Certified.
Food applications: Lactic Acid Food Grade is used Beverages, Meat, Confectionary, Feed and Pet food.


Lactic Acid Food Grade is used in a wide range of applications and industries, including but not limited to food, drinks, personal care and cleaning.
For the food applications, Lactic Acid Food Grade serves mainly as a mild-tasting acidity regulator, as a preservative and as a flavouring agent.
Lactic Acid Food Grade is certified Halal and Kosher.


For technical applications, Lactic Acid Food Grade is exploited primarily for its acid moiety and antibacterial properties.
Lactic Acid Food Grade can be added to baked goods, like bread, muffins, and cake, as well as other food products, like yogurt and cheese, since it acts as a natural preservative.


Lactic Acid Food Grade helps to extend the shelf life of many foods, preventing bacteria growth.
Meanwhile because the good ability of bacteriostasis and fresh-keeping, Lactic Acid Food Grade can be used to extend product's shelf life.
Lactic Acid Food Grade is widely used in candy, canned food, bread and other solid foods.


Lactic Acid Food Grade is a colorless transparent liquid that can be mixed with water.
Lactic Acid Food Grade is widely used in applications such as baking and beer.
Lactic Acid Food Grade, in its food-grade form, is commonly used in the food and beverage industry for various purposes.


Lactic Acid Food Grade is often utilized as a preservative, flavoring agent, pH regulator, and moisturizer.
Lactic Acid Food Grade is also employed in various chemical processes, such as the production of biodegradable plastics and environmentally friendly solvents.


Lactic Acid Food Grade is used Preservative, Dairy culturing agent, Contraceptive jellies, Acidifier, Pharmaceutical ingredient, and Cosmetic ingredient.
Lactic Acid Food Grade has the dual characteristics of Lactic acid and Calcium lactate, which not only possesses mild and lasting sourness of lactic acid, but also an excellent source of calcium.


Because Lactic Acid Food Grade is powder product so it's especially suitable for regulating the acidity and sourness of various kinds of solid food.
Lactic Acid Food Grade can also be used as a flavoring agent.
Lactic Acid Food Grade can help stimulate collagen and strengthen the skin, which equals fewer fine lines and wrinkles.


The hydroxy acids exfoliate the top layer of skin, helping smooth and even complexion, keep pores unclogged, brighten skin and even fade dark marks and discoloration.
Some beers (sour beers) deliberately contain added Lactic Acid Food Grade, one such type being Belgian lambics.


In most cases, Lactic Acid Food Grade in beer is produced from various bacterial strains.
These bacteria ferment sugars into acids, unlike yeasts which ferment sugars into ethanol.
Once the wort has cooled, the yeast and bacteria are allowed to 'fall' into the open fermenters.


Brewers of more conventional beers would ensure that such bacteria do not enter the fermenter.
Other styles of sour beer include 'Berliner weisse', 'Flanders red' and 'American wild ale'.
In wine production, natural malic acid is converted to Lactic Acid Food Grade to reduce spiciness and for other taste reasons, a natural or controlled bacterial process is often used.


If the bacterial action is unstable, additional Lactic Acid Food Grade is added to maintain stable product parameters.
In the washing industry, an antimicrobial agent, Lactic Acid Food Grade is used as a natural ingredient for descaling, which is natural and environmentally friendly.


Lactic Acid Food Grade is commonly found in organic descalers for coffee machines.
Many products can be found for the care of the skin of livestock (therapeutic ointments, disinfectants, post-milking teat wipes, pre-milking cleansers etc.).


Lactic Acid Food Grade is also used as a respiratory and acidity regulator, thus making feed more palatable and odorous and thus increasing the digestibility of feed.
Animals gain weight faster and produce more milk.


Preservative: Lactic Acid Food Grade and its salts, such as sodium lactate, can help extend the shelf life of certain food products by lowering the pH and creating an environment that inhibits the growth of spoilage microorganisms.
Flavor Enhancer: Lactic Acid Food Grade is used as a flavor enhancer in various foods, including dairy products, candies, and soft drinks, to impart a mildly tangy taste.


pH Regulator: Lactic Acid Food Grade can be used to regulate the pH of certain food products, especially in the dairy industry, to improve product stability.
Lactic Acid Food Grade can be used in pharmaceutical products because it produces water-soluble lactates from otherwise insoluble ingredients.


Lactic Acid Food Grade is used as a preservative and flavoring in dressings and salads.
Lactic Acid Food Grade is used in fermentation and pH regulator in beer, wine, and spirits.
Lactic Acid Food Grade is used as in antimicrobial agent and shelf life extender in bakery, meat products.


Lactic Acid Food Grade is food grade and is used for the production of several types of cheeses.
Lactic Acid Food Grade is particularly useful when UHT, ultra-pasteurised or powdered milk are used as the starting materials, since the heat treatments used in the production of these milks deactivates the lactose and prevents the cheese culture from being able to turn it fully into lactic acid.


Lactic Acid Food Grade is a natural organic acid with a long history of food, leather, wood-dyeing, and cosmetic industries.
Lactic Acid Food Grade was formed by natural fermentation in products such as cheese, yogurt, soy sauce, meat products, pickled vegetables, beer, and wine.
Lactic Acid Food Grade is used as pH regulator in Pharma products, used in nickel plating because of its unique complexion constant for the nickel.


Lactic Acid Food Grade is commonly used as a preservative and antioxidant.
Lactic Acid Food Grade also has uses as a fuel additive, chemical intermediate, acidity regulator, and disinfectant.
Lactic Acid Food Grade is used frequently in the cosmetic industry due to the effect of promoting collagen production, helping to firm the skin against wrinkles and sagging.


Lactic Acid Food Grade can also cause micro peeling, which can help reduce various scars and age spots.
Lactic Acid Food Grade is a great solution for people with sensitive or dry skin where exfoliants don’t work.
Lactic Acid Food Grade is used for food and personal care products.


Lactic Acid Food Grade can be used as acidulant, flavoring agent and pH regulator in beverages, meat, sourdough, salads and dressings, confectionery and pickled vegetables.
Lactic Acid Food Grade is used as in acidification agent for beverages.


Lactic Acid Food Grade is also used in a wide range of food applications such as bakery products, beverages, meat products, confectionery, dairy products, salads, dressings, ready meals, etc.
Lactic Acid Food Grade in food products usually serves as either as a pH regulator or as a preservative.


Lactic Acid Food Grade is also used as a flavouring agent.
Meat, Poultry & Fish: Lactic Acid Food Grade can be used in meat, poultry and fish in the form of sodium or potassium lactate to extend shelf life, control pathogenic bacteria (improve food safety), enhance and protect meat flavour, improve water binding capacity and reduce sodium.


Pickling: Lactic Acid Food Grade is used in the pickling process to create a sour flavor and lower the pH of pickled vegetables like cucumbers.
Cheese Making: In cheese production, Lactic Acid Food Grade bacteria are used to ferment milk and produce the acidity required for curd formation and flavor development.


Marinades and Sauces: Lactic Acid Food Grade is used in marinades and sauces for meats and seafood to enhance flavor and tenderness.
Fruit Juices: Lactic Acid Food Grade can be added to fruit juices to adjust acidity levels and improve the taste of citrus and other fruit-based beverages.
Confections: Lactic Acid Food Grade is used in the production of confectionery items like gummies and sour candies to provide a sour and tangy flavor.


Fermentation: Lactic Acid Food Grade bacteria are employed in the fermentation of various foods, such as sauerkraut, kimchi, and sourdough bread.
Sports and Energy Drinks: Lactic Acid Food Grade or its salts are added to sports and energy drinks to provide a mild acidity and enhance the flavor profile.


Lactic Acid Food Grade has many uses and is produced by bacterial fermentation of carbohydrates such as sugars and starches.
In the food industry, Lactic Acid Food Grade is found primarily in sour milk products, these include kumis, laban, yogurt, kefir, and some cottage cheeses.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade.


Lactic Acid Food Grade is also responsible for the sour flavour of sourdough bread.
Lactic Acid Food Grade is also used in beer making, wine production and as a food additive.
Lactic Acid Food Grade is also used to adjust the pH level in foods and beverages.


In production, Lactic Acid Food Grade is usually added so that the pH of the milk reaches around 5.0.
The casein in fermented milk is coagulated (curdled) by Lactic Acid Food Grade and it is also responsible for the sour flavour of sourdough breads.
Lactic Acid Food Grade is responsible for the tangy flavor of fermented milk products (e.g. yogurt, kefir), sour beers, and sourdough bread.


Fermentation usually results in the racemate, although some fermenting bacteria produce the D-enantiomer only.
In winemaking, some wines may go through a natural or induced process called malolactic fermentation, which converts malic acid to Lactic Acid Food Grade, to reduce the sharpness of the acidity.


Beverages uses of Lactic Acid Food Grade: Because of its mild taste, Lactic Acid Food Grade is used as an acidity regulator in beverages such as soft drinks and fruit juices.
Lactic Acid Food Grade is widely used in brewing to adjust pH In the mash in small quantities to adjust the room temperature mash to 5.4-5.6 range.


Lactic Acid Food Grade commonly used as a pH modifier in beer brewing.
Lactic Acid Food Grade is used in beer brewing to lower the pH and increase the body of the beer.
Lactic Acid Food Grade is also used in various beverages and cocktails to impart a sour taste.


Lactic Acid Food Grade in animal nutrition is characterized by lowering the pH of the stomach, reducing the buffering properties of the feed, increasing the activity of proteolytic enzymes/improving the secretion of pancreatic secretions, stimulating the activity of digestive enzymes, stimulating the growth of beneficial bacterial growth, reducing the survival of pathogens in the stomach/maintaining the balance of microbial populations, and directly killing bacteria.


Lactic Acid Food Grade is also found as a nutritional additive for livestock, which improves the digestion of herbivorous animals, as the acid helps to ferment feed faster.
Lactic Acid Food Grade is widely used in brewing to adjust pH In the mash in small quantities to adjust the room temperature mash to 5.4-5.6 range.


Lactic Acid Food Grade is also used in beer making, wine production and as a food additive.
Lactic Acid Food Grade is naturally present in many foodstuffs.
Lactic Acid Food Grade is formed by natural fermentation in products such as cheese, yogurt, soy sauce, sourdough, meat products and pickled vegetables.


The inclusion of additional lactic acid prior to rennetting overcomes this shortage and improves the curd yield.
Lactic Acid Food Grade is a vital ingredient in Ricotta Impastata, Mozzarella, Queso Blanco and other speciality cheeses and can be used in the production of sour milk products, such as Koumiss, Laban, Kefir, as well as some cottage cheeses.


Given its prevalence in nature, Lactic Acid Food Grade is useful for manipulating food chemistry, and is therefore a common additive.
Lactic Acid Food Gradev may be used as a preservative, an acidifier, a dairy culturing agent, or an ingredient in infant formulas.
Lactic Acid Food Grade may also be used in pharmaceuticals and cosmetics as a preservative and acidifier, and in contraceptive jellies as an active ingredient.


Lactic Acid Food Grade is used as a food preservative, curing agent, and flavoring agent.
Lactic Acid Food Grade is an ingredient in processed foods and is used as a decontaminant during meat processing.
Lactic Acid Food Grade has several industrial applications, including its use in food production, pharmaceuticals, and cosmetics.


-Food preservation:
Lactic Acid Food Grade exhibits antimicrobial properties, and its use as a food preservative helps inhibit the growth of harmful bacteria, molds, and yeasts.
Lactic Acid Food Grade can extend the shelf life of processed foods and prevent spoilage.


-Acidification:
Lactic Acid Food Grade is utilized to acidify and adjust the pH of certain foods and beverages.
Lactic Acid Food Grade is particularly valuable in fermented products such as sauerkraut, pickles, kimchi, and yogurt, where it contributes to the characteristic acidity and tanginess.


-Bakery products:
Lactic Acid Food Grade is utilized in the baking industry to regulate dough fermentation and improve the texture and volume of baked goods.
Lactic Acid Food Grade contributes to the development of a desirable crumb structure and imparts a mild tangy flavor.


-Beverages:
Lactic Acid Food Grade finds applications in the production of various beverages, including fruit juices, soft drinks, and alcoholic beverages.
Lactic Acid Food Grade helps adjust acidity levels, improve flavor profiles, and act as a natural preservative.
It is important to note that Lactic Acid Food Grade is generally recognized as safe (GRAS) by regulatory authorities when used in accordance with the approved levels and good manufacturing practices.


-Meat and Poultry:
Lactic Acid Food Grade can be used to reduce microbial load and enhance food safety in meat and poultry products.
Lactic Acid Food Grade is sometimes applied as a surface treatment or spray to reduce the risk of bacterial contamination.


-Flavoring and pH regulation:
Lactic Acid Food Grade is employed as a natural flavoring agent and pH regulator in a wide range of food and beverage products.
Lactic Acid Food Grade imparts a tangy or sour taste, similar to the flavor of yogurt or sourdough bread.


-Dairy products:
Lactic Acid Food Grade plays a vital role in the production of various dairy products.
Lactic Acid Food Grade is used in cheese making to facilitate curd formation and enhance the texture, flavor, and shelf life of cheeses.
Lactic Acid Food Grade bacteria are also employed in the fermentation of milk to produce yogurt and cultured buttermilk.


-Meat and poultry processing:
Lactic Acid Food Grade is employed as an antimicrobial treatment in the processing of meat and poultry products.
Lactic Acid Food Grade can help reduce bacterial contamination and enhance food safety.


-Acidulant:
Lactic Acid Food Grade is used as an acidulant to adjust the pH level and provide a tangy or sour flavor in various food products.
Lactic Acid Food Grade's commonly used in salad dressings, condiments, and beverages to enhance taste.


-Bakery Products: In baking, Lactic Acid Food Grade is used as a dough conditioner to enhance the texture, rise, and shelf life of bread and other baked goods.
Lactic Acid Food Grade can also contribute to the browning of bread crusts.


-Dairy Products:
Lactic Acid Food Grade is naturally present in fermented dairy products such as yogurt, kefir, and buttermilk.
Lactic Acid Food Grade contributes to the tangy flavor and the thickening of these products.



SPECIFICATIONS OF LACTIC ACID FOOD GRADE:
Lactic Acid Food Grade is affirmed GRAS by the FDA.
Lactic Acid Food Grade is also certified 21 CFR 184.1061.
Lactic Acid Food Grade does not use genetically modified microorganism for fermentation.
Lactic Acid Food Grade is Kosher under the Orthodox Union and Halal certified.



CHARACTERISTICS OF LACTIC ACID FOOD GRADE:
Lactic Acid Food Grade is a mild-tasting acidity regulator, flavor enhancer, and shows antibacterial properties.
Lactic Acid Food Grade is colorless to yellowish, nearly odorless, and has a syrupy texture.
Lactic Acid Food Grade is an aqueous solution stable under normal conditions and has a pH (50%) value of less than 2 at 25°C.
Lactic Acid Food Grade is easily biodegradable and should not be in environments warmer than 200°C.



WHY IS LACTIC ACID FOOD GRADE PUT INTO FOOD?
The primary reason food manufacturers add Lactic Acid Food Grade to food is due to its antimicrobial properties and ability to extend shelf life.
Lactic Acid Food Grade also enhances flavor.

Furthermore, food manufacturers use Lactic Acid Food Grade in food, because it is a:
*natural additive
*solvent
*curing agent
*gelling agent
*food carrier
*discoloration inhibitor
The FDA approve the use of Lactic Acid Food Grade in most foods. However, this does not apply to infant formulas or foods.



IS LACTIC ACID FOOD GRADE VEGAN?
The Vegetarian Resource Group state that food manufacturers tend to use beet sugar or corn starch when cultivating Lactic Acid Food Grade, which means it is vegan.
Vegan foods that contain Lactic Acid Food Grade include:

*pickled vegetables
*fermented soy products
*cereals
*legumes



WHAT FOODS HAVE HIGH LEVELS OF LACTIC ACID FOOD GRADE?
Some common foods that contain high levels of Lactic Acid Food Grade and its-producing bacteria include:
*pickled vegetables
*sauerkraut
*kimchi
*yogurt
*kefir
*cured fish
Bacteria that produce Lactic Acid Food Grade — for example, Lactobacillus — are a type of probiotic.



IS LACTIC ACID FOOD GRADE GOOD FOR YOU?
Lactic Acid Food Grade and the bacteria that produce it may offer some health benefits, such as:
*protection against infection
*immune system support
*increased absorption of vitamins and minerals
*antioxidant effects

Researchers found Lactic Acid Food Grade-producing bacteria could provide several health benefits.
For example, they may:
*prevent colon cancer
*alleviate lactose intolerance
*ease diarrhea
*relieve peptic ulcers
*stimulate the immune system

Summary:
Lactic Acid Food Grade is a naturally occurring preservative that manufacturers add to some food products.
Foods such as pickled vegetables and yogurt contain Lactic Acid Food Grade.

Lactic Acid Food Grade and the bacteria that produce it may have numerous health benefits.
For instance, they may boost the immune system and help protect the body against certain types of cancer.

The bacteria that produce Lactic Acid Food Grade are a type of probiotic.
Probiotics have several health benefits, including improving gut health.



IS LACTIC ACID FOOD GRADE GOOD FOR YOU?
Yes, Lactic Acid Food Grade is good for you, even when it’s in the form of a food preservative.

Although many food preservatives are unhealthy, Lactic Acid Food Grade preservatives will help protect you from getting sick.
Lactic Acid Food Grade controls the pH, or acidity and alkalinity, to prevent food from spoiling.

Lactic Acid Food Grade also improves your food’s taste.
By controlling the acidity, Lactic Acid Food Grade balances flavors in foods such as olives, cheese, canned fish, desserts, and carbonated drinks.

More importantly, Lactic Acid Food Grade can boost the quality of your food’s nutrition.
While the Lactic Acid Food Grade added to desserts, canned fish, and carbonated drinks is not very healthy, the naturally produced it in fermented foods such as kimchi and yogurt offers a variety of health benefits by:

*Strengthening your immune system
*Helping your body absorb minerals and vitamins
*Giving your food antioxidant effects
*Protecting you from vaginal and urinary infections
*Some strains of Lactic Acid Food Grade bacteria found in food are probiotics, such as those belonging to the genus Lactobacillus.

This means many foods high in Lactic Acid Food Grade have probiotic qualities and can boost your gut health.
Lactic Acid Food Grade can also protect you from constipation and other gastrointestinal issues.



IS LACTIC ACID FOOD GRADE VEGAN?
Generally, Lactic Acid Food Grade is vegan because it’s made from or originates from cereals, legumes, or fermented vegetables.
The main exceptions are Lactic Acid Food Grade found in fermented meat and dairy products, which are non-vegan.

But some food manufacturers may have used animal sources to produce human-made Lactic Acid Food Grade.
The only way to find out for certain is to ask the manufacturer directly.



HOW IS LACTIC ACID FOOD GRADE MADE?
Lactic Acid Food Grade is produced through fermentation, a process where yeasts, mold, fungi, or bacteria break down carbohydrates -- like sugar and starch -- into alcohol, gas, and acids.
Fermentation results in food products high in Lactic Acid Food Grade.

*Fermentation can happen naturally.
Yogurt and sourdough, for instance, ferment on their own.
But in most cases, food manufacturers use a starter culture to begin the fermentation process.

A manufacturer takes these steps to create fermented foods:
*Selects a container to limit oxygen exposure
*Adds a brine of water and salt to the container before sealing it
*Puts in the food that needs to be fermented, such as cabbage or cucumber
*As bacteria break down the sugar in the food, carbon dioxide and Lactic Acid Food Grade will form.

Meanwhile, the process removes oxygen, and the food becomes more acidic.
This promotes the growth of more Lactic Acid Food Grade bacteria and suppresses the growth of other microorganisms.

The fermentation process can take anywhere from days to months.
The food manufacturer will then take the fermented food out and store it in a cool place to keep it from spoiling.



WHAT FOODS ARE HIGH IN LACTIC ACID FOOD GRADE?
A few types of foods are high in Lactic Acid Food Grade.
Generally, any food produced through a fermentation process is full of Lactic Acid Food Grade bacteria and other beneficial bacteria.
These include but are not limited to:

*Bread and beer
*Soy products such as tofu and soy milk
*Cheese
*Pickled vegetables such as kimchi and sauerkraut
*Pickled meats such as salami
*Legumes such as beans and peas.

To get the most out of these foods, avoid cooking them over high heat.
This may kill the beneficial bacteria.
Instead, try adding them as toppings or condiments for cooked food.

Fermented foods are delicious and highly varied in texture and flavor.
They make an excellent addition to any meal.



PHYSICAL and CHEMICAL PROPERTIES of LACTIC ACID FOOD GRADE:
Odor: odorless
Melting point/freezing point:
Melting point: 18 °C at 1.013 hPa
Initial boiling point and boiling range: 122 °C at 18,66 - 19,99 hPa
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits: No data available
Flash point: 113 °C - closed cup
Autoignition temperature: 400 °C at 1.011,4 - 1.018,9 hPa
Decomposition temperature: No data available
pH: No data available
Molecular Formula: CH3CHOHCOOH.
Molecular Weight: 90.08 g/mol.

Boiling point: 122 °C.
Melting point: 16.8 °C.
Viscosity
Viscosity, kinematic: No data available
Viscosity, dynamic: No data available
Water solubility: 100 g/l at 20 °C - soluble
Partition coefficient: n-octanol/water:
log Pow: ca.-0,54 at 25 °C - Bioaccumulation is not expected.
Vapor pressure: No data available
Density: 1,25 g/cm3 at 15 °C
Relative density: No data available
Relative vapor density: No data available
Particle characteristics: No data available
Explosive properties: No data available

Oxidizing properties: none
Other safety information:
Surface tension 70,7 mN/m at 1g/l at 20 °C
Formula: H₃CCH(OH)COOH
MW: 90.08 g/mol
Boiling Pt: 122 °C (20 hPa)
Density: 1.11…1.21 g/cm³ (20 °C)
Storage Temperature: Ambient
MDL Number: MFCD00004520
CAS Number: 50-21-5
EINECS: 200-018-0
CAS: 50-21-5
MF: C3H6O3
MW: 90.08
EINECS: 200-018-0

Mol File: 50-21-5.mol
Lactic acid Chemical Properties
Melting point: 18°C
alpha: -0.05 º (c= neat 25 ºC)
Boiling point: 122 °C/15 mmHg (lit.)
density: 1.209 g/mL at 25 °C (lit.)
vapor density: 0.62 (vs air)
vapor pressure: 19 mm of Hg (@ 20°C)
FEMA: 2611 | LACTIC ACID
refractive index: n20/D 1.4262
Fp: >230 °F
storage temp.: 2-8°C

solubility: Miscible with water and with ethanol (96 per cent).
form: syrup
pka: 3.08(at 100℃)
Specific Gravity: 1.209
color: Colorless to yellow
Water Solubility: SOLUBLE
Merck: 145,336
JECFA Number: 930
BRN: 1209341
Stability: Stable.
Physical state: viscous
Color: colorless
Chemical Name : 2-hydroxy – propanoic acid
Molecular Weight : 90.08

Stereochemical purity (L isomer) Min 97.0 %
Content Min 80.0 %
Colour Fresh : Max 100 Apha
Appearance: Colorless to yellow.
Assay: 80 to 88%.
Also known as: Milk acid.
CAS No: 50-21-5.
Density: 1.206 g/ml.
Grade Standard: Commercial, Food Grade.
Molecular Formula: C3H6O3.
Molecular Weight: 90.078 g•mol−1.
Physical State: Liquid.
Usage: Food, Pharma Synthesis.
Chemical Name: L(S)-2-hydroxypropionic acid.



FIRST AID MEASURES of LACTIC ACID FOOD GRADE:
-Description of first-aid measures:
*General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LACTIC ACID FOOD GRADE:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up with liquid-absorbent material.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of LACTIC ACID FOOD GRADE:
-Extinguishing media:
*Suitable extinguishing media:
Water
Foam
Carbon dioxide (CO2)
Dry powder
*Unsuitable extinguishing media:
For this substance/mixture no limitations of extinguishing agents are given.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LACTIC ACID FOOD GRADE:
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles
*Body Protection:
protective clothing
*Respiratory protection
Recommended Filter type: Filter type ABEK
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LACTIC ACID FOOD GRADE:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.



STABILITY and REACTIVITY of LACTIC ACID FOOD GRADE:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Possibility of hazardous reactions:
No data available.
-Incompatible materials:
No data available


Lactose
Lactose; (+)-Lactose; Lactose anhydrous; Milk sugar; 4-(beta-D-Galactosido)-D-glucose; 4-O-beta-D-Galactopyranosyl-D-glucose; Aletobiose; D-Lactose; 1-beta-D-Galactopyranosyl-4-D-glucopyranose; Lactobiose; Lactosum anhydricum; beta-D-galactopyranosyl-(1->4)-D-glucopyranose; (2R,3R,4S,5R,6S)-2-(Hydroxymethyl)-6- ((2R,3S,4R,5R)-4,5,6-trihydroxy-2-(hydroxymethyl)oxan-3-yl) oxyoxane-3,4,5-triol CAS NO: 63-42-3 (anhydrous), CAS NO: 64044-51-5 (hydrate)
LACTOSE MONOHYDRATE
L-ALPHA-PINENE, N° CAS : 7785-26-4, Nom INCI : L-ALPHA-PINENE, Nom chimique : (-)-Pin-2(3)-ene, N° EINECS/ELINCS : 232-077-3. Ses fonctions (INCI). Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. (-)-alpha-pinene; Pinene Alpha; alpha-Pinen (1S)-(-)-alpha-Pinene (1S,5S)-4,6,6-trimethylbicyclo[3.1.1]hept-3-ene (1S,5S)-4,7,7-trimethylbicyclo[3.1.1]hept-3-ene 2,6,6-trimethylbicyclo[3.1.1]hept-2-ene 4,6,6-trimetilbiciclo[3.1.1]hept-3-eno ALPHA PINENE Bicyclo(3.1.1)hept-2-ene, 2,6,6-trimethyl-, (1S,5S)- Alpha Pinene Laevo Laevo Alpha Pinene
LACTOSE MONOHYDRATE
Lactose monohydrate is a sugar that occurs in many plants.
Lactose monohydrate is extracted commercially from sugar cane and sugar beet.
Lactose monohydrate is a disaccharide formed from a glucose unit and a fructose unit.

CAS: 5989-81-1
MF: C12H24O12
MW: 360.31
EINECS: 611-913-4

Lactose monohydrate is hydrolyzed to a mixture of fructose and glucose by the enzyme invertase.
Since Lactose monohydrate has a different optical rotation (levorotatory) than the original sucrose, the mixture is called invert sugar.
Lactose monohydrate is widely used in pharmaceutical formulations as a diluent in oral capsule and tablet formulations.
Lactose monohydrate may also be used in intravenous injections.

Adverse reactions to Lactose monohydrate are largely due to lactose intolerance, which occurs in individuals with a deficiency of the enzyme lactase.
Lactose monohydrate is a reducing sugar.
The amorphous Lactose monohydrate, which is the most reactive form of lactose present in spray-dried lactose, will interact more readily than conventional crystalline grades.
Typical reactions include the Maillard reaction with either primary or secondary amines.

Lactose monohydrate is a crystallized form of milk sugar.
Lactose monohydrate’s commonly used as a filler for medications and added to packaged foods, baked goods, and infant formulas as a sweetener or stabilizer.
This additive is widely considered safe and may not cause symptoms in those who are otherwise lactose intolerant.
However, those with severe Lactose monohydrate may wish to avoid products with this additive to be safe.

Lactose monohydrate is milk sugar.
Lactose monohydrate is a disaccharide composed of one galactose and one glucose molecule.
In the pharmaceutical industry, Lactose monohydrate is used to help form tablets because it has excellent compressibility properties.
Lactose monohydrate is also used to form a diluent powder for dry-powder inhalations.
Lactose monohydrate may be listed as lactose hydrous, lactose anhydrous, lactose monohydrate, or lactose spray-dried.

People who are Lactose monohydrate do not have the enzymes needed to digest lactose.
Most medications do not contain enough lactose to cause lactose intolerance.
But some patients with severe Lactose monohydrate may experience symptoms.
Lactose monohydrate can be found in birth control pills, and some OTC drugs to treat stomach acid or gas.
Patients who are specifically "allergic" to Lactose monohydrate (not just lactose intolerant) should not use tablets containing lactose, or ask their health care provider prior to use.

Lactose monohydrate is a disaccharide sugar synthesized by galactose and glucose subunits and has the molecular formula C12H22O11.
Lactose monohydrate makes up around 2–8% of milk (by mass).
The name comes from lac (gen. lactis), the Latin word for milk, plus the suffix -ose used to name sugars.
Lactose monohydrate is a white, water-soluble, non-hygroscopic solid with a mildly sweet taste.
Lactose monohydrate is used in the food industry.

Lactose monohydrate Chemical Properties
Melting point: 219 °C
Boiling point: 412.35°C (rough estimate)
Alpha: [α]D20+52.2~+52.8°
Density: 1,53 g/cm3
Refractive index: 1.6480 (estimate)
RTECS: OD9625000
Storage temp.: Inert atmosphere,Room Temperature
Solubility H2O: soluble1M, clear, colorless
Form: neat
Color: White to Off-White
PH: pH (50g/l, 25℃) : 4.0~6.0
Water Solubility: Soluble in water.
Stability: Hygroscopic
InChIKey: WSVLPVUVIUVCRA-KPKNDVKVSA-N
CAS DataBase Reference: 5989-81-1(CAS DataBase Reference)
EPA Substance Registry System: Lactose monohydrate (5989-81-1)

Lactose monohydrate occurs as white to off-white crystalline particles or powder.
Lactose monohydrate is odorless and slightly sweet-tasting.
Spray-dried directcompression grades of Lactose monohydrate are generally composed of 80–90% specially prepared pure a-lactose monohydrate along with 10–20% of amorphous lactose.

Structure and Reactions
Lactose monohydrate is a disaccharide derived from the condensation of galactose and glucose, which form a β-1→4 glycosidic linkage.
Lactose monohydrate's systematic name is β-D-galactopyranosyl-(1→4)-D-glucose.
The glucose can be in either the α-pyranose form or the β-pyranose form, whereas the galactose can only have the β-pyranose form: hence α-lactose and β-lactose refer to the anomeric form of the glucopyranose ring alone.

Detection reactions for Lactose monohydrate are the Woehlk- and Fearon's test.
Both can be easily used in school experiments to visualise the different lactose content of different dairy products such as whole milk, lactose free milk, yogurt, buttermilk, coffee creamer, sour cream, kefir, etc.
Lactose monohydrate is hydrolysed to glucose and galactose, isomerised in alkaline solution to lactulose, and catalytically hydrogenated to the corresponding polyhydric alcohol, lactitol.
Lactose monohydrate is a commercial product, used for treatment of constipation.

Uses
Lactose monohydrate is used as a carrier and stabiliser of aromas, pharmaceutical products, Food industry.
Lactose monohydrate is widely used as a binder, filler-binder, and flow aid in direct compression tableting.
Lactose monohydrate's mild flavor and easy handling properties have led to its use as a carrier and stabiliser of aromas and pharmaceutical products.
Lactose monohydrate is not added directly to many foods, because its solubility is less than that of other sugars commonly used in food.
Infant formula is a notable exception, where the addition of Lactose monohydrate is necessary to match the composition of human milk.

Lactose monohydrate is not fermented by most yeast during brewing, which may be used to advantage.
For example, Lactose monohydrate may be used to sweeten stout beer; the resulting beer is usually called a milk stout or a cream stout.
Yeast belonging to the genus Kluyveromyces have a unique industrial application, as they are capable of fermenting Lactose monohydrate for ethanol production.
Surplus lactose from the whey by-product of dairy operations is a potential source of alternative energy.
Another significant Lactose monohydrate use is in the pharmaceutical industry.
Lactose monohydrate is added to tablet and capsule drug products as an ingredient because of its physical and functional properties.
For similar reasons, Lactose monohydrate can be used to dilute illicit drugs such as cocaine or heroin.

Production Methods
A suspension of a-lactose monohydrate crystals in a lactose solution is atomized and dried in a spray drier.
Approximately 10–20% of the total amount of lactose is in solution and the remaining 80–90% is present in the crystalline form.
The spray-drying process predominantly produces spherical particles.
The compactibility of the material and its flow characteristics are a function of the primary particle size of the lactose monohydrate and the amount of amorphous lactose.

Biochem/physiol Actions
Lactose monohydrate is the primary sugar present in milk and the main energy source to a newborn mammalian through its mother′s milk.
Lactose monohydrate is digested by the intestinal lactase (EC 3.2.1.108), an enzyme expressed in newborns.
The enzyme′s activity declines following weaning which can lead to lactose intolerance in adult mammals.

Synonyms
Lactose monohydrate
5989-81-1
alpha-D-Lactose monohydrate
alpha-Lactose monohydrate
64044-51-5
Respitose
D-Lactose monohydrate
Lactose, monohydrate
Lactose(Monohydrate)
alpha-lactose hydrate
LACTOSE,MONOHYDRATE
Lactose monohydrate [NF]
EWQ57Q8I5X
(2R,3R,4S,5R,6S)-2-(hydroxymethyl)-6-[(2R,3S,4R,5R,6S)-4,5,6-trihydroxy-2-(hydroxymethyl)oxan-3-yl]oxyoxane-3,4,5-triol;hydrate
Lactose, hydrous
MFCD00150747
a-D-Glucopyranose, 4-O-b-D-galactopyranosyl-, monohydrate
4-O-beta-D-Galactopyranosyl-alpha-D-glucose
Lactose monohydrate (NF)
Lactopress
Pharmatose
Lactochem
Lactohale
Wyndale
Wynhale
lactose hydrate
Lactose hydrous
ALPHA-LACTOSEMONOHYDRATE
a-Lactose monohydrate
10039-26-6
Lactose Monohydrate (Alpha-Form)
Pharmatose dcl ii
Supertab 11sd
Supertab 14sd
Supertab 30gr
Microtose
Pharmaose
Supertab 50 odt
Supertab 11sd nz
Pharmatose dcl 11
Lactopress spray dried
Lactose fastflo 316
(2R,3R,4S,5R,6S)-2-(hydroxymethyl)-6-{[(2R,3S,4R,5R,6S)-4,5,6-trihydroxy-2-(hydroxymethyl)oxan-3-yl]oxy}oxane-3,4,5-triol hydrate
(2S,3R,4R,5S,6R)-6-(Hydroxymethyl)-5-(((2S,3R,4S,5R,6R)-3,4,5-trihydroxy-6-(hydroxymethyl)tetrahydro-2H-pyran-2-yl)oxy)tetrahydro-2H-pyran-2,3,4-triol hydrate
Spherolac 100
Alpha-lactose,monohydrate
alpha-D-Glucopyranose, 4-O-beta-D-galactopyranosyl-, monohydrate
Lactose (TN)
NSC-760401
UNII-EWQ57Q8I5X
.alpha.-D-Glucopyranose, 4-O-.beta.-D-galactopyranosyl-, monohydrate
Lactose (JP17)
(2R,3R,4S,5R,6S)-2-(hydroxymethyl)-6-[(2R,3S,4R,5R,6S)-4,5,6-trihydroxy-2-(hydroxymethyl)tetrahydropyran-3-yl]oxy-tetrahydropyran-3,4,5-triol
alpha -lactose monohydrate
SCHEMBL16787
LACTOSE HYDRATE [JAN]
LACTOSE, HYDROUS [II]
D-Glucose, 4-O-beta-D-galactopyranosyl-, monohydrate
PHARMATOSE DCL II [II]
D-Glucose, 4-O-.beta.-D-galactopyranosyl-, monohydrate
DTXSID1052828
LACTOSE MONOHYDRATE [II]
alpha-D-Lactose monohydrate, ACS
CHEBI:189432
alpha-Lactose, analytical standard
LACTOSE MONOHYDRATE [USP-RS]
LACTOSE MONOHYDRATE [WHO-IP]
AKOS015896871
FS-3862
NSC 760401
MALONICACIDDISODIUMSALTMONOHYDRATE
(2R,3R,4S,5R,6S)-2-(hydroxymethyl)-6-[(2R,3S,4R,5R,6S)-4,5,6-trihydroxy-2-(hydroxymethyl)oxan-3-yl]oxyoxane-3,4,5-triol hydrate
LACTOSE MONOHYDRATE [EP MONOGRAPH]
CS-0128727
LACTOSUM, MONOHYDRATE [WHO-IP LATIN]
D03226
E80712
EN300-1608278
alpha-4-O-(beta-D-galactopyranosido)-D-glucopyranose
Q27277391
alpha-Lactose monohydrate, >=99% total lactose basis (GC)
4-O-beta-D-Galactopyranosyl-alpha-D-glucopyranose monohydrate
alpha-D-Glucopyranose, 4-O-beta-D-galactopyranosyl-, hydrate
alpha-Lactose monohydrate, BioXtra, >=99% total lactose basis (GC)
alpha-Lactose monohydrate, suitable for cell culture, BioReagent
.alpha.-D-Glucopyranose, 4-O-.beta.-D-galactopyranosyl-, hydrate (1:1)
66857-12-3
L-ALPHA-PINENE
LAMP BLACK 101; Amorphous carbon cas no: 1333-86-4
LAMEFORM TGI (POLYGLYCERYL-3 DIISOSTEARATE)
Lameform TGI (Polyglyceryl-3 Diisostearate) is a water-in-oil emulsifier for use in the production of cosmetic emulsions, lipophilic sticks and ointments.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a clear, yellowish liquid which turns cloudy at room temperature.
Lameform TGI (Polyglyceryl-3 Diisostearate) is used as a water-in-oil emulsifier for cold manufacture, and the cloudiness appearance is reversible by heating.

CAS Number: 66082-42-6
Molecular Formula: C45H88O9

Triglycerin diisostearate, 66082-42-6, [2-hydroxy-3-[2-hydroxy-3-[2-hydroxy-3-(16-methylheptadecanoyloxy)propoxy]propoxy]propyl] 16 methylheptadecanoate, Triglyceryl diisostearate.

Lameform TGI (Polyglyceryl-3 Diisostearate) is a humectant and moisturizer ingredient just like glycerin, but the larger molecular structure penetrates slower into the skin and gives milder, longer lasting moisture.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a nonionic, W/O emulsifier.
Lameform TGI (Polyglyceryl-3 Diisostearate) is used in sun care (after-sun, self-tanning & self-protection), body & face care, personal care wipes and baby care & cleansing formulations.

Lameform TGI (Polyglyceryl-3 Diisostearate), also known as Polyglyceryl-3 Diisostearate, is an ingredient commonly used in cosmetics and personal care products.
Lameform TGI (Polyglyceryl-3 Diisostearate) belongs to the class of polyglyceryl esters, which are derived from glycerin and fatty acids.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a plant-derived ingredient, usually appearing as a yellow viscous liquid with a characteristic fatty acid scent.

This ingredient is used as an emulsifier, aiding the mixing of water and oil ingredients by reducing their surface tension.
Lameform TGI (Polyglyceryl-3 Diisostearate) is used as an emulsifier.
Lameform TGI (Polyglyceryl-3 Diisostearate) gives a soft and powdery feel to the formula.

Lameform TGI (Polyglyceryl-3 Diisostearate) is very gentle and hence used for baby and sensitive skin formulations.
Lameform TGI (Polyglyceryl-3 Diisostearate) is used as an emollient and surfactant in products such as anti-aging serums, foundations, lip gloss, lipsticks, sunscreens, bronzers, moisturizers.
Lameform TGI (Polyglyceryl-3 Diisostearate) adds shine, gloss, vibrancy in make up products.

Lameform TGI (Polyglyceryl-3 Diisostearate) is incorporated into lipophilic ointments and sticks.
Lameform TGI (Polyglyceryl-3 Diisostearate) improves spreadability, absorption of the product and provides softness to the skin.
Lameform TGI (Polyglyceryl-3 Diisostearate) can be derived from stearic acid (a saturated fatty acid from coconut/palm) and polyglycerin-3 (vegetable oil component).

Lameform TGI (Polyglyceryl-3 Diisostearate) is hydroxy compounds used in cosmetics and skin care products as emollients and surfactants, and are found primarily in lip glosses and lipsticks, although they are also seen in foundations, sunscreens, bronzers, moisturizers and anti-aging serums.
Lameform TGI (Polyglyceryl-3 Diisostearate) facilitates the blending of oil and water components in formulations, ensuring uniform distribution and stability.
Lameform TGI (Polyglyceryl-3 Diisostearate) can contribute to the texture and feel of cosmetic products, imparting a smooth and luxurious skin feel.

Lameform TGI (Polyglyceryl-3 Diisostearate) may help to hydrate and moisturize the skin by forming a protective barrier that reduces water loss from the skin's surface.
This ingredient can improve the spreadability of formulations, allowing for easy application and smooth coverage on the skin.
Lameform TGI (Polyglyceryl-3 Diisostearate) is generally well-tolerated by the skin and is suitable for use in a wide range of cosmetic formulations.

An effective emulsifier for Water in Oil formulations.
Lameform TGI (Polyglyceryl-3 Diisostearate) is exceptionally gentle on the skin and mild, which makes it ideal in products aimed at sensitive skin areas.
The emulsifier is especially versatile during production, being both usable in Hot and Cold Process formulations. Suitable for both skin and hair formulations.

Lameform TGI (Polyglyceryl-3 Diisostearate) is a water-in-oil emulsifier for use in the production of cosmetic emulsions, lipophilic sticks and ointments.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a clear, yellowish liquid which turns cloudy at room temperature.
Lameform TGI (Polyglyceryl-3 Diisostearate) is used as a water-in-oil emulsifier for cold manufacture, and the cloudiness appearance is reversible by heating.

Lameform TGI (Polyglyceryl-3 Diisostearate) is primarily used as an emulsifier and surfactant in cosmetic formulations.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps to stabilize emulsions by promoting the mixing of oil and water phases, leading to the formation of stable and homogeneous products.
This ingredient is often found in creams, lotions, moisturizers, makeup products, and sunscreens.

Lameform TGI (Polyglyceryl-3 Diisostearate) is a nonionic surfactant, meaning it does not carry an electrical charge in solution.
Nonionic surfactants are generally milder and less irritating compared to ionic surfactants, making them suitable for use in skincare products, especially for sensitive or delicate skin types.
Lameform TGI (Polyglyceryl-3 Diisostearate) is soluble in both water and oil phases, which makes it versatile in formulating various types of cosmetic products.

Lameform TGI (Polyglyceryl-3 Diisostearate) can help create stable emulsions with different ratios of water to oil, providing flexibility in product design.
When applied to the skin, Lameform TGI (Polyglyceryl-3 Diisostearate) can form a thin, protective film that helps to lock in moisture and protect the skin from environmental stressors.
This film-forming property can contribute to the long-lasting hydration and comfort of skincare products.

Lameform TGI (Polyglyceryl-3 Diisostearate) is often used in combination with other emulsifiers and thickeners to optimize the performance and stability of cosmetic formulations.
Its compatibility with a wide range of ingredients allows formulators to achieve desired product characteristics and sensory attributes.
Lameform TGI (Polyglyceryl-3 Diisostearate) is generally recognized as safe (GRAS) for use in cosmetics and personal care products by regulatory agencies such as the U.S. Food and Drug Administration (FDA) and the European Union (EU).

Lameform TGI (Polyglyceryl-3 Diisostearate) is listed on ingredient inventories such as the Cosmetic Ingredient Database (Cosing) and the Personal Care Product Council (PCPC) International Cosmetic Ingredient Dictionary and Handbook.
Lameform TGI (Polyglyceryl-3 Diisostearate) is considered biodegradable and environmentally friendly, with low toxicity to aquatic organisms.

This makes it a preferred choice for formulators seeking sustainable and eco-friendly cosmetic ingredients.
Lameform TGI (Polyglyceryl-3 Diisostearate) is commercially available from various suppliers worldwide, making it readily accessible to cosmetic manufacturers and formulators.

Acid Value: ≤12
Saponification Value: ≤165

Lameform TGI (Polyglyceryl-3 Diisostearate) is a natural emulsifiable obtained from glycerin and stearic acid.
Lameform TGI (Polyglyceryl-3 Diisostearate) is used in oily external fase cream formulations and allows to properly emulsify the physical filters in sunscreens.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a hydroxy compound used as an emollient and surfactant.

Lameform TGI (Polyglyceryl-3 Diisostearate) is used in lip glosses and lipsticks especially along with foundations, sunscreens, moisturizers and anti-aging serums.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a Diester of isostearic acid and polyglycerin3 Polyglyceryl-3 diisostearate uses and applications include: Emulsifier, emollient, thickener, solvent in cosmetics, creams, lotions, lip products, pharmaceuticals; dye and pigment wetting agent; food emulsifier; pharmaceuticals excipient.

Lameform TGI (Polyglyceryl-3 Diisostearate) helps improve the stability of cosmetic formulations by preventing phase separation, creaming, or coalescence.
This ensures that the product maintains its desired consistency and appearance over time, even under various storage conditions.
In addition to its emulsifying properties, Lameform TGI (Polyglyceryl-3 Diisostearate) can contribute to the overall texture and sensorial experience of cosmetic products.

Lameform TGI (Polyglyceryl-3 Diisostearate) imparts a smooth, non-greasy feel and can help create lightweight, easily spreadable formulations that are pleasant to use.
Lameform TGI (Polyglyceryl-3 Diisostearate) is compatible with a wide range of active ingredients commonly used in skincare formulations, including antioxidants, vitamins, and botanical extracts.
This compatibility allows formulators to incorporate various functional ingredients without compromising the stability or efficacy of the final product.

Lameform TGI (Polyglyceryl-3 Diisostearate) can be used in a variety of cosmetic products, including moisturizers, creams, lotions, serums, sunscreens, and makeup formulations.
Its versatility makes it suitable for both leave-on and rinse-off products, providing formulators with flexibility in product development.
Lameform TGI (Polyglyceryl-3 Diisostearate) contributes to the sensory attributes of cosmetic products, such as smoothness, silkiness, and skin feel.

Lameform TGI (Polyglyceryl-3 Diisostearate) helps create formulations that are easy to apply, absorb quickly into the skin, and leave a soft, velvety finish without tackiness or greasiness.
When combined with other emulsifiers, thickeners, and stabilizers, Lameform TGI (Polyglyceryl-3 Diisostearate) can act synergistically to optimize the performance and aesthetics of cosmetic formulations.
This synergistic effect allows formulators to achieve specific product goals, such as enhanced hydration, improved skin barrier function, or prolonged wear.

Cosmetic products formulated with Lameform TGI (Polyglyceryl-3 Diisostearate) often appeal to consumers seeking lightweight, non-comedogenic, and non-irritating skincare solutions.
Its mildness and compatibility with sensitive skin make it suitable for a wide range of skin types, including dry, oily, and combination skin.
Lameform TGI (Polyglyceryl-3 Diisostearate) complies with regulatory requirements for cosmetic ingredients in major markets worldwide, including the United States, European Union, Japan, and China.

Lameform TGI (Polyglyceryl-3 Diisostearate) meets safety standards and specifications established by regulatory agencies to ensure consumer safety and product quality.
Lameform TGI (Polyglyceryl-3 Diisostearate) can help improve skin hydration and moisturization by forming a protective barrier on the skin's surface.
This barrier helps to prevent moisture loss and maintains the skin's natural hydration levels, resulting in smoother, softer, and more supple skin.

Due to its lightweight and non-greasy texture, formulations containing Lameform TGI (Polyglyceryl-3 Diisostearate) are often non-comedogenic, meaning they are less likely to clog pores or contribute to acne breakouts.
This makes it suitable for use in skincare products designed for acne-prone or oily skin types.
Lameform TGI (Polyglyceryl-3 Diisostearate) exhibits emollient properties, which help to soften and smooth the skin's surface.

Lameform TGI (Polyglyceryl-3 Diisostearate) can also act as a conditioning agent, improving the overall texture and feel of cosmetic products while imparting a luxurious skin feel.
In formulations containing antioxidants or other sensitive active ingredients, Lameform TGI (Polyglyceryl-3 Diisostearate) can help enhance stability and protect these ingredients from degradation due to exposure to air, light, or heat.
This ensures the efficacy and longevity of the product over time.

Lameform TGI (Polyglyceryl-3 Diisostearate) is compatible with a wide range of formulation ingredients, including oils, waxes, silicones, and hydrophilic polymers.
This compatibility allows formulators to create innovative and multifunctional cosmetic products with diverse textures and sensory profiles.
By improving the dispersion and compatibility of ingredients within cosmetic formulations, Lameform TGI (Polyglyceryl-3 Diisostearate) can enhance the overall performance of the product.

This includes attributes such as spreadability, absorbency, adherence, and longevity, resulting in products that deliver optimal results to consumers.
Some suppliers of Lameform TGI (Polyglyceryl-3 Diisostearate) offer sustainable sourcing options and eco-friendly manufacturing processes.
This aligns with the growing demand for environmentally conscious and socially responsible cosmetic ingredients, appealing to consumers who prioritize sustainability.

Lameform TGI (Polyglyceryl-3 Diisostearate) can be easily incorporated into various cosmetic formulations at different concentrations to achieve specific performance objectives and desired sensory attributes.
This allows formulators to customize products according to market trends, consumer preferences, and brand identity.
Many formulations containing Lameform TGI (Polyglyceryl-3 Diisostearate) undergo rigorous clinical testing and safety assessments to ensure they meet regulatory standards and consumer safety requirements.

This includes dermatological testing, irritation testing, sensitization testing, and stability testing to confirm the safety and efficacy of the product.
Cosmetic companies often provide information about the benefits and uses of Lameform TGI (Polyglyceryl-3 Diisostearate) to educate consumers and promote transparency regarding ingredient sourcing, manufacturing practices, and product performance.
This helps to build trust and confidence in the brand and its products among consumers.

Uses:
Lameform TGI (Polyglyceryl-3 Diisostearate) is used in cosmetic, food, plastic, metal process and petrochemical industry etc.
Lameform TGI (Polyglyceryl-3 Diisostearate) could be used in ice cream, candy, protein beverage, margarine, dairy products because of the good emulsification, dispersing and stable property.
Lameform TGI (Polyglyceryl-3 Diisostearate) could be used in meat product such as sausage, luncheon meat, burger, fish stuffing because of the good dispersing and stable property.

Lameform TGI (Polyglyceryl-3 Diisostearate) could be used in pharmaceutical chemicals, such as pharmacy painting, printing ink.
Lameform TGI (Polyglyceryl-3 Diisostearate) could be used as protective agent in edible dry yeast, improve the antistaling agent's freshness effect.
Lameform TGI (Polyglyceryl-3 Diisostearate) could improve productivity by improving the crystallization of sucrose.

Lameform TGI (Polyglyceryl-3 Diisostearate) also could be used as dispersing agents in cod-liver oil emulsion or spongarion.
As emulsion, stabilizer, dispersing agents and plasticizer, it could be widely applied in textile, papermaking, painting, plastic, rubber, printing and dyeing industry. Lameform TGI (Polyglyceryl-3 Diisostearate) has broad range of HLB value, except for its high security for human, it also has good characteristics of non-stimulation for skin, good water and emulsion solubility.

Lameform TGI (Polyglyceryl-3 Diisostearate) could stand thermophilic digestion so that it's good for goods' sterilization .
Lameform TGI (Polyglyceryl-3 Diisostearate) acts as an emulsifier, helping to stabilize oil-in-water and water-in-oil emulsions.
This property is essential for creating homogeneous mixtures of oil and water phases in products like creams, lotions, and serums.

As a surfactant, Lameform TGI (Polyglyceryl-3 Diisostearate) reduces the surface tension between different ingredients, facilitating their dispersion and improving the spreadability of cosmetic formulations.
v contributes to the texture and feel of cosmetic products, imparting a smooth, non-greasy sensation to formulations.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps create products with desirable sensory attributes.

Lameform TGI (Polyglyceryl-3 Diisostearate) forms a protective barrier on the skin, helping to lock in moisture and prevent dehydration.
This moisturizing effect is particularly beneficial in skincare products like moisturizers and body lotions.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps soften and condition the skin, leaving it feeling smooth and hydrated.

This makes it a valuable ingredient in skincare products designed to improve skin texture and appearance.
Lameform TGI (Polyglyceryl-3 Diisostearate) enhances the compatibility of different ingredients in cosmetic formulations, ensuring their proper integration and interaction.
This property is crucial for maintaining the stability and efficacy of the final product.

Lameform TGI (Polyglyceryl-3 Diisostearate) assists in the formulation process by improving the homogeneity, stability, and performance of cosmetic products.
Formulators rely on Lameform TGI (Polyglyceryl-3 Diisostearate) to achieve desired product characteristics and meet consumer expectations.
Lameform TGI (Polyglyceryl-3 Diisostearate) serves multiple functions in cosmetic formulations, simplifying the formulation process and reducing the need for additional ingredients.

Its versatility makes it suitable for a wide range of skincare, haircare, and personal care products.
Lameform TGI (Polyglyceryl-3 Diisostearate) is a compound used primarily in lip care and lipsticks due to its emollient effect, although it is also found in sunscreens, bronzers, moisturizers and anti-aging serums.
Lameform TGI (Polyglyceryl-3 Diisostearate) used as a natural and gentle emulsifier that gives a soft texture to products.

Vegetable-based high polarity oil with medium viscosity used as co-emulsifier in emulsions.
Lameform TGI (Polyglyceryl-3 Diisostearate) products are pale yellow to yellow waxy solid, are easy to soluble in oil, organic solvent, and disperse into hot water.
Lameform TGI (Polyglyceryl-3 Diisostearate) also has good property of thermostability and acid resistance

Lameform TGI (Polyglyceryl-3 Diisostearate) is used in sun care (after-sun, self-tanning and self-protection), body & face care, personal care wipes, and baby care & cleansing formulations
Lameform TGI (Polyglyceryl-3 Diisostearate) is commonly used in the formulation of creams and lotions, where it acts as an emulsifier to stabilize the mixture of water and oil phases.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps create smooth, creamy textures that are easy to apply and absorb into the skin.

In serums and moisturizers, Lameform TGI (Polyglyceryl-3 Diisostearate) serves as a moisturizing agent, helping to hydrate and soften the skin.
Its emollient properties contribute to the luxurious feel of these products, leaving the skin feeling nourished and supple.
Lameform TGI (Polyglyceryl-3 Diisostearate) is often included in sunscreen formulations to improve their spreadability and ensure even coverage on the skin.

Lameform TGI (Polyglyceryl-3 Diisostearate) helps disperse the active sunscreen ingredients evenly throughout the formulation, enhancing the product's efficacy.
In makeup products such as foundations, BB creams, and concealers, Lameform TGI (Polyglyceryl-3 Diisostearate) functions as an emulsifier and texture enhancer.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps create smooth, blendable textures that glide effortlessly onto the skin, providing a flawless finish.

Some cleansing formulations, such as facial cleansers and body washes, contain Lameform TGI (Polyglyceryl-3 Diisostearate) to improve their texture and emulsification properties.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps the formulation effectively remove dirt, oil, and makeup while leaving the skin feeling clean and refreshed.
Lameform TGI (Polyglyceryl-3 Diisostearate) can also be used in haircare products such as shampoos, conditioners, and styling products.

Lameform TGI (Polyglyceryl-3 Diisostearate) helps emulsify the ingredients in these formulations, improving their stability and performance while enhancing the texture and manageability of the hair.
Due to its mild and non-irritating properties, Lameform TGI (Polyglyceryl-3 Diisostearate) is suitable for use in formulations designed for sensitive skin.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps minimize the risk of skin irritation or allergic reactions, making it an ideal choice for gentle skincare products.

Lameform TGI (Polyglyceryl-3 Diisostearate) can be used in natural and organic cosmetic formulations as a plant-derived emulsifier.
Lameform TGI (Polyglyceryl-3 Diisostearate) allows formulators to create natural skincare products that meet consumer demand for clean, green beauty options.
In anti-aging skincare products, Lameform TGI (Polyglyceryl-3 Diisostearate) helps improve the texture and appearance of the skin, reducing the appearance of fine lines and wrinkles.

Its moisturizing properties help hydrate and plump the skin, giving it a more youthful and radiant appearance.
From body lotions and creams to body scrubs and massage oils, Lameform TGI (Polyglyceryl-3 Diisostearate) is a versatile ingredient used in various body care formulations.
Lameform TGI (Polyglyceryl-3 Diisostearate) helps enhance the texture, spreadability, and moisturizing properties of these products, leaving the skin feeling soft, smooth, and nourished.

Safety profile:
Lameform TGI (Polyglyceryl-3 Diisostearate) is considered to be safe for use in cosmetics.
Lameform TGI (Polyglyceryl-3 Diisostearate) is not known to cause allergy, irritation, toxicity or carcinogenicity.
In some individuals, Lameform TGI (Polyglyceryl-3 Diisostearate) may cause skin irritation or allergic reactions, especially in those with sensitive skin or pre-existing skin conditions.

Lameform TGI (Polyglyceryl-3 Diisostearate)'s important to perform patch testing before using products containing this ingredient, particularly if you have a history of skin sensitivity.
Contact with the eyes may cause irritation or discomfort.
Avoid direct contact with the eyes and rinse thoroughly with water if accidental exposure occurs.

Inhalation: Inhalation of airborne particles or aerosols containing Lameform TGI (Polyglyceryl-3 Diisostearate) may cause respiratory irritation in sensitive individuals.
Ensure adequate ventilation when handling powdered forms of the substance and use appropriate respiratory protection if necessary.
While Lameform TGI (Polyglyceryl-3 Diisostearate) is not intended for ingestion, accidental ingestion of large quantities may cause gastrointestinal discomfort or irritation.

Keep products containing this ingredient out of reach of children and pets, and seek medical attention if ingestion occurs.
Lameform TGI (Polyglyceryl-3 Diisostearate) is considered biodegradable, excessive discharge into the environment may contribute to water pollution.
Dispose of unused products properly and follow local regulations for wastewater treatment and disposal.

LAMEPON S
DESCRIPTION:

LAMEPON S is an anionic & co-surfactant.
LAMEPON S belongs to the product class of protein fatty acid condensates which account of its very good physiological characteristics.
LAMEPON S improves the skin and eye mucosa compatibility of basic surfactants and/or surfactant systems.
LAMEPON S is used in mild shower, foam baths, shampoos and body cleansers.

LAMEPON S is Co-surfactant suitable for mild shower and foam baths as well as shampoos and body cleansers.
Lamepon S belongs to the product class of protein fatty acid condensates which account of its excellent physiological characteristics is highly suited for use in mild shower and foam baths as well as in shampoos and body cleansers.
As co-surfactant Lamepon S clearly improves the skin and eye mucosa compatibility of basic surfactants and/or surfactant systems.

CHEMICAL AND PHYSICAL PROPERTIES OF LAMEPON S:
Chemical Function: Protein
Product Applications: Bath & Shower, Hand Cleansing, Skin Cleansing


SAFETY INFORMATION ABOUT LAMEPON S:

First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product.
LAMP BLACK 101
LANETH-10, N° CAS : 61791-20-6. Nom INCI : LANETH-10. Classification : Composé éthoxylé. Ses fonctions (INCI). Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
LAMP BLACK 101 (CARBON BLACK)
Lamp black 101 (Carbon Black) is a finely divided form of carbon.
Lamp black 101 (Carbon Black) may ignite explosively if suspended in air in the presence of an ignition source or slowly undergo spontaneous combustion upon contact with water.
In addition, Lamp black 101 (Carbon Black) is toxic by inhalation, with a TLV of 3.5 mg/m3 in air.

CAS: 1333-86-4
MF: C
MW: 12.01
EINECS: 215-609-9

Lamp black 101 (Carbon Black) is a black pigment that is used in the manufacture of paints, inks, and other products.
Lamp black 101 (Carbon Black) has high values of thermal expansion and adsorption properties.
Lamp black 101 (Carbon Black) has been used as an adsorbent for the removal of chemical pesticides from wastewater.
Lamp black 101 (Carbon Black) also has been used to remove phenols and organic matter from water by adsorption.
The optimum concentration of carbon black is between 0.5% and 1%.
The concentration-time curve for activated carbon shows a rapid initial rise followed by a slower rate of increase.
This curve occurs due to the fast absorption capacity of activated carbon, which leads to rapid uptake rates in the early stages before saturation occurs.

Primary uses are in the manufacture of tires, belt covers, plastics, carbon paper, colorant for printing inks, and as a solar-energy absorber.
A finely divided form of carbon, practically all of which is made by burning vaporized heavy-oil frac- tions in a furnace with 50% of the air required for complete combustion (partial oxidation).
This type is also called furnace black.
Carbon black can also be made from methane or natural gas by crack- ing (thermal black) or direct combustion (channel black), but these methods are virtually obsolete.
All types are characterized by extremely fine particle size, which accounts for their reinforcing and pig- menting effectiveness.

Multi walled carbon nanotubes (MWNTs, CNTs) were prepared by chemical vapor deposition (CVD).
In chemical vapor deposition (CVD), a volatile precursor undergoes thermal decomposition at elevated temperatures to form a solid deposit on a substrate.
1 Carboxylic acid groups can be attached to the defect sides and ends of the nanotube by treatment with oxidizing agents.
Carboxylic acid groups can be easily derivatized into different functional groups.

Lamp black 101 (Carbon Black) (with subtypes acetylene black, channel black, furnace black, lamp black and thermal black) is a material produced by the incomplete combustion of coal tar, vegetable matter, or petroleum products, including fuel oil, fluid catalytic cracking tar, and ethylene cracking in a limited supply of air.
Lamp black 101 (Carbon Black) is a form of paracrystalline carbon that has a high surface-area-to-volume ratio, albeit lower than that of activated carbon.

Lamp black 101 (Carbon Black) is dissimilar to soot in its much higher surface-area-to-volume ratio and significantly lower (negligible and non-bioavailable) polycyclic aromatic hydrocarbon (PAH) content.
However, Lamp black 101 (Carbon Black) can be used as a model compound for diesel soot to better understand how diesel soot behaves under various reaction conditions as carbon black and diesel soot have some similar properties such as particle sizes, densities, and copolymer adsorption abilities that contribute to them having similar behaviours under various reactions such as oxidation experiments.

Lamp black 101 (Carbon Black) is used as a colorant and reinforcing filler in tires and other rubber products; pigment and wear protection additive in plastics, paints, and ink pigment.
Lamp black 101 (Carbon Black) is used in the EU as a food colorant when produced from vegetable matter.
The current International Agency for Research on Cancer (IARC) evaluation is that, "Carbon black is possibly carcinogenic to humans (Group 2B)".
Short-term exposure to high concentrations of Lamp black 101 (Carbon Black) dust may produce discomfort to the upper respiratory tract through mechanical irritation.

Lamp black 101 (Carbon Black) Chemical Properties
Melting point: 3550 °C(lit.)
Boiling point: 500-600 °C(lit.)
Density: ~1.7 g/mL at 25 °C(lit.)
Vapor pressure: Fp: >230 °F
Solubility: H2O: soluble0.1mg/mL
Form: rod
Color: Clear colorless
Specific Gravity: bulk 0.10/g/cm3
Water Solubility: Insoluble
Merck: 14,1808
Exposure limits ACGIH: TWA 3 mg/m3
OSHA: TWA 3.5 mg/m3
NIOSH: IDLH 1750 mg/m3; TWA 3.5 mg/m3; TWA 0.1 mg/m3
Stability: Stable. Combustible.
InChIKey: VNWKTOKETHGBQD-UHFFFAOYSA-N
LogP: 1.090 (est)
IARC: 2B (Vol. Sup 7, 65, 93) 2010
EPA Substance Registry System: Lamp black 101 (Carbon Black) (1333-86-4)

Physical properties
Lamp black 101 (Carbon Black) is virtually pure elemental carbon (diamond and graphite are other forms of nearly pure carbon) in the form of near-spherical colloidal particles that are produced by incomplete combustion or thermal decomposition of gaseous or liquid hydrocarbons.
Lamp black 101 (Carbon Black)'s physical appearance is that of a black, finely divided pellet or powder, the latter sometimes small enough to be invisible to the naked eye.
Lamp black 101 (Carbon Black)'s use in tires, rubber and plastic products, printing inks and coatings is related to the properties of specific surface area, particle size and structure, conductivity and color.
Lamp black 101 (Carbon Black) is in the top 50 industrial chemicals manufactured worldwide, based on annual tonnage. Current worldwide production is about 15 billion pounds per year (6.81 million metric tons).

Approximately 90% of Lamp black 101 (Carbon Black) is used in rubber applications, 9% as a pigment, and the remaining 1% as an essential ingredient in hundreds of diverse applications.
Modern Lamp black 101 (Carbon Black) products are direct descendants of early “lampblack”, first produced in China over 3500 years ago.
These early lampblacks were not very pure and differed greatly in their chemical composition from current carbon blacks.
Since the mid-1970s most carbon black has been produced by the oil furnace process, which is most often referred to as furnace black.
Unlike diamond and graphite, which are crystalline carbons, Lamp black 101 (Carbon Black) is an amorphous carbon composed of fused particles called aggregates.
Properties, such as surface area, structure, aggregate diameter and mass differentiate the various carbon black grades.

Uses
1. Lamp black 101 (Carbon Black) is edible black pigment.
Lamp black 101 (Carbon Black) can be used for pastry with the usage amount of 0.001% to 0.1%.
2. Lamp black 101 (Carbon Black) can be used for food coloring agent.
China provides that Lamp black 101 (Carbon Black) can be used for rice, flour products, candy, biscuits and pastries with the maximum usage amount of 5.0g/kg.
3. Rubber industry uses Lamp black 101 (Carbon Black) as a reinforcing filler.
Paint Inks applies Lamp black 101 (Carbon Black) as coloring pigments in paint inks.
Used for the manufacturing of black paper such as packaging materials for photographic materials and the black paper made of high-conductivity black carbon in the radio equipment.
4. Carbon paper and typewriter; Lamp black 101 (Carbon Black) is used when it is required for darker colors and can remain on the carrier.
5. Plastic coloring, ink, phonograph records, shoe polish, paint cloth, leather coatings, colored cement, electrodes, electronic brushes, batteries and so on.

As electric conductive agent of lithium ion battery;
Mainly used for rubber, paint, ink and other industries;
6. Used for the reinforcement of car tread and sidewall, hose, groove, industrial rubber products as well as conveyor belt.
7. Used for tire tread, surface tire repair, automotive rubber parts, conveyor belts, conveyor pads, etc., The vulcanized glue of this carbon black shows excellent tensile strength and abrasion resistance
8. Lamp black 101 (Carbon Black) is mainly used for the reinforcement of tire belt, sidewall, solid tires, outer layer of roller, hose surface, industrial rubber products and car tire tread.
9. Lamp black 101 (Carbon Black) is used for the reinforcement of the tire tread of car and truck, surface of conveyor belt and industrial rubber products.
10. For rubber reinforcement, coloring agent, metallurgy, rocket propellant.

11. For rubber products to fill and reinforcement.
12. For rubber products, carcass, valves and other filling .
13. For paints and inks, plastics and other industries.
14. Mainly used for raw materials of battery as well as for conductive and anti-static rubber products.
15. In the rubber industry, Lamp black 101 (Carbon Black) is used as the reinforcing agent and filter for the manufacturing of natural rubber and butyl rubber, being able to endow the vulcanized rubber with excellent tensile strength, elongation and tear resistance and so on.
Lamp black 101 (Carbon Black) should be mostly used for natural rubber-based large-scale engineering tires and a variety of off-road tires as well as being used for carcass and sidewall.
In addition, Lamp black 101 (Carbon Black) can also be used for high-strength conveyor belt, cold rubber products and drilling device.
In light industry, Lamp black 101 (Carbon Black) can be used as the filter of the paint, ink, enamel and plastic products.

Lamp black 101 (Carbon Black) was used as conductive agent.
Super P furnace black the best conductive additive.
Lamp black 101 (Carbon Black) was added with binder in the composite electrode to compensate the low electrical conductivity of PPy and PPyDVB in miniemulsion polymerization.
The hybrid Super P-SACNT conductive network manifests itself as a promising strategy to improve the battery performances with a minimum amount of conductive fillers.

Tire treads, belt covers, and other abrasion- resistant rubber products; plastics as a reinforc- ing agent, opacifier, electrical conductor, UV- light absorber; colorant for printing inks;carbon paper; typewriter ribbons; paint pigment; nucleat- ing agent in weather modification; expanders in bat- tery plates; solar-energy absorber (see note).
In the rubber, plastic, printing, and paint industries as a reinforcing agent and a pigment
Lamp black 101 (Carbon Black) is a type of fine soot that is obtained from materials that have not been completely burned.
Lamp black 101 (Carbon Black) has various applications, including its use in polishing celluloid and bone.

Production method
Natural gas tank method of making carbon black: take natural gas as raw material and use iron pipe to send it into the combustion chamber.
The form of the combustion chamber can be either long and short and is made of iron plate.
Lamp black 101 (Carbon Black) contains a number of olefin burner inside it.
Natural gas is sprayed with appropriate force from the burner nozzle and burned in the case of insufficient air, that is, to generate a bright and black smoke flame.
The flame then goes directly into the channel iron with the distance between the burner and the slot surface being 65~80 mm.

At this time, the temperature of olefin burning is reduced from about 1000 to 1400 ° C to about 500 ° C, and the carbon black is accumulated.
The groove can move back and forth horizontally, with a moving speed of 3 to 4 mm/s.
In order to maintain normal production, the required amount of air is about 2.5 to 3 times the theoretical calculation.
The resulting carbon black was scraped into a funnel with a fixed doctor blade and sent to a central packing chamber for disposal.

Then the carbon black is softened, filtered to remove the hard particles and scale and further sent into the mill grinding to enable more uniform thickness.
However, the body is still very light and loose, thus should be shaken to a become a bit solid.
Then add a small amount of water to the carbon black to make Lamp black 101 (Carbon Black) into paste-like shape and have a small needle rotated inside Lamp black 101 (Carbon Black) to forming micro-pellets, followed by drying to obtain the finished product.
In the case of using pigment for carbon black, in order to facilitate the dispersion, the granulation is unnecessary.

The process is as follows:
Raw gas, air → combustion cracking → collection → granulation → packaging → finished product.
Carbon black is one of the oldest industrial products.
In ancient times, china has already applied incomplete combustion of vegetable oil for making pigment carbon black.
In 1872, the United States first used natural gas as raw material to produce carbon black using tank method and mainly used it as a coloring agent.
Lamp black 101 (Carbon Black) was not until 1912 when Mott found the reinforcement effect carbon black on the rubber before the carbon black industry had gotten rapid development.
Then Lamp black 101 (Carbon Black) had successively developed of a variety of process methods.
At present, oil furnace method is the most efficient and most economical method with the oil furnace black production amount accounting for 70-90% of the total carbon black production. There are mainly furnace, slot method, thermal cracking, three methods.
Lamp black 101 (Carbon Black) is obtained by the carbonization of the plant material such as peat.
Lamp black 101 (Carbon Black) can also be derived from the carbonization of cocoa shell and beef bone or from the combustion of vegetable oil.

Health Hazard
There are no well demonstrated health hazards to humans from acute exposure to Lamp black 101 (Carbon Black).
Commercial carbon black is a spherical colloidal form of nearly pure carbon particles and aggregates with trace amounts of organic impurities adsorbed on the surface.
Potential health effects usually are attributed to these impurities rather than to the carbon itself.
Soots, by contrast, contain mixtures of particulate carbon, resins, tars, and so on, in a nonadsorbed state.

Synonyms
ACTIVATED CARBON DARCO G-60
ACTIVATED CHARCOAL NORIT
ACTIVATED CHARCOAL NORIT(R)
ACETYLENE BLACK
ACETYLENE CARBON BLACK
COSMETICBLACK(A3278)
CARBONBLACKTONER
9901LAMPBLACK
LANETH-10 ( Alcohols, lanolin, ethoxylated)
LANETH-15, N° CAS : 61791-20-6 / 84650-19-1, Nom INCI : LANETH-15, Classification : Composé éthoxylé, Ses fonctions (INCI). Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
LANETH-15 ( Alcohols, lanolin, ethoxylated)
LANETH-20, N° CAS : 61791-20-6, Nom INCI : LANETH-20, Classification : Composé éthoxylé, Ses fonctions (INCI). Agent nettoyant : Aide à garder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile).Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
LANETH-20 ( Alcohols, lanolin, ethoxylated )
LANETH-40, N° CAS : 61791-20-6. Nom INCI : LANETH-40. Classification : Composé éthoxylé. Ses fonctions (INCI). Agent nettoyant : Aide à garder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation.Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
LANETH-40 ( Alcohols, lanolin, ethoxylated)
LANETH-5, N° CAS : 61791-20-6, Nom INCI : LANETH-5, Classification : Composé éthoxylé. Ses fonctions (INCI). Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Agent d'entretien de la peau : Maintient la peau en bon état. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
LANETH-5 ( Alcohols, lanolin, ethoxylated )
SYNONYMS Wool fat; Wool grease; Wool wax; Woolwax ester;
LANOL 1688
Lanol 1688 is a very easy-to-emulsify emollient with a specific and complementary sensory profile.
Lanol 1688 is light, dry structure.


CAS Number: 90411-68-0
EC Number: 291-445-1
Chem/IUPAC Name: Hexanoic acid, 2-ethyl-, C16-18-alkyl esters
INCI: Cetearyl Ethylhexanoate
Molecular Formula: C24H48O2



Cetyl 2-ethylhexanoate, Cetyl Octanoate, Hexadecyl 2-ethylhexanoate, Hexadecyl Ester, Cetyl Ethylhexanoate, Cetearyl Octanoate, Perceline oil, Hexadecyl 2-ethylhexanoate, 59130-69-7, Cetyl 2-ethylhexanoate, cetyl ethylhexanoate, HEXANOIC ACID, 2-ETHYL-, HEXADECYL ESTER, 134647WMX4, EINECS 261-619-1, Schercemol CO, Exceparl HO, Tegosoft CO, UNII-134647WMX4, Cetearyl octanoate, Pelemol 168, Hest CSO (Salt/Mix), Crodamol CAP (Salt/Mix), EC 261-619-1, Tegosoft liquid (Salt/Mix), SCHEMBL15239, Lanol 1688 (Salt/Mix), 90411-68-0, DTXSID20866741, XJNUECKWDBNFJV-UHFFFAOYSA-N, 2-Ethylhexanoic acid, cetyl ester, CETYL ETHYLHEXANOATE [INCI], AKOS028108429, BENZALDEHYDEPROPYLENEGLYCOLACETAL, DB11349, Q27251471, Hexanoic acid, 2-ethyl-, C16-18-alkyl esters, CETYL ETHYLHEXANOATE, 134647WMX4, UNII:134647WMX4, Hexanoic acid, 2-ethyl-, hexadecyl ester, EINECS 261-619-1, Hexadecyl 2-ethylhexanoate,



Lanol 1688 is the ester of cetearyl alcohol and 2-ethylhexanoic acid and was formerly called cetearyl octanoate.
Lanol 1688 is a transparent, oil-like, water-resistant liquid that protects skin from moisture loss by acting as an emollient.
Lanol 1688, which has a comparable chemical makeup but slightly different properties and safety, should not be confused with this ingredient.


Lanol 1688 is easy to spread.
Lanol 1688 is a clear/colorless to pale yellow liquid.
Lanol 1688 is an oil that is compatible with all skin care products due to its rapid absorption into the skin, its soft, non-greasy feel, non-stickiness, easy emulsification and resistance to oxidation.


Lanol 1688 acts as a liquid emollient agent.
Lanol 1688 is preservative-free and extremely easy to spread, for light textures and a soft feel.
Lanol 1688 improves the skin's suppleness.


Lanol 1688 is easy to spread emollient, for light textures
The liquid emollient agent Lanol 1688 is extremely easy to spread, for light textures and a soft feel.


Commercially, Lanol 1688 is produced through the catalytic esterification of cetearyl alcohol and 2-ethylhexanoic acid, with the removal step being an azeotropic distillation.
Cetyl octanoate and stearyl octanoate can also be combined in a 7:2 weight ratio to create the product.



USES and APPLICATIONS of LANOL 1688:
Application of Lanol 1688: Hair care, skin care, hygiene, sun protection
Lanol 1688 acts as a liquid emollient agent.
Lanol 1688 is preservative-free and extremely easy to spread, for light textures and a soft feel.


Lanol 1688 improves the skin's suppleness.
Lanol 1688 is easy to spread emollient, for light textures
The liquid emollient agent Lanol 1688 is extremely easy to spread, for light textures and a soft feel.


Lanol 1688 is used in all types of skincare formula, suncare, make-up.
Lanol 1688 is an emollient oil which is distinguished by excellent application on the skin, fast absorption into the skin, a soft non-greasy, non-sticky feel, very easy emulsification and a good resistance to oxidation.


Applications of Lanol 1688: Skin Care, Hair Care, Hygiene, Make-Up, and Sun Care.
Lanol 1688 is a synthetic mixture of fatty acids imparts water repelling characteristics to cosmetics; it is also a moisturising ingredient.


-Skin care:
Lanol 1688 smooths and softens the skin.
Lanol 1688 adds a sophisticated spreadability to creams and lotions and is oxygen-stable in addition to its moisturizing qualities.
In leave-on products, Lanol 1688 can be used up to 35% of the time.

Additionally, Lanol 1688 serves as a replacement for whale-derived spermaceti wax.
Numerous cosmetic products, including foundation, facial moisturizers, lipsticks, lip glosses, lip/eye liners, conditioners, and anti-aging products, contain Lanol 1688.



FUNCTION OF LANOL 1688:
Liquid emollient ester similar to the natural oil derived from waterfowl.
Spreads evenly on the skin to impart velvety softness, and leaves a long-lasting silky feel to the skin.


WHAT IS LANOL 1688 USED FOR?
Lanol 1688 works as an emoliient, texture enhancer and a conditioning agent in cosmetics and personal care products.


CLAIMS OF LANOL 1688:
*Emollients > Esters
spreading
preservative-free
softness
light feeling



ALTERNATIVE OF LANOL 1688:
*CETYL ETHYLHEXANOATE,
*ETHYLHEXYL ETHYLHEXANOATE,
*ISODECYL ETHYLHEXANOATE


PROPERTIES OF LANOL 1688:
*Improves the skin's suppleness
*Very easy to spread
*Soft, light, dry feel


SPECIFICITIES OF LANOL 1688:
*Liquid presentation
*Preservative-free
*Lanol 1688 is covered by a Mass Balance certificate BVC-RSPO-1-1972708497.


SAFETY PROFILE OF LANOL 1688:
The safety of 16 alkyl ethylhexanoates, including Lanol 1688, as used in cosmetics was evaluated by the Cosmetic Ingredient Review (CIR) Expert Panel.
The panel looked over any clinical data on these ingredients that was available.
The panel came to the conclusion that these ingredients are safe when used in cosmetic formulations under the current usage and concentration patterns when they are made to be non-irritating.



PHYSICAL and CHEMICAL PROPERTIES of LANOL 1688:
Name: LANOL 1688
INCI: Cetearyl Ethylhexanoate
Form: Liquid
Color: Colorless
Certification: Ecocert&Cosmos&Nature
Boiling Point: 431.86°C
Solubility: Insoluble in water
Molecular Weight: 368.6 g/mol
XLogP3-AA: 10.7
Hydrogen Bond Donor Count: 0
Hydrogen Bond Acceptor Count: 2
Rotatable Bond Count: 21

Exact Mass: 368.365430770 g/mol
Monoisotopic Mass: 368.365430770 g/mol
Topological Polar Surface Area: 26.3Ų
Heavy Atom Count: 26
Formal Charge: 0
Complexity: 288
Isotope Atom Count: 0
Defined Atom Stereocenter Count: 0
Undefined Atom Stereocenter Count: 1
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes
CAS Number: 90411-68-0
Molecular Formula: C24H48O2

Molecular Weight: 368.637
Chemical Name: Hexanoic acid, 2-ethyl-, C16-18-alkyl esters
CAS Registry Number: 90411-68-0
PubChemID: 42956
Molecular Weight: 368.63672
LogP: 11.15
EINECS: 291-445-1
Molecular Formula: C24H48O2
Density: 0.9±0.1 g/cm3
Boiling Point: 407.2±13.0 °C at 760 mmHg
Flash Point: 203.7±9.7 °C
Refractive Index: 1.449



FIRST AID MEASURES of LANOL 1688:
-Description of first-aid measures:
*General advice:
Show this material safety data sheet to the doctor in attendance.
*If inhaled:
After inhalation:
Fresh air.
Call in physician.
*In case of skin contact:
Take off immediately all contaminated clothing.
Rinse skin with water/ shower.
Consult a physician.
*In case of eye contact:
After eye contact:
Rinse out with plenty of water.
Immediately call in ophthalmologist.
Remove contact lenses.
*If swallowed:
After swallowing:
Immediately make victim drink water (two glasses at most).
Consult a physician.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LANOL 1688:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Observe possible material restrictions.
Take up dry.
Dispose of properly.
Clean up affected area.



FIRE FIGHTING MEASURES of LANOL 1688:
-Extinguishing media:
*Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
-Further information:
Prevent fire extinguishing water from contaminating surface water or the ground water system.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LANOL 1688:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
Tightly fitting safety goggles
*Skin protection:
Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
Splash contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
*Body Protection:
protective clothing
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LANOL 1688:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.
Dry.
Store at Room Temperature.
Light sensitive



STABILITY and REACTIVITY of LANOL 1688:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Incompatible materials:
No data available


LANOLIN
DESCRIPTION:

Lanolin (from Latin lāna 'wool', and oleum 'oil'), also called wool fat, wool yolk, wool wax, or wool grease, is a wax secreted by the sebaceous glands of wool-bearing animals.
Lanolin used by humans comes from domestic sheep breeds that are raised specifically for their wool.
Historically, many pharmacopoeias have referred to lanolin as wool fat (adeps lanae); however, as lanolin lacks glycerides (glycerol esters), it is not a true fat.

CAS: 8006-54-0
European Community (EC) Number: 232-348-6


Lanolin primarily consists of sterol esters instead.
Lanolin's waterproofing property aids sheep in shedding water from their coats.
Certain breeds of sheep produce large amounts of lanolin.


Lanolin is a principle component of lanolin, which is a natural product obtained from the fleece of sheep.
Lanolin is found in steroid-containing creams/ointments, medicated shampoos, veterinary products, hand lotions, moisturizers, sunscreens, self-tanning creams, lipsticks, makeup removers, foundations, eye shadows, hairsprays, shaving creams, baby oils and products, printing inks, furniture and shoe polishes, lubricants, leather, and paper.

Lanolin's role in nature is to protect wool and skin from climate and the environment; it also plays a role in skin (integumental) hygiene.
Lanolin and its derivatives are used in the protection, treatment, and beautification of human skin

Lanolin is a yellow fat obtained from sheep's wool.
It is used as an emollient, cosmetic, and pharmaceutic aid.
The US federal code of regulations states that lanolin in the concentration range of 12-50% may be included in over the counter skin ointments.
Lanolin is the purified, secreted product of the sheep sebaceous glands.
Lanolin primarily consists of long-chain waxy esters, or sterol esters, that lack glycerides.

For this reason, it is also called wool wax or wool grease.
Lanolin is used in the protection, treatment, and cosmetic enhancement of human skin.
Its hydrophobic properties can help protect skin against infections or skin irritation, as it helps seal in moisture that is already present in the skin.

Lanolin is used as an active ingredient in over the counter topical products such as ointments, lubricants, lotions and facial cosmetics.
Lanolin is also frequently used in protective baby skin treatment and for sore nipples in breastfeeding mothers,.



COMPOSITION OF LANOLIN :
A typical high-purity grade of lanolin is composed predominantly of long chain waxy esters (approximately 97% by weight) with the remainder being lanolin alcohols, lanolin acids and lanolin hydrocarbons.
An estimated 8,000 to 20,000 different types of lanolin esters are present in lanolin, resulting from combinations between the 200 or so different lanolin acids and the 100 or so different lanolin alcohols identified so far.


Lanolin’s complex composition of long-chain esters, hydroxyesters, diesters, lanolin alcohols, and lanolin acids means in addition to its being a valuable product in its own right, it is also the starting point for the production of a whole spectrum of lanolin derivatives, which possess wide-ranging chemical and physical properties.
The main derivatisation routes include hydrolysis, fractional solvent crystallisation, esterification, hydrogenation, alkoxylation and quaternisation.


Lanolin derivatives obtained from these processes are used widely in both high-value cosmetics and skin treatment products.
Hydrolysis of lanolin yields lanolin alcohols and lanolin acids.
Lanolin alcohols are a rich source of cholesterol (an important skin lipid) and are powerful water-in-oil emulsifiers; they have been used extensively in skincare products for over 100 years.

Approximately 40% of the acids derived from lanolin are alpha-hydroxy acids (AHAs).
The use of AHAs in skin care products has attracted a great deal of attention in recent years.
Details of the AHAs isolated from lanolin can be seen in the table below.


PRODUCTION OF LANOLIN :
Crude lanolin constitutes about 5–25% of the weight of freshly shorn wool.
The wool from one Merino sheep will produce about 250–300 ml of recoverable wool grease.
Lanolin is extracted by washing the wool in hot water with a special wool scouring detergent to remove dirt, wool grease (crude lanolin), suint (sweat salts), and anything else stuck to the wool.

The wool grease is continuously removed during this washing process by centrifuge separators, which concentrate it into a waxlike substance melting at approximately 38 °C (100 °F).


APPLICATIONS OF LANOLIN :
Lanolin and its many derivatives are used extensively in both the personal care (e.g., high value cosmetics, facial cosmetics, lip products) and health care sectors such as topical liniments.
Lanolin is also found in lubricants, rust-preventive coatings, shoe polish, and other commercial products.
Lanolin is a relatively common allergen and is often misunderstood as a wool allergy.


However, allergy to a lanolin-containing product is difficult to pinpoint and often other products containing lanolin may be fine for use.
Patch testing can be done if a lanolin allergy is suspected.
It is frequently used in protective baby skin treatment and for sore nipples from breastfeeding although health authorities do not recommend it, advise against nipple cleaning and rather recommend improving baby positioning and expressing milk by hand.

Lanolin is used commercially in many industrial products ranging from rustproof coatings to lubricants.
Some sailors use lanolin to create slippery surfaces on their propellers and stern gear to which barnacles cannot adhere.

Commercial products (e.g. Lanocote) containing up to 85% lanolin are used to prevent corrosion in marine fasteners, especially when two different metals are in contact with each other and saltwater.
The water-repellent properties make it valuable in many applications as a lubricant grease where corrosion would otherwise be a problem.
7-Dehydrocholesterol from lanolin is used as a raw material for producing vitamin D3 by irradiation with ultraviolet light.


Baseball players often use it to soften and break in their baseball gloves (shaving cream with lanolin is popularly used for this).
Anhydrous liquid lanolin, combined with parabens, has been used in trials as artificial tears to treat dry eye.

Anhydrous lanolin is also used as a lubricant for brass instrument tuning slides.
Lanolin can also be restored to woollen garments to make them water and dirt repellent, such as for cloth diaper covers.
Lanolin is also used in lip balm products such as Carmex.

For some people, it can irritate the lips.
Lanolin is sometimes used by people on continuous positive airway pressure therapy to reduce irritation with masks, particular nasal pillow masks that can often create sore spots in the nostrils.
Lanolin is a popular additive to moustache wax, particularly 'extra-firm' varieties.

Lanolin is used as a primary lubricating component in aerosol-based brass lubricants in the ammunition reloading process.
Mixed warm 1:12 with highly concentrated ethanol (usually 99%), the ethanol acts as a carrier which evaporates quickly after application, leaving a fine film of lanolin behind to prevent brass seizing in resizing dies.

Lanolin, when mixed with ingredients such as neatsfoot oil, beeswax and glycerol, is used in various leather treatments, for example in some saddle soaps and in leather care products.



STANDARDS AND LEGISLATION ABOUT LANOLIN :
In addition to general purity requirements, lanolin must meet official requirements for the permissible levels of pesticide residues.
The Fifth Supplement of the United States Pharmacopoeia XXII published in 1992 was the first to specify limits for 34 named pesticides.
A total limit of 40 ppm (i.e. 40 mg/kg) total pesticides was stipulated for lanolin of general use, with no individual limit greater than 10 ppm.


A second monograph also introduced into the US Pharmacopoeia XXII in 1992 was entitled 'Modified Lanolin'.
Lanolin conforming to this monograph is intended for use in more exacting applications, for example on open wounds.
In this monograph, the limit of total pesticides was reduced to 3 ppm total pesticides, with no individual limit greater than 1 ppm.


In 2000, the European Pharmacopoeia introduced pesticide residue limits into its lanolin monograph.
This requirement, which is generally regarded as the new quality standard, extends the list of pesticides to 40 and imposes even lower concentration limits.
Some very high-purity grades of lanolin surpass monograph requirements.

New products obtained using complex purification techniques produce lanolin esters in their natural state, removing oxidative and environmental impurities resulting in white, odourless, hypoallergenic lanolin.
These ultra-high-purity grades of lanolin are ideally suited to the treatment of dermatological disorders such as eczema and on open wounds.

Lanolin attracted attention owing to a misunderstanding concerning its sensitising potential.
A study carried out at New York University Hospital in the early 1950s had shown about 1% of patients with dermatological disorders were allergic to the lanolin being used at that time.

By one estimate, this simple misunderstanding of failing to differentiate between the general healthy population and patients with dermatological disorders exaggerates the sensitising potential of lanolin by 5,000–6,000 times.


The European Cosmetics Directive, introduced in July 1976, contained a stipulation that cosmetics which contained lanolin should be labelled to that effect.
This ruling was challenged immediately, and in the early 1980s, it was overturned and removed from the directive.
Despite only being in force for a short period of time, this ruling did harm both to the lanolin industry and to the reputation of lanolin in general.

The Cosmetics Directive ruling only applied to the presence of lanolin in cosmetic products; it did not apply to the many hundreds of its different uses in dermatological products designed for the treatment of compromised skin conditions.

Modern analytical methods have revealed lanolin possesses a number of important chemical and physical similarities to human stratum corneum lipids; the lipids which help regulate the rate of water loss across the epidermis and govern the hydration state of the skin.

Cryogenic scanning electron microscopy has shown that lanolin, like human stratum corneum lipids, consists of a mass of liquid crystalline material.
Cross-polarised light microscopy has shown the multilamellar vesicles formed by lanolin are identical to those formed by human stratum corneum lipids.
The incorporation of bound water into the stratum corneum involves the formation of multilamellar vesicles.

Skin bioengineering studies have shown the durational effect of the emollient (skin smoothing) action produced by lanolin is very significant and lasts for many hours.
Lanolin applied to the skin at 2 mg/cm2 has been shown to reduce roughness by about 35% after one hour and 50% after two hours, with the overall effect lasting for considerably more than eight hours.

Lanolin is also known to form semiocclusive (breathable) films on the skin.
When applied daily at around 4 mg/cm2 for five consecutive days, the positive moisturising effects of lanolin were detectable until 72 hours after final application.
Lanolin may achieve some of its moisturising effects by forming a secondary moisture reservoir within the skin.

The barrier repair properties of lanolin have been reported to be superior to those produced by both petrolatum and glycerol.
In a small clinical study conducted on volunteer subjects with terribly dry (xerotic) hands, lanolin was shown to be superior to petrolatum in reducing the signs and symptoms of dryness and scaling, cracks and abrasions, and pain and itch.
In another study, a high purity grade of lanolin was found to be significantly superior to petrolatum in assisting the healing of superficial wounds.



PRODUCTS THAT MAY CONTAIN LANOLIN :
Cosmetics
• Foundations
• Eye makeup
• Lipsticks

Hair Care
• Hairspray

Household Products
• Furniture polish
• Leather
• Paper
• Printing inks

Liquids
• Baby oils
• Baby ointments
• Hand lotion
• Moisturizers
• Self-tanners
• Sunscreen


SAFETY INFORMATION ABOUT LANOLIN :
First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product






SYNONYMS OF LANOLIN :
Lanolin
8006-54-0
7EV65EAW6H
Anhydrous lanolin
Wool grease
Wool wax, refined
Black Rose
Lanashield
Lanolin, anhydrous
Skin Protectant with Lanolin
Theresienol MD Skin Protectant
Theriac Advanced Healing
232-348-6
3CE DRAWING LIP CHILLING
4sport skincare anti chafing
AGNOLIN NO 1
AmeriDermDermaFix
CORONA MULTI-PURPOSE
CORONA ORIGINAL LANOLIN RICH
DTXSID2027678
EMERY 1600
EUCERITE
LANOLIN (II)
LANOLIN (USP MONOGRAPH)
LANOLIN (USP-RS)
LANOLIN,ANHYDROUS LIQUID
Lana1263
LanoGuardDaily Care Skin Protectant
LanoGuardDry Skin Therapy
Lanoderm
Lantiseptic Dry Skin Therapy
Lantiseptic by DermaRite Original Skin Protectant
Lantiseptic by Dermarite Dry Skin Therapy
LincoFix
North Country Dairy Supply Non Iodine Barrier Dip
PrimaGuardDaily Care Skin Protectant
SUINTINE
Smartchoices Lanolin Plus0
Soothe and Cool Free Medseptic
Soothe and Cool Free MedsepticSkin Protectant
LANOLIN
LANOLIN; Wool fat; Wool grease; Wool wax; Woolwax ester; cas no: 8006-54-0
LANOLIN (COSMETIC GRADE)
DESCRIPTION:

Lanolin (Cosmetic Grade), a natural substance derived from sheep's wool, is a commonly used ingredient in cosmetics and skincare products.
Lanolin (Cosmetic Grade) consists of a combination of lanolin oil and lanolin alcohol.
Extracted from wool grease, lanolin is purified to obtain anhydrous lanolin, which is free of water content.

CAS Number, 8006-54-0
EINECS/ELINCS No:, 232-348-6
COSING REF No:, 34857


SYNOYMS OF LANOLIN (COSMETIC GRADE):
Lanolin;Agnolin No. 1;Alapurin;Anhydrous lanolin;Anhydrous Lanum;Lanain;Lanalin;Lanesin;Lanichol;Laniol;Oesipos;Agnolin;Adeps lane;Amber lanolin;Lanum;Processed lanolin;Cosmelan;Lantrol;Fats,lanolin;Fats,wool;Lanoprodine;Crodapur;Argowax;Clearlan 1650;Clearlan;HHC 82;FPG 1;Lanox HHC 82;Lanox HH 73;Lanox FPG 103;Lanox FPG 105;Lanox CNB 500;Lanox FP 1410N;Fats and Glyceridic oils,wool;Fats and Glyceridic oils,lanolin;Emery HP 2050;Lanox FP 85N;Lanox FP 8;Lanox FPK 108;Lanox CNB 50;Wool wax,lanolin;Coronet;Lanox CNB 80;Medilan;Super Lanolin;Natralube 210;Furuiran SP;Furuiran T;Fluilan T;E 913;Rikaranoru;Rikalanol;Medilan Ultra;Crodamol ODL;Lanolin TR;Corilene UL;TJ-F 402;YOFCO;Lanolins;Super Lanolin SO;Corona 8;Adeps Lanae;114471-15-7;8036-05-3;8038-41-3;8038-43-5;8040-96-8




In the world of cosmetics, Lanolin (Cosmetic Grade) is known by various names such as wool wax, wool fat, or Adeps Lanae.
Lanolin (Cosmetic Grade) is essential to note that lanolin is not a steroid but rather a complex blend of lipids.
Lanolin (Cosmetic Grade) imparts moisturizing, emollient, and protective properties, making it a valued component in skincare formulations.
The chemical formula of Lanolin (Cosmetic Grade) is C34H68O2.

Lanolin (Cosmetic Grade) is a wax that comes from the wool of animals.
Usually, wool from sheep is used to extract Lanolin (Cosmetic Grade).

Lanolin (Cosmetic Grade) is a naturally forming yellowish waxy substance.
Lanolin (Cosmetic Grade) is also called 'wool wax'.

A regular ingredient in many cosmetic products, although loosing favour to vegetable products these days, Lanolin (Cosmetic Grade) is mostly used as a moisturiser.
Lanolin (Cosmetic Grade) is an excellent emollient, better than petrolatum or glycerin.
There is also a chemical similarity between human skin and lanolin.
Pure Lanolin (Cosmetic Grade) will be yellowish-brown in colour.

Lanolin (Cosmetic Grade) has long been hailed from the Ancient Greeks and Chinese as an essential ingredient for Skin care; nourishing, protecting, anti-aging, and helping to heal dry and cracked skin.
Lanolin (Cosmetic Grade) sinks deep into your skin.
Lanolin (Cosmetic Grade) keeps your skin moisturised on the surface but also helps it stay hydrated from within.
Lanolin (Cosmetic Grade) Beauty capture the purity and quality of Australian cosmetic grade Lanolin to offer unique everyday skincare.


Lanolin (Cosmetic Grade), USP is a great skin protectorate and conditioner.
Lanolin (Cosmetic Grade) helps with chaffing and skin irritation due to moisture loss and makes for the perfect skincare product for nursing mothers.
Lanolin (Cosmetic Grade), USP can be used for moisturizing dry skin and eczema, as well as healing cuts, scrapes and burns, and boost color in lip products.


Lanolin (Cosmetic Grade) has a wide range of applications because of its colloidal chemical Properties and compatibility with a broad range of ingredients.
Lanolin (Cosmetic Grade) is useful in pharmaceutical preparations, salves and ointments, as well as having functional attributes as an epidermal moisturizer, lubricant and emollient.
Lanolin (Cosmetic Grade) can also be used for other industrial applications, such as waterless hand cleaners, printing inks, can coatings, corrosive inhibitors and lubricants.


Lanolin Cosmetic Grade is a purified sterol rich compound.
Lanolin (Cosmetic Grade) has a lower cholesterol content compared to some superior pharmaceutical grades.
Lanolin (Cosmetic Grade) is soluble in mineral oil, ethanol, chloroform, ether, petroleum ether, and toluene.

Lanolin (Cosmetic Grade) is not soluble in water.
Lanolin (Cosmetic Grade) can be widely used in w/o emulsion.
It's an excellent emulsifier, stabilizer, thickener, and emollient in hair care and skin care products.



Lanolin (Cosmetic Grade) is a product of Lanolin wax.
The lanolin wax is subjected to low temperature fractional crystallization.
This isolates the liquid esters of the regular anhydrous lanolin.

In formulations and recipes it provides a lighter texture than Lanolin wax.
Lanolin (Cosmetic Grade) can also be used as a mineral oil substitute in any formulation.
Lanolin (Cosmetic Grade) is a great emollient and provides protection for the epidermis from moisture loss.

Lanolin (Cosmetic Grade) softens the skin and is a good humectant making it ideal for use in balms, hair treatments and conditioners, body oils, bath oils, rich creams, cosmetics and other products.
Lanolin (Cosmetic Grade) can also be used to treat chapped lips, diaper rash, dry skin, itchy skin, rough feet, minor cuts, minor burns and skin abrasions.


Lanolin (Cosmetic Grade) helps to form emulsions and blends well with nearly all other substances used in cosmetics and personal care products.
Pharmaceutical grade segment is highly demanded, as lanolin and its derivatives find wide utilization in medicinal and personal care applications.







USES OF LANOLIN (COSMETIC GRADE):
Lanolin (Cosmetic Grade) has many different uses in the world of skin care and cosmetics.
From providing moisturizing benefits to enhancing the texture of the products - this ingredient does it all.

Skin care:
Lanolin (Cosmetic Grade) is valued for its exceptional moisturizing properties.
Lanolin (Cosmetic Grade) acts as a natural emollient, creating a protective barrier that helps to prevent moisture loss and keeps the skin hydrated.
Lanolin (Cosmetic Grade) is often incorporated into creams, lotions, and lip balms to alleviate dryness, soothe rough or chapped skin, and promote softness and suppleness

Cosmetic products:
Lanolin (Cosmetic Grade) serves as a binding agent, helping to hold cosmetic formulations together and providing stability.
Lanolin (Cosmetic Grade) can also enhance the texture and spreadability of products, contributing to a smooth application

Lanolin (Cosmetic Grade) is used as Emulsifier.
Lanolin (Cosmetic Grade) is used as Antifoaming agent.
Lanolin (Cosmetic Grade) is used as Rust inhibitor.

Lanolin (Cosmetic Grade) is used as Corrosion inhibitor.
Lanolin (Cosmetic Grade) is used as Pharmaceutical additives.
Lanolin (Cosmetic Grade) is used as Cosmetic preparation.

Gas chromatographic fixative (maximum use temperature 200℃, solvent is chloroform), separation and analysis of non-polar compounds, ethanol, aromatic and heterocyclic compounds and volatile oil.


ORIGIN OF LANOLIN (COSMETIC GRADE):
Lanolin (Cosmetic Grade) is obtained through a process of extracting and purifying the wool grease found in sheep's wool.
The wool grease is treated to remove impurities and excess water, resulting in the production of lanolin.
This refined Lanolin (Cosmetic Grade) is then further processed to obtain different forms, such as anhydrous lanolin or lanolin oil.




CHEMICAL AND PHYSICAL PROPERTIES OF LANOLIN (COSMETIC GRADE):

Melting Point, 38-40°C
pH, 5.5-7.0
Solubility, Insoluble in water
Viscosity, High
Physical form at 25°C: Solid
Product Name:
Lanolin
CAS No.:
8006-54-0
InChIKeys:
BILPUZXRUDPOOF-UHFFFAOYSA-N
Molecular Weight:
508.9
Exact Mass:
508.521931
EC Number:
232-348-6
HScode:
15050000
Categories:
Fungicides
PSA:
26.3
XLogP3:
log Kow = 15.60 (est)
Appearance:
White to yellow Adhering Crystals or Powder
Density:
0.932-0.945 g/cm3 @ Temp: 15 °C
Melting Point:
38-42 °C
Flash Point:
209 °C
Water Solubility:
soluble in ether, petroleum ether, chloroform and petroleum benzene.
Sparingly soluble in ethanol. Insoluble in water.chloroform: 0.1 g/mL, clear to faintly turbid (
Storage Conditions:
Lanolin may gradually undergo autoxidation during storage.
To inhibit this process, the inclusion of butylated hydroxytoluene is permitted as an antioxidant.
Exposure to excessive or prolonged heating may cause anhydrous lanolin to darken in color and develop a strong rancidlike odor.

However, lanolin may be sterilized by dry heat at 150°C.
Ophthalmic ointments containing lanolin may be sterilized by filtration or by exposure to gamma irradiation.
Odor:
Slight odor or practically odorless

CHEMISTRY OF LANOLIN (COSMETIC GRADE):

Waxes
Functions
Emulsion stabilisers
Superfatting agents
Emulsifiers

REGIONAL AVAILABILITY OF LANOLIN (COSMETIC GRADE):

Asia
Europe
Latin America
N America

APPLICATIONS OF LANOLIN (COSMETIC GRADE):

Bath, shower & soaps
After sun
Body care
Eye contour care
Face / neck skin care
Hair conditioners - rinse off
Lip care
Lip colour
Shampoos
Shaving / hair removal
Sun protection

CONSUMER BENEFIT:
Hydrating / moisturising / nourishing
Calming / soothing / redness


SAFETY INFORMATION ABOUT LANOLIN (COSMETIC GRADE):
First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product


LANOLIN (WOOL FAT)
Lanolin (Wool Fat) is a popular substance that is often used as a care product for cracked and dry skin.
Lanolin (Wool Fat) is a natural product that is obtained from the wool of sheep.
Lanolin (Wool Fat) is of high quality tested for pesticides and pollutants.


CAS Number: 8006-54-0
EC Number: 232-348-6
Molecular Formula: C34H68O2



SYNONYMS:
Adeps Lanae ahydricus, Adeps lanae, Adeps lane, Agnin, Agnolin, Agnolin No. 1, Alapurin, Amber lanolin, Anhydrous lanolin, Anhydrous lanum, Caswell No. 518, Clearlan, Clearlan 1650, Coronet, Cosmelan, Crodapur, EINECS 232-348-6, EPA Pesticide Chemical Code 031601, Emery HP 2050, FPG 1, Fats and Glyceridic oils, lanoline, Fats and Glyceridic oils, wool, Fats, lanolin, Fats, wool, HHC 82, HSDB 1817, Lanae cera, Lanain, Lanalin, Lanesin, Lanichol, Laniol, Lanolin, Lanolin oil, Lanolin, anhydrous, Lanoprodine, Lanox CNB 50, Lanox CNB 500, Lanox CNB 80, Lanox FP 1410N, Lanox FP 8, Lanox FP 85N, Lanox FPG 103, Lanox FPG 105, Lanox FPK 108, Lanox HH 73, Lanox HHC 82, Lantrol, Lanum, Medilan, Natralube 210, Oesipos, Processed lanolin, Super Lanolin, Wollfett, Wool fat, Wool grease, Wool wax, lanolin, Wool wax, refined, Lanolin 8006-54-0, 7EV65EAW6H, Anhydrous lanolin, Wool grease, Wool wax, refined, Black Rose, Lanashield, Lanolin, anhydrous, Skin Protectant with Lanolin, Theresienol MD Skin Protectant, Theriac Advanced Healing, 232-348-6, 3CE DRAWING LIP CHILLING, 4sport skincare anti chafing, AGNOLIN NO 1, AmeriDermDermaFix, CORONA MULTI-PURPOSE, CORONA ORIGINAL LANOLIN RICH, DTXSID2027678, EMERY 1600, EUCERITE, LANOLIN (II), LANOLIN (USP MONOGRAPH), LANOLIN (USP-RS), LANOLIN,ANHYDROUS LIQUID, Lana1263, LanoGuardDaily Care Skin Protectant, LanoGuardDry Skin Therapy, Lanoderm, Lantiseptic Dry Skin Therapy, Lantiseptic by DermaRite Original Skin Protectant, Lantiseptic by Dermarite Dry Skin Therapy, LincoFix, North Country Dairy Supply Non Iodine Barrier Dip, PrimaGuardDaily Care Skin Protectant, SUINTINE, Smartchoices Lanolin Plus0, Soothe and Cool Free Medseptic, Soothe and Cool Free MedsepticSkin Protectant, Wool fat, Adeps lanae



Lanolin (Wool Fat) is obtained from raw wool by kneading it in water, or by scouring with soap solution, and then centrifuging.
The wool grease so obtained is refined, bleached, deodorized, and dried.
Chemically, Lanolin (Wool Fat) consists of a mixture of several sterols, fatty acids, and their esters.


Lanolin (Wool Fat) is a yellow fat obtained from sheep's wool.
It is used as an emollient, cosmetic, and pharmaceutic aid.
The US federal code of regulations states that Lanolin (Wool Fat) in the concentration range of 12-50% may be included in over the counter skin ointments.


Lanolin (Wool Fat) is the purified, secreted product of the sheep sebaceous glands.
Lanolin (Wool Fat) primarily consists of long-chain waxy esters, or sterol esters, that lack glycerides.
For this reason, Lanolin (Wool Fat) is also called wool wax or wool grease.


Lanolin (Wool Fat) is used in the protection, treatment, and cosmetic enhancement of human skin.
Its hydrophobic properties can help protect skin against infections or skin irritation, as Lanolin (Wool Fat) helps seal in moisture that is already present in the skin.


Lanolin (Wool Fat) is a waxy substance that sheep naturally produce to protect their wool.
Because Lanolin (Wool Fat)'s properties are similar to those of the sebum (oil) secreted by human skin, it is a popular ingredient in moisturizers, hair care products, and soaps.


Lanolin (Wool Fat) is also widely promoted as a natural remedy for sore nipples due to breastfeeding.
The Lanolin (Wool Fat) in the products you buy comes from sheep raised for their wool.
Lanolin (Wool Fat) also goes by the names wool grease, wool yolk, and wool wax.


Lanolin (Wool Fat) is a popular substance that is often used as a care product for cracked and dry skin.
Lanolin (Wool Fat) is a natural product that is obtained from the wool of sheep.
Lanolin (Wool Fat) is of high quality tested for pesticides and pollutants.


At a temperature of 39 °C, Lanolin (Wool Fat) begins to become liquid.
True to the “DIY” motto, you can create your own creams and ointments with Lanolin (Wool Fat).
Lanolin (Wool Fat) is 'occlusive' meaning it prevents water evaporating from our skin.


It has been researched than Lanolin (Wool Fat) can reduce skin's water loss by as much as 20-30%.
Lanolin (Wool Fat) does not increase the moisture content of the skin, it only hold existing moisture.
Lanolin (Wool Fat) contains cholesterol similar to the cholesterol our skin naturally produces which is why Lanolin (Wool Fat) is so good for human skin.


Lanolin (Wool Fat) is safe, however if you have known allergies to it then it is best to not use it.
Allergies normally stem from the Lanolin (Wool Fat) not being refined to become purified.
Lanolin (Wool Fat) once separated from the wool, undergoes refining processes of up to 5 times to ensure the end product is free from as many impurities as possible.


The Merino breed of sheep produces the most amount of Lanolin (Wool Fat).
Lanolin (Wool Fat) is the naturally occurring fat in wool, which helps protect wool and skin against the environment.
Lanolin (Wool Fat) is the naturally occurring fat in wool


Lanolin (Wool Fat) helps protect the skin against the environment
Lanolin (Wool Fat) is preservative free.
Lanolin (Wool Fat), a natural substance derived from sheep's wool, is a commonly used ingredient in cosmetics and skincare products.


It consists of a combination of Lanolin (Wool Fat) oil and Lanolin (Wool Fat) alcohol.
Extracted from wool grease, Lanolin (Wool Fat) is purified to obtain anhydrous Lanolin (Wool Fat), which is free of water content.
In the world of cosmetics, Lanolin (Wool Fat) is known by various names such as wool wax, wool fat, or Adeps Lanae.


It is essential to note that Lanolin (Wool Fat) is not a steroid but rather a complex blend of lipids.
Lanolin (Wool Fat) imparts moisturizing, emollient, and protective properties, making it a valued component in skincare formulations.
The chemical formula of Lanolin (Wool Fat) is C34H68O2.


Lanolin (Wool Fat) is a wax made of a mixture of esters, diesters, and hydroxyl esters of high-molecular-weight Lanolin (Wool Fat) alcohols and high-molecular-weight Lanolin (Wool Fat) acids.
Lanolin (Wool Fat)'s role on the sheep is to protect the wool fibres and the skin from the environment including rain and direct sun.


Lanolin (Wool Fat) contains anti-fungal and anti-bacterial properties to protect the sheep's skin.
Lanolin (Wool Fat) (from Latin lāna 'wool', and oleum 'oil'), also called wool fat, wool yolk, wool wax, sheep grease, or wool grease, is a wax secreted by the sebaceous glands of wool-bearing animals.


Lanolin (Wool Fat) used by humans comes from domestic sheep breeds that are raised specifically for their wool.
Historically, many pharmacopoeias have referred to Lanolin (Wool Fat) as wool fat (adeps lanae); however, as Lanolin (Wool Fat) lacks glycerides (glycerol esters), it is not a true fat.


Lanolin (Wool Fat) primarily consists of sterol esters instead.
Lanolin (Wool Fat)'s waterproofing property aids sheep in shedding water from their coats.
Certain breeds of sheep produce large amounts of Lanolin (Wool Fat).


Lanolin (Wool Fat)'s role in nature is to protect wool and skin from climate and the environment; it also plays a role in skin (integumental) hygiene.
Lanolin (Wool Fat) is a popular additive to moustache wax, particularly 'extra-firm' varieties.



USES and APPLICATIONS of LANOLIN (WOOL FAT):
Lanolin (Wool Fat), purified form of wool grease or wool wax (sometimes erroneously called wool fat), used either alone or with soft paraffin or lard or other fat as a base for ointments, emollients, skin foods, salves, superfatted soaps, and fur dressing.
Lanolin (Wool Fat), a translucent, yellowish-white, soft, unctuous, tenacious substance, is readily absorbed by the skin and thus makes an ideal base for medicinal products intended to be absorbed.


Lanolin (Wool Fat) is used as an active ingredient in over the counter topical products such as ointments, lubricants, lotions and facial cosmetics.
Lanolin (Wool Fat) is also frequently used in protective baby skin treatment and for sore nipples in breastfeeding mothers.
Lanolin (Wool Fat) is a wax derived from the fat of sheep’s wool.


It has a wide range of uses, from medical to cosmetic, and can be found in a variety of products.
In the medical field, Lanolin (Wool Fat) is used as a topical ointment to protect and soothe dry, chapped, or irritated skin.
Lanolin (Wool Fat) is also used to treat and prevent diaper rash, protect nipples during breastfeeding, and to soften and protect cracked, dry lips.


Lanolin (Wool Fat) is even sometimes used to treat minor burns and scrapes.
Lanolin (Wool Fat) is used in eye creams, Hemorrhoid medication, Lip balm, Lotions and creams for dry skin, Makeup and makeup removers, Medicated shampoos, Mustache wax, Shaving cream, Baby oil, Diaper rash cream, Lanolin (Wool Fat) for Breastfeeding and Sore Nipples.


During breastfeeding, your nipples may become sore, dry, and even cracked.
Many healthcare providers recommend Lanolin (Wool Fat) creams to ease nipple pain from breastfeeding.
A big benefit is that it's generally considered safe for your baby to ingest small amounts of Lanolin (Wool Fat).


It's recommended that you use Lanolin (Wool Fat) at least ten minutes before you start breastfeeding.
But unlike other products, you don't need to wipe Lanolin (Wool Fat) off.
It's also safe to give your baby breastmilk expressed while Lanolin (Wool Fat) is on your nipples.


Lanolin (Wool Fat) is a soothing Lanolin (Wool Fat) preparation for use on chapped or rough skin.
Lanolin (Wool Fat) protects against the harsh elements of the weather.
Pure Lanolin (Wool Fat) supports great skin hydration.


Lanolin (Wool Fat) helps to create a protective barrier against everyday external factors, such as changes in weather and the environment.
Active ingredients can be easily incorporated into Lanolin (Wool Fat).
Lanolin (Wool Fat) is also an excellent household product and can be used, for example, as a lubricant for door hinges.


Lanolin (Wool Fat) is used widely in products formulated to protect and treat our skin.
Lanolin (Wool Fat) and its many derivatives are used extensively in both the personal care (e.g., high value cosmetics, facial cosmetics, lip products) and health care sectors such as topical liniments.


Lanolin (Wool Fat) is also found in lubricants, rust-preventive coatings, shoe polish, and other commercial products.
However, allergy to a Lanolin (Wool Fat)-containing product is difficult to pinpoint and often other products containing Lanolin (Wool Fat) may be fine for use.


Lanolin (Wool Fat) is frequently used in protective baby skin treatment and for sore nipples from breastfeeding although health authorities do not recommend it, advise against nipple cleaning and rather recommend improving baby positioning and expressing milk by hand.
Lanolin (Wool Fat) is used commercially in many industrial products ranging from rustproof coatings to lubricants.


Some sailors use Lanolin (Wool Fat) to create slippery surfaces on their propellers and stern gear to which barnacles cannot adhere.
Commercial products (e.g. Lanocote) containing up to 85% Lanolin (Wool Fat) are used to prevent corrosion in marine fasteners, especially when two different metals are in contact with each other and saltwater.


The water-repellent properties make Lanolin (Wool Fat) valuable in many applications as a lubricant grease where corrosion would otherwise be a problem.
7-Dehydrocholesterol from Lanolin (Wool Fat) is used as a raw material for producing vitamin D3 by irradiation with ultraviolet light.
Lanolin (Wool Fat) is frequently used for baby skin treatments.


Baseball players often use Lanolin (Wool Fat) to soften and break in their baseball gloves (shaving cream with Lanolin (Wool Fat) is popularly used for this).
Anhydrous liquid Lanolin (Wool Fat), combined with parabens, has been used in trials as artificial tears to treat dry eye.


Anhydrous Lanolin (Wool Fat) is also used as a lubricant for brass instrument tuning slides.
Lanolin (Wool Fat) can also be restored to woollen garments to make them water and dirt repellent, such as for cloth diaper covers.
Lanolin (Wool Fat) is also used in lip balm products such as Carmex.


Lanolin (Wool Fat) is sometimes used by people on continuous positive airway pressure therapy to reduce irritation with masks, particular nasal pillow masks that can often create sore spots in the nostrils.
Lanolin (Wool Fat) and its derivatives are used in the protection, treatment, and beautification of human skin.


Lanolin (Wool Fat) is used as a primary lubricating component in aerosol-based brass lubricants in the ammunition reloading process.
Mixed warm 1:12 with highly concentrated ethanol (usually 99%), the ethanol acts as a carrier which evaporates quickly after application, leaving a fine film of Lanolin (Wool Fat) behind to prevent brass seizing in resizing dies.


Lanolin (Wool Fat), when mixed with ingredients such as neatsfoot oil, beeswax, and glycerol, is used in various leather treatments, for example in some saddle soaps and in leather care products.
Lanolin (Wool Fat) is frequently used for baby skin treatments.



BENEFITS AND USES OF LANOLIN (WOOL FAT):
Lanolin (Wool Fat) is classified as an occlusive moisturizer.
This means Lanolin (Wool Fat) works by reducing water loss from the skin, similar to petroleum jelly.
While petroleum can reduce the evaporation of skin's moisture by 98%, Lanolin (Wool Fat) reduces it by between 20% and 30%.

However, many people like that Lanolin (Wool Fat) isn't as heavy as petroleum jelly, making it more pleasant to use.
In skincare products, there's no hard evidence showing Lanolin (Wool Fat) is better than synthetic waxes.
If you like using natural products, though, you may prefer Lanolin (Wool Fat) over synthetics.



KEY FEATURES OF LANOLIN (WOOL FAT):
• Natural skin moisturiser
• Nourishes dry and cracked skin
• Forms a protective barrier
• Lanolin (Wool Fat) is derived from sheep wool
• Lanolin (Wool Fat)'s hydrating use has been known since Ancient Greek times!



WHAT IS LANOLIN (WOOL FAT) USED FOR?
Lanolin (Wool Fat) has many different uses in the world of skin care and cosmetics.
From providing moisturizing benefits to enhancing the texture of the products - Lanolin (Wool Fat) does it all.

*Skin care:
Lanolin (Wool Fat) is valued for its exceptional moisturizing properties.
Lanolin (Wool Fat) acts as a natural emollient, creating a protective barrier that helps to prevent moisture loss and keeps the skin hydrated.
Lanolin (Wool Fat) is often incorporated into creams, lotions, and lip balms to alleviate dryness, soothe rough or chapped skin, and promote softness and suppleness

*Cosmetic products:
Lanolin (Wool Fat) serves as a binding agent, helping to hold cosmetic formulations together and providing stability.
Lanolin (Wool Fat) can also enhance the texture and spreadability of products, contributing to a smooth application



ORIGIN OF LANOLIN (WOOL FAT):
Lanolin (Wool Fat) is obtained through a process of extracting and purifying the wool grease found in sheep's wool.
The wool grease is treated to remove impurities and excess water, resulting in the production of Lanolin (Wool Fat).
This refined Lanolin (Wool Fat) is then further processed to obtain different forms, such as anhydrous Lanolin (Wool Fat) or Lanolin (Wool Fat) oil.



WHAT DOES LANOLIN (WOOL FAT) DO IN A FORMULATION?
*Emollient
*Moisturising
*Skin conditioning



SAFETY PROFILE OF LANOLIN (WOOL FAT):
Lanolin (Wool Fat) is widely regarded as a safe ingredient for use in cosmetics.
However, it is important to note that individuals can have varying sensitivities, so patch testing is recommended to check for potential allergic reactions before using products containing Lanolin (Wool Fat).
Additionally, Lanolin (Wool Fat) alcohol can be considered halal if the specific sourcing and the processing methods are employed.



ALTERNATIVES OF LANOLIN (WOOL FAT):
*GLYCERIN



PRODUCTION OF LANOLIN (WOOL FAT):
Crude Lanolin (Wool Fat) constitutes about 5–25% of the weight of freshly shorn wool.
The wool from one Merino sheep will produce about 250–300 ml of recoverable wool grease.

Lanolin (Wool Fat) is extracted by washing the wool in hot water with a special wool scouring detergent to remove dirt, wool grease (crude Lanolin (Wool Fat)), suint (sweat salts), and anything else stuck to the wool.

The wool grease is continuously removed during this washing process by centrifuge separators, which concentrate it into a waxlike substance melting at approximately 38 °C (100 °F).



COMPOSITION OF LANOLIN (WOOL FAT):
A typical high-purity grade of Lanolin (Wool Fat) is composed predominantly of long chain waxy esters (approximately 97% by weight) with the remainder being Lanolin (Wool Fat) alcohols, Lanolin (Wool Fat) acids and Lanolin (Wool Fat) hydrocarbons.

An estimated 8,000 to 20,000 different types of Lanolin (Wool Fat) esters are present in Lanolin (Wool Fat), resulting from combinations between the 200 or so different Lanolin (Wool Fat) acids and the 100 or so different Lanolin (Wool Fat) alcohols identified so far.

Lanolin (Wool Fat)’s complex composition of long-chain esters, hydroxyesters, diesters, Lanolin (Wool Fat) alcohols, and Lanolin (Wool Fat) acids means in addition to its being a valuable product in its own right, it is also the starting point for the production of a whole spectrum of Lanolin (Wool Fat) derivatives, which possess wide-ranging chemical and physical properties.

The main derivatisation routes include hydrolysis, fractional solvent crystallisation, esterification, hydrogenation, alkoxylation and quaternisation.
Lanolin (Wool Fat) derivatives obtained from these processes are used widely in both high-value cosmetics and skin treatment products.

Hydrolysis of Lanolin (Wool Fat) yields Lanolin (Wool Fat) alcohols and Lanolin (Wool Fat) acids.
Lanolin (Wool Fat) alcohols are a rich source of cholesterol (an important skin lipid) and are powerful water-in-oil emulsifiers; they have been used extensively in skincare products for over 100 years.

Approximately 40% of the acids derived from Lanolin (Wool Fat) are alpha-hydroxy acids (AHAs).
The use of AHAs in skin care products has attracted a great deal of attention in recent years.



WHERE IS LANOLIN (WOOL FAT) FOUND?
Wool fat is a principle component of Lanolin (Wool Fat), which is a natural product obtained from the fleece of sheep.
Lanolin (Wool Fat) is found in steroid-containing creams/ointments, medicated shampoos, veterinary products, hand lotions, moisturizers, sunscreens, self-tanning creams, lipsticks, makeup removers, foundations, eye shadows, hairsprays, shaving creams, baby oils and products, printing inks, furniture and shoe polishes, lubricants, leather, and paper.



WHAT ARE SOME PRODUCTS THAT MAY CONTAIN LANOLIN (WOOL FAT)?
Cosmetics
• Foundations
• Eye makeup
• Lipsticks

Hair Care
• Hairspray

Household Products
• Furniture polish
• Leather
• Paper
• Printing inks

Liquids
• Baby oils
• Baby ointments
• Hand lotion
• Moisturizers
• Self-tanners
• Sunscreen



THE DIFFERENCE BETWEEN LANOLIN (WOOL FAT) WOOL AND LANOLIN (WOOL FAT) CREAMS:
Lanolin (Wool Fat) Wool Fat is simply the purest form of Lanolin (Wool Fat) and has not been altered or processed in any way.
This makes it a much more natural and ethical choice than Lanolin (Wool Fat) creams.
Lanolin (Wool Fat) creams, on the other hand, are often processed and contain potentially harmful ingredients.

Many of these creams are made from Lanolin (Wool Fat) that has been extracted from sheep’s wool using harsh chemicals.
This process can strip the Lanolin (Wool Fat) of its natural properties and can cause irritation for people with sensitive skin.
Furthermore, the use of harsh chemicals in the manufacturing process is often seen as unethical.

In contrast, Lanolin (Wool Fat) Wool Fat is ethically sourced and is not exposed to any chemicals during the extraction process.
It is also free from fragrances, colors, and preservatives which can irritate the skin and cause reactions.

Overall, Lanolin (Wool Fat) Wool Fat is a much better choice than Lanolin (Wool Fat) creams.
Its natural and ethical production process makes Lanolin (Wool Fat) a safer and more reliable option for healing inflammation.
Furthermore, Lanolin (Wool Fat) is free from potentially harmful ingredients and fragrances, making it a much healthier choice.



PHYSICAL and CHEMICAL PROPERTIES of LANOLIN (WOOL FAT):
Physical state: Paste
Color: Yellow
Odor: Not available
Melting point/freezing point: Not available
Initial boiling point and boiling range: Not available
Flammability (solid, gas): Not available
Upper/lower flammability or explosive limits: Not available
Flash point: 113°C - closed cup
Autoignition temperature: Not available
Decomposition temperature: Not available
pH: Not available
Viscosity:
Kinematic viscosity: Not available
Dynamic viscosity: Not available

Water solubility: Not available
Partition coefficient: n-octanol/water: Not available
Vapor pressure: Not available
Density: Not available
Relative density: Not available
Relative vapor density: Not available
Particle characteristics: Not available
Explosive properties: Not available
Oxidizing properties: Not available
Other safety information: Not available
Additional Information:
Melting Point: 38-40°C
pH: 5.5-7.0
Solubility: Insoluble in water
Viscosity: High



FIRST AID MEASURES of LANOLIN (WOOL FAT):
-Description of first-aid measures:
*If inhaled:
If breathed in, move person into fresh air.
*In case of skin contact:
Wash off with soap and plenty of water.
*In case of eye contact:
Flush eyes with water as a precaution.
*If swallowed:
Rinse mouth with water.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LANOLIN (WOOL FAT):
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Sweep up and shovel.
Keep in suitable, closed containers for disposal.



FIRE FIGHTING MEASURES of LANOLIN (WOOL FAT):
-Extinguishing media:
*Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
-Further information:
No data available



EXPOSURE CONTROLS/PERSONAL PROTECTION of LANOLIN (WOOL FAT):
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
*Skin protection:
Handle with gloves.
Wash and dry hands.
Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
Splash contact:
Material: Nitrile rubber
Minimum layer thickness: 0,11 mm
Break through time: 480 min
*Body Protection:
Choose body protection in relation to its type.
*Respiratory protection:
Respiratory protection is not required.
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LANOLIN (WOOL FAT):
-Precautions for safe handling:
*Advice on protection against fire and explosion:
Provide appropriate exhaust ventilation at places where dust is formed.
Normal measures for preventive fire protection.
*Hygiene measures:
General industrial hygiene practice.
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Store in cool place.
Keep container tightly closed in a dry and well-ventilated place.
*Storage class:
Storage class (TRGS 510): 13:
Non Combustible Solids



STABILITY and REACTIVITY of LANOLIN (WOOL FAT):
-Reactivity:
No data available
-Chemical stability:
Stable under recommended storage conditions.
-Possibility of hazardous reactions:
No data available
-Conditions to avoid:
No data available


LANOLIN (WOOL FAT)
DESCRIPTION:

LANOLIN (WOOL FAT) (from Latin lāna 'wool', and oleum 'oil'), also called wool fat, wool yolk, wool wax, or wool grease, is a wax secreted by the sebaceous glands of wool-bearing animals.
LANOLIN (WOOL FAT) used by humans comes from domestic sheep breeds that are raised specifically for their wool.
Historically, many pharmacopoeias have referred to Lanolin (wool fat) as wool fat (adeps lanae); however, as Lanolin (wool fat) lacks glycerides (glycerol esters), it is not a true fat.

CAS: 8006-54-0
European Community (EC) Number: 232-348-6


LANOLIN (WOOL FAT) primarily consists of sterol esters instead.
Lanolin (wool fat)'s waterproofing property aids sheep in shedding water from their coats.
Certain breeds of sheep produce large amounts of Lanolin (wool fat).


LANOLIN (WOOL FAT) is a principle component of Lanolin (wool fat), which is a natural product obtained from the fleece of sheep.
LANOLIN (WOOL FAT) is found in steroid-containing creams/ointments, medicated shampoos, veterinary products, hand lotions, moisturizers, sunscreens, self-tanning creams, lipsticks, makeup removers, foundations, eye shadows, hairsprays, shaving creams, baby oils and products, printing inks, furniture and shoe polishes, lubricants, leather, and paper.

Lanolin (wool fat)'s role in nature is to protect wool and skin from climate and the environment; it also plays a role in skin (integumental) hygiene.
LANOLIN (WOOL FAT) and its derivatives are used in the protection, treatment, and beautification of human skin

LANOLIN (WOOL FAT) is a yellow fat obtained from sheep's wool.
LANOLIN (WOOL FAT) is used as an emollient, cosmetic, and pharmaceutic aid.
The US federal code of regulations states that Lanolin (wool fat) in the concentration range of 12-50% may be included in over the counter skin ointments.
Lanolin (wool fat) is the purified, secreted product of the sheep sebaceous glands.
Lanolin (wool fat) primarily consists of long-chain waxy esters, or sterol esters, that lack glycerides.

For this reason, it is also called wool wax or wool grease.
Lanolin (wool fat) is used in the protection, treatment, and cosmetic enhancement of human skin.
Its hydrophobic properties can help protect skin against infections or skin irritation, as it helps seal in moisture that is already present in the skin.

Lanolin (wool fat) is used as an active ingredient in over the counter topical products such as ointments, lubricants, lotions and facial cosmetics.
Lanolin (wool fat) is also frequently used in protective baby skin treatment and for sore nipples in breastfeeding mothers,.



COMPOSITION OF LANOLIN (WOOL FAT) :
A typical high-purity grade of Lanolin (wool fat) is composed predominantly of long chain waxy esters (approximately 97% by weight) with the remainder being Lanolin (wool fat) alcohols, Lanolin (wool fat) acids and Lanolin (wool fat) hydrocarbons.
An estimated 8,000 to 20,000 different types of Lanolin (wool fat) esters are present in Lanolin (wool fat), resulting from combinations between the 200 or so different Lanolin (wool fat) acids and the 100 or so different Lanolin (wool fat) alcohols identified so far.


Lanolin (wool fat)’s complex composition of long-chain esters, hydroxyesters, diesters, Lanolin (wool fat) alcohols, and Lanolin (wool fat) acids means in addition to its being a valuable product in its own right, it is also the starting point for the production of a whole spectrum of Lanolin (wool fat) derivatives, which possess wide-ranging chemical and physical properties.
The main derivatisation routes include hydrolysis, fractional solvent crystallisation, esterification, hydrogenation, alkoxylation and quaternisation.


Lanolin (wool fat) derivatives obtained from these processes are used widely in both high-value cosmetics and skin treatment products.
Hydrolysis of Lanolin (wool fat) yields Lanolin (wool fat) alcohols and Lanolin (wool fat) acids.
Lanolin (wool fat) alcohols are a rich source of cholesterol (an important skin lipid) and are powerful water-in-oil emulsifiers; they have been used extensively in skincare products for over 100 years.

Approximately 40% of the acids derived from Lanolin (wool fat) are alpha-hydroxy acids (AHAs).
The use of AHAs in skin care products has attracted a great deal of attention in recent years.
Details of the AHAs isolated from Lanolin (wool fat) can be seen in the table below.


PRODUCTION OF LANOLIN (WOOL FAT) :
Crude Lanolin (wool fat) constitutes about 5–25% of the weight of freshly shorn wool.
The wool from one Merino sheep will produce about 250–300 ml of recoverable wool grease.
Lanolin (wool fat) is extracted by washing the wool in hot water with a special wool scouring detergent to remove dirt, wool grease (crude Lanolin (wool fat)), suint (sweat salts), and anything else stuck to the wool.

The wool grease is continuously removed during this washing process by centrifuge separators, which concentrate it into a waxlike substance melting at approximately 38 °C (100 °F).


APPLICATIONS OF LANOLIN (WOOL FAT) :
Lanolin (wool fat) and its many derivatives are used extensively in both the personal care (e.g., high value cosmetics, facial cosmetics, lip products) and health care sectors such as topical liniments.
Lanolin (wool fat) is also found in lubricants, rust-preventive coatings, shoe polish, and other commercial products.
Lanolin (wool fat) is a relatively common allergen and is often misunderstood as a wool allergy.


However, allergy to a Lanolin (wool fat)-containing product is difficult to pinpoint and often other products containing Lanolin (wool fat) may be fine for use.
Patch testing can be done if a Lanolin (wool fat) allergy is suspected.
It is frequently used in protective baby skin treatment and for sore nipples from breastfeeding although health authorities do not recommend it, advise against nipple cleaning and rather recommend improving baby positioning and expressing milk by hand.

Lanolin (wool fat) is used commercially in many industrial products ranging from rustproof coatings to lubricants.
Some sailors use Lanolin (wool fat) to create slippery surfaces on their propellers and stern gear to which barnacles cannot adhere.

Commercial products (e.g. Lanocote) containing up to 85% Lanolin (wool fat) are used to prevent corrosion in marine fasteners, especially when two different metals are in contact with each other and saltwater.
The water-repellent properties make it valuable in many applications as a lubricant grease where corrosion would otherwise be a problem.
7-Dehydrocholesterol from Lanolin (wool fat) is used as a raw material for producing vitamin D3 by irradiation with ultraviolet light.


Baseball players often use it to soften and break in their baseball gloves (shaving cream with Lanolin (wool fat) is popularly used for this).
Anhydrous liquid Lanolin (wool fat), combined with parabens, has been used in trials as artificial tears to treat dry eye.

Anhydrous Lanolin (wool fat) is also used as a lubricant for brass instrument tuning slides.
Lanolin (wool fat) can also be restored to woollen garments to make them water and dirt repellent, such as for cloth diaper covers.
Lanolin (wool fat) is also used in lip balm products such as Carmex.

For some people, it can irritate the lips.
Lanolin (wool fat) is sometimes used by people on continuous positive airway pressure therapy to reduce irritation with masks, particular nasal pillow masks that can often create sore spots in the nostrils.
Lanolin (wool fat) is a popular additive to moustache wax, particularly 'extra-firm' varieties.

Lanolin (wool fat) is used as a primary lubricating component in aerosol-based brass lubricants in the ammunition reloading process.
Mixed warm 1:12 with highly concentrated ethanol (usually 99%), the ethanol acts as a carrier which evaporates quickly after application, leaving a fine film of Lanolin (wool fat) behind to prevent brass seizing in resizing dies.

Lanolin (wool fat), when mixed with ingredients such as neatsfoot oil, beeswax and glycerol, is used in various leather treatments, for example in some saddle soaps and in leather care products.



STANDARDS AND LEGISLATION ABOUT LANOLIN (WOOL FAT) :
In addition to general purity requirements, Lanolin (wool fat) must meet official requirements for the permissible levels of pesticide residues.
The Fifth Supplement of the United States Pharmacopoeia XXII published in 1992 was the first to specify limits for 34 named pesticides.
A total limit of 40 ppm (i.e. 40 mg/kg) total pesticides was stipulated for Lanolin (wool fat) of general use, with no individual limit greater than 10 ppm.


A second monograph also introduced into the US Pharmacopoeia XXII in 1992 was entitled 'Modified Lanolin (wool fat)'.
Lanolin (wool fat) conforming to this monograph is intended for use in more exacting applications, for example on open wounds.
In this monograph, the limit of total pesticides was reduced to 3 ppm total pesticides, with no individual limit greater than 1 ppm.


In 2000, the European Pharmacopoeia introduced pesticide residue limits into its Lanolin (wool fat) monograph.
This requirement, which is generally regarded as the new quality standard, extends the list of pesticides to 40 and imposes even lower concentration limits.
Some very high-purity grades of Lanolin (wool fat) surpass monograph requirements.

New products obtained using complex purification techniques produce Lanolin (wool fat) esters in their natural state, removing oxidative and environmental impurities resulting in white, odourless, hypoallergenic Lanolin (wool fat).
These ultra-high-purity grades of Lanolin (wool fat) are ideally suited to the treatment of dermatological disorders such as eczema and on open wounds.

Lanolin (wool fat) attracted attention owing to a misunderstanding concerning its sensitising potential.
A study carried out at New York University Hospital in the early 1950s had shown about 1% of patients with dermatological disorders were allergic to the Lanolin (wool fat) being used at that time.

By one estimate, this simple misunderstanding of failing to differentiate between the general healthy population and patients with dermatological disorders exaggerates the sensitising potential of Lanolin (wool fat) by 5,000–6,000 times.


The European Cosmetics Directive, introduced in July 1976, contained a stipulation that cosmetics which contained Lanolin (wool fat) should be labelled to that effect.
This ruling was challenged immediately, and in the early 1980s, it was overturned and removed from the directive.
Despite only being in force for a short period of time, this ruling did harm both to the Lanolin (wool fat) industry and to the reputation of Lanolin (wool fat) in general.

The Cosmetics Directive ruling only applied to the presence of Lanolin (wool fat) in cosmetic products; it did not apply to the many hundreds of its different uses in dermatological products designed for the treatment of compromised skin conditions.

Modern analytical methods have revealed Lanolin (wool fat) possesses a number of important chemical and physical similarities to human stratum corneum lipids; the lipids which help regulate the rate of water loss across the epidermis and govern the hydration state of the skin.

Cryogenic scanning electron microscopy has shown that Lanolin (wool fat), like human stratum corneum lipids, consists of a mass of liquid crystalline material.
Cross-polarised light microscopy has shown the multilamellar vesicles formed by Lanolin (wool fat) are identical to those formed by human stratum corneum lipids.
The incorporation of bound water into the stratum corneum involves the formation of multilamellar vesicles.

Skin bioengineering studies have shown the durational effect of the emollient (skin smoothing) action produced by Lanolin (wool fat) is very significant and lasts for many hours.
Lanolin (wool fat) applied to the skin at 2 mg/cm2 has been shown to reduce roughness by about 35% after one hour and 50% after two hours, with the overall effect lasting for considerably more than eight hours.

Lanolin (wool fat) is also known to form semiocclusive (breathable) films on the skin.
When applied daily at around 4 mg/cm2 for five consecutive days, the positive moisturising effects of Lanolin (wool fat) were detectable until 72 hours after final application.
Lanolin (wool fat) may achieve some of its moisturising effects by forming a secondary moisture reservoir within the skin.

The barrier repair properties of Lanolin (wool fat) have been reported to be superior to those produced by both petrolatum and glycerol.
In a small clinical study conducted on volunteer subjects with terribly dry (xerotic) hands, Lanolin (wool fat) was shown to be superior to petrolatum in reducing the signs and symptoms of dryness and scaling, cracks and abrasions, and pain and itch.
In another study, a high purity grade of Lanolin (wool fat) was found to be significantly superior to petrolatum in assisting the healing of superficial wounds.



PRODUCTS THAT MAY CONTAIN LANOLIN (WOOL FAT) :
Cosmetics
• Foundations
• Eye makeup
• Lipsticks

Hair Care
• Hairspray

Household Products
• Furniture polish
• Leather
• Paper
• Printing inks

Liquids
• Baby oils
• Baby ointments
• Hand lotion
• Moisturizers
• Self-tanners
• Sunscreen


SAFETY INFORMATION ABOUT LANOLIN (WOOL FAT) :
First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product






SYNONYMS OF LANOLIN (WOOL FAT) :
Lanolin (wool fat)
8006-54-0
7EV65EAW6H
Anhydrous Lanolin (wool fat)
Wool grease
Wool wax, refined
Black Rose
Lanashield
Lanolin (wool fat), anhydrous
Skin Protectant with Lanolin (wool fat)
Theresienol MD Skin Protectant
Theriac Advanced Healing
232-348-6
3CE DRAWING LIP CHILLING
4sport skincare anti chafing
AGNOLIN NO 1
AmeriDermDermaFix
CORONA MULTI-PURPOSE
CORONA ORIGINAL LANOLIN (WOOL FAT) RICH
DTXSID2027678
EMERY 1600
EUCERITE
LANOLIN (WOOL FAT) (II)
LANOLIN (WOOL FAT) (USP MONOGRAPH)
LANOLIN (WOOL FAT) (USP-RS)
LANOLIN (WOOL FAT),ANHYDROUS LIQUID
Lana1263
LanoGuardDaily Care Skin Protectant
LanoGuardDry Skin Therapy
Lanoderm
Lantiseptic Dry Skin Therapy
Lantiseptic by DermaRite Original Skin Protectant
Lantiseptic by Dermarite Dry Skin Therapy
LincoFix
North Country Dairy Supply Non Iodine Barrier Dip
PrimaGuardDaily Care Skin Protectant
SUINTINE
Smartchoices Lanolin (wool fat) Plus0
Soothe and Cool Free Medseptic
Soothe and Cool Free MedsepticSkin Protectant


LANOLIN + 75 EO
Lanolin + 75 EO is available in the form of yellow to light brown wax.
Lanolin + 75 EO is a derivative of lanolin, which shows good water solubility.


CAS Number: 61790-81-6 / 8039-09-6
Chem/IUPAC Name: Lanolin, ethoxylated (75 mol EO average molar ratio)
Chemical Name: Lanolin, Ethoxylated, PEG-75 lanolin
Chemical Family: Alcohols, Ethoxylates, Waxes



SYNONYMS:
Lanolin, oil, ethoxylated, Ethoxylated Lanolin, Lanolin, Ethoxylated, Lanolin + 75 EO, Lanolin, ethoxylated, polyoxyethylene (75) lanolin, polyethylene glycol-75 lanolin, lanolin adduct, Ethoxylated lanolin, Lanolin, ethoxylated, Polyoxyethylene (75) Lanolin, (PEG-75 Lanolin), Super?Solan, PEG-25LANOLIN, PEG-75 LANOLIN, PEG-40 LANOLIN, Ethoxylated lanolin, Lanolin, ethoxylated, Water-soluble lanolin, Polyoxyethylene lanolins, WOOLGREASE-POLYETHOXYLATED, PEG-75 Lanolin (Ethoxylated Lanolin 75 EO)



Lanolin + 75 EO is a cosmetic grade ingredient that works as an emollient which helps in hydrating and softening the skin.
Lanolin + 75 EO appears as a pale yellow liquid that is odorless.
Lanolin + 75 EO is also a great surfactant and emulsifier that helps to combine water-based and oil-based ingredients in a formulation and form a stable product.


In personal care products, Lanolin + 75 EO is highly nourishing and also protects the skin by forming a protective barrier on the surface.
Lanolin + 75 EO is a polyoxyethylene condensate of lanolin with 75 moles of ethyleneoxide.
Lanolin + 75 EO is a hard pale yellow wax with a faint fruitly odor.


Lanolin + 75 EO is particulary indicated for use in aqueous or aqueous-alcoholic lotions, mainly in shampoos, skin cleansing and after-shave lotions.
Lanolin + 75 EO is a very mild nonionic surfactant that can be used with amphoterics and other mild surfactants in the production of baby shampoos.
Washable Lanolin + 75 EO advantages: smoothes the skin and hair, its liquid form facilitates the formulation of preparations, facilitates the dissolution of perfumes, essential oils, antiseptics, compatibility with other surfactants, stabilizes oil-in-water (O/W) emulsions, biodegradable.


Lanolin + 75 EO is available in the form of yellow to light brown wax.
Lanolin + 75 EO is a derivative of lanolin, which shows good water solubility.
Lanolin + 75 EO is a polyoxyethylene condensate with the best pharmaceutical lanolin.


Lanolin + 75 EO has a mean chain length of 75 ethylene oxide units and an average molecular weight of about 3.970 Da.
The lanolin content in Lanolin + 75 EO is approximately 17%.
Lanolin + 75 EO is a hard, pale yellow wax with weak fruity odour.


Lanolin + 75 EO is safe to use, non-toxic.
Lanolin + 75 EO is a surfactant.
Lanolin + 75 EO is an ethoxylated derivative of lanolin.


Lanolin + 75 EO comes in the form of yellow to light brown wax.
Lanolin + 75 EO is very well soluble in water.
Lanolin + 75 EO is predominantly hydrophobic.


Lanolin + 75 EO is pharma grade lanolin containing 50% water.
Hypoallergenic and vegetarian certificates of Lanolin + 75 EO are available.
Lanolin + 75 EO is a very mild nonionic surfactant that can be used with amphoterics and other mild surfactants in the production of baby shampoos.


Lanolin + 75 EO is a polyoxyethylene condensate with the best lanolin.
Lanolin + 75 EO has a mean chain length of 75 ethylene oxide units and an average molecular weight of about 3.970 Da.
The lanolin content in Lanolin + 75 EO is approximately 17%.


Lanolin + 75 EO is a hard, pale yellow wax with weak fruity odour.
Washable Lanolin + 75 EO advantages: smoothes skin and hair, liquid form facilitates the formulation of preparations, facilitates dissolution of perfumes, essential oils, antiseptics, compatibility with other surfactants, stabilizes oil-in-water (O/W) emulsions, biodegradable
Lanolin + 75 EO is an emollient and surfactant derived from Lanolin



USES and APPLICATIONS of LANOLIN + 75 EO:
Lanolin + 75 EO is used cosmetics and detergents, shampoos, liquid soaps, body washes, gels for washing face and body, shower gels, bubble baths, toners, pore-refining, before and after shave fluids, creams, moisturisers, lotions, aqueous or aqueous-alcoholic liquids with high clarity, detergents for industrial washing, wetting and conditioning agent for cold wave perm products.


Lanolin + 75 EO is a non-ionic surfactant (INCI name: PEG-75 Lanolin), an ethoxylated derivative of lanolin, used mainly in cosmetic applications.
Lanolin + 75 EO is particularly recommended for use in aqueous or aqueous-alcoholic lotions and solutions with high clarity.
Moreover, Lanolin + 75 EO has emulsifying, solubilising and emollient properties and a mild cleaning effect.


Main applications of Lanolin + 75 EO include skin cleansing and after-shave lotions, as well as in shampoos and detergent formulations, where viscosity is of importance.
Thanks to its various properties, Lanolin + 75 EO is an ingredient in many products such as shampoos, facial gels, body washes, liquid soaps, lotions and toners.


Among industrial applications, Lanolin + 75 EO is mainly used as an industrial cleaning detergent.
The role and effects of Lanolin + 75 EO in cosmetics and personal care products: Lanolin + 75 EO in cosmetics serves both as a base (a kind of foundation on which a cosmetic formulation is built) and an active ingredient (ensuring specific properties).


Although it was recognised as safe for personal care and cosmetic products, Lanolin + 75 EO should not be used as an ingredient in formulations intended for children and pregnant women.
Lanolin + 75 EO is primarily an emulsifier used in O/W emulsions (oil-in-water emulsions).


Lanolin + 75 EO enables to form an emulsion by mixing the oil phase with the water phase.
As a surfactant, Lanolin + 75 EO enables the formation of foam.
Foam is where air (or another gas) is dispersed in a liquid.


Adequate foaming properties of cosmetics are responsible for effective removal of impurities.
Lanolin + 75 EO contributes to the rheology modification.
One of the factors determining sensory quality and usability of e.g. cosmetic creams is their rheological characteristics, namely viscosity of Lanolin + 75 EO, which often influences consumer decisions on the purchase of a specific formulation.


Lanolin + 75 EO as one of the product ingredients, increases or decreases the viscosity of the finished product.
Another effect of Lanolin + 75 EO is solubilization.
As a solubiliser, in a process called micellar solubilisation, Lanolin + 75 EO introduces substances that are hydrophobic (i.e. not soluble in water) into the aqueous solution in which it is found.


The result is an isotropic, transparent composition whose viscosity is similar to that of water.
Examples of substances that can be introduced into aqueous solution thanks to the use of Lanolin + 75 EO include plant extracts, oily substances and fragrance compositions.


Lanolin + 75 EO also works well in skin care formulations as an emollient.
Lanolin + 75 EO forms a thin occlusive layer on the surface of the skin that prevents excessive evaporation of water and keeps an adequate level of moisture (indirect moisturising effect).


The visible effect is smoothening and softening of the epidermis.
Lanolin + 75 EO is particularly recommended for use in aqueous or aqueous-alcoholic lotions and solutions with high clarity.
Moreover, Lanolin + 75 EO has emulsifying, solubilising and emollient properties and a mild cleaning effect.


Main applications of Lanolin + 75 EO include skin cleansing and after-shave lotions, as well as in shampoos and detergent formulations, where viscosity is of importance.
Lanolin + 75 EO is used as a conditioning agent and emollient in cleansing and skin care cosmetics.


Lanolin + 75 EO has a moisturising as well as softening and smoothening effect.
Skincare: Add Lanolin + 75 EO to creams, lotions, serums, and body butters to enhance their moisturizing properties and improve skin texture.
Haircare: Incorporate Lanolin + 75 EO into shampoos, conditioners, hair masks, and styling products to nourish and condition the hair.


Formulation: Lanolin + 75 EO can be easily incorporated into water-based formulations due to its water-soluble nature.
Lanolin + 75 EO is a unique and versatile ingredient that offers excellent emollient and moisturizing properties, making it a popular choice in skincare and haircare products.


Lanolin + 75 EO is a water-soluble derivative of lanolin, a natural substance derived from sheep’s wool.
Lanolin + 75 EO is known for its ability to improve skin and hair texture, leaving them soft, smooth, and well-hydrated.



WHAT IS LANOLIN + 75 EO USED FOR?
Lanolin + 75 EO is very useful for the cosmetic and personal care industry.
Lanolin + 75 EO can be found in products such as foundations, eyeshadows, lotions, creams, and lip balms.

*Decorative cosmetics:
Lanolin + 75 EO improves the texture of the products and keeps different ingredients in the formulation from separating.
Lanolin + 75 EO also reduces the harsh and dry nature of cosmetics by making them smoother and hydrating

*Hair care:
Lanolin + 75 EO offers natural shine to the shafts by nourishing and conditioning them.
Lanolin + 75 EO also forms a protective barrier on the scalp and promotes healthy hair - full of sheen and shine



ORIGIN OF LANOLIN + 75 EO:
Lanolin + 75 EO is made from wool wax that comes from the wool of sheep.
Lanolin + 75 EO is made by hydrogenation and hydrolysis of the wool which involves breaking down the fatty acids into smaller molecules.
These molecules are then manufactured into the cosmetic grade ingredient - Lanolin + 75 EO.



WHAT DOES LANOLIN + 75 EO DO IN A FORMULATION?
*Emollient
*Emulsifying
*Surfactant



SAFETY PROFILE OF LANOLIN + 75 EO:
Lanolin + 75 EO is safe for skin and hair.
The recommended use level of this ingredient is between 0.5-20%.
Levels of Lanolin + 75 EO higher than this can cause side effects such as rashes, itching, and redness.

A patch test is recommended before full application.
Further, Lanolin + 75 EO is non-comedogenic and does not cause blemishes or acne.
Lanolin + 75 EO is not vegan.



ALTERNATIVES OF LANOLIN + 75 EO:
*SHEA BUTTER GLYCERIDES



FUNCTIONS OF LANOLIN + 75 EO:
*Emulsifier,
*Surfactant,
*Surfactant (Nonionic)



FEATURES LANOLIN + 75 EO:
Lanolin + 75 EO is ethoxylated, to obtain not only complete water solubility, but also solutions that are crystal clear in all concentrations, both in water and in aqueous ethanol concentrations of up to 40%.

The solutions are nonionic and compatible with most other solubilisers including up to 10% electrolytes solutions.
The solution is only slightly affected by oxidative and reducing agents.

Lanolin + 75 EO is stable in a pH range of 2-10.
A particularly unique feature of Lanolin + 75 EO is its carefully controlled manufacturing that ensures minimum viscosity variations of the aqueous solutions.



KEY FEATURES OF LANOLIN + 75 EO:
1. **Emollient and Moisturizing:**
Lanolin + 75 EO acts as an effective emollient, forming a protective barrier on the skin and hair to lock in moisture, keeping them hydrated and supple.

2. **Enhances Skin Texture:**
Lanolin + 75 EO helps improve the texture of the skin, making it ideal for use in creams, lotions, and moisturizers.

3. **Hair Conditioning:**
Lanolin + 75 EO can be used in haircare products like shampoos and conditioners to add moisture and improve hair manageability and shine.

4. **Water-Soluble:**
Unlike traditional lanolin, Lanolin + 75 EO is water-soluble, making it easier to incorporate into various formulations.

5. **Non-Greasy:**
Lanolin + 75 EO is non-greasy and absorbs quickly, providing a smooth and comfortable feel on the skin and hair.



FEATURES AND BENEFITS OF LANOLIN + 75 EO:
Benefit Claims
*Acidic pH Stable,
*Basic pH Stable,
*Compatibility,
*Dispersing,
*Emolliency,
*Emulsifying,
*Good Wetting Properties,
*Skin Conditioning
*Labeling Claims
*Halal,
*Kosher,
*Ulta Beauty's Conscious Beauty



BENEFITS OF LANOLIN + 75 EO:
– Skin Hydration:
Lanolin + 75 EO helps prevent water loss from the skin, promoting long-lasting hydration.

– Hair Nourishment:
When used in hair products, Lanolin + 75 EO can help repair and protect damaged hair, leaving it soft and silky.

– Compatibility:
Lanolin + 75 EO is compatible with a wide range of cosmetic ingredients, making it suitable for formulating a variety of products.



GENERAL CHARACTERISTICS OF LANOLIN + 75 EO:
Lanolin + 75 EO is the INCI name for one of polyethylene glycol derivatives.
Its common chemical name is lanolin ethoxylated with 75 moles of ethylene oxide or Lanolin + 75 EO.

The number of moles of ethylene oxide in an ethylene glycol derivative is indicated in the INCI name of Lanolin + 75 EO (as with other ethylene glycol derivatives).
The CAS number to search for and identify Lanolin + 75 EO is 61790-81-6.



DERMATOLOGY OF LANOLIN + 75 EO:
Lanolin + 75 EO is made from pharmaceutical grade lanolin, which complies to the European Pharmacopoeia.
Lanolin + 75 EO is well established in the market for many years, especially for hair and skin care products.
To date, no adverse effects were observed.
Patch tests that were made with the 100 % substance in 11 subjects with daily dosing of 2-3 hours over a period of 4 weeks showed no adverse skin reaction.



PROCESSING OF LANOLIN + 75 EO:
When used in solutions, Lanolin + 75 EO should first be melted, followed by addition of 3 times the amount of hot water under constant stirring.
The resulting concentrate of Lanolin + 75 EO is then diluted with either hot or cold water.
In order to prepare emulsions, Lanolin + 75 EO is normally melted together with the oil phase, but it can also be dissolved in the aqueous phase.
Lanolin + 75 EO should be stored cool in closed containers. Prolonged heating above 80 °C should be avoided.



SOLUBILITY OF LANOLIN + 75 EO:
Solubility at room temperature
Water: soluble; ethanol, anhydrous: soluble; ethanol 80%: partly soluble; ethanol 40%: soluble; mineral oil: slightly soluble



ADVANTAGES OF LANOLIN + 75 EO:
Key advantages of PEG-75 Lanolin:
*facilitates emulsion formation by reducing surface tension of substances to be emulsified;
*creates a protective layer on the surface of the skin, making Lanolin + 75 EO soft and smooth;
*in hair care products, Lanolin + 75 EO prevents excessive water evaporation;
facilitates dissolution of perfumes or essential oils in water;
*Lanolin + 75 EOis compatible and synergic with other surfactants.



FEATURES OF LANOLIN + 75 EO:
Lanolin + 75 EO is ethoxylated, to obtain not only complete water solubility, but also solutions that are crystal clear in all concentrations, both in water and in aqueous ethanol concentrations of up to 40%.

The solutions are nonionic and compatible with most other solubilisers including up to 10% electrolytes solutions.
The solution is only slightly affected by oxidative and reducing agents.

Lanolin + 75 EO is stable in a pH range of 2-10.
A particularly unique feature of Lanolin + 75 EO is its carefully controlled manufacturing that ensures minimum viscosity variations of the aqueous solutions.



ADVANTAGES OF LANOLIN + 75 EO:
* emollient and conditioning agent in colouring cosmetics,
* smoothes the skin and hair,
* the liquid form facilitates formulation of preparations,
* agent facilitating the dissolution of perfumes, essential oils, antiseptics,
* compatibility and synergy with other surfactants,
* stabilizes oil-in-water (O/W) emulsions,



PHYSICAL and CHEMICAL PROPERTIES of LANOLIN + 75 EO:
Boiling Point: 300°C
Melting Point: 99°C
pH: 5.0-7.0
Solubility: Soluble in water
Boiling Point: 300°C
Melting Point: 99°C
pH: 5.0-7.0
Solubility: Soluble in water
CAS Number: 61790-81-6 / 8039-09-6
Chem/IUPAC Name: Lanolin, ethoxylated (75 mol EO average molar ratio)
COSING REF No: 77290
Assay: 95.00 to 100.00
Food Chemicals Codex Listed: No
Soluble in Water: 0.0002397 mg/L @ 25°C (estimated)



FIRST AID MEASURES of LANOLIN + 75 EO:
-Description of first-aid measures:
*If inhaled:
If breathed in, move person into fresh air.
*In case of skin contact:
Wash off with soap and plenty of water.
*In case of eye contact:
Flush eyes with water as a precaution.
*If swallowed:
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
-Indication of any immediate medical attention and special treatment needed:
No data available



ACCIDENTAL RELEASE MEASURES of LANOLIN + 75 EO:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Keep in suitable, closed containers for disposal.



FIRE FIGHTING MEASURES of LANOLIN + 75 EO:
-Extinguishing media:
*Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
-Further information:
No data available



EXPOSURE CONTROLS/PERSONAL PROTECTION of LANOLIN + 75 EO:
-Control parameters:
--Ingredients with workplace control parameters:
-Exposure controls:
--Personal protective equipment:
*Eye/face protection:
Use equipment for eye protection.
*Skin protection:
Handle with gloves.
Wash and dry hands.
*Body Protection:
Impervious clothing
*Respiratory protection:
Respiratory protection not required.
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of LANOLIN + 75 EO:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Store in cool place.
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.



STABILITY and REACTIVITY of LANOLIN + 75 EO:
-Reactivity:
No data available
-Chemical stability:
Stable under recommended storage conditions.
-Possibility of hazardous reactions:
No data available
-Conditions to avoid:
No data available

LANOLIN ACID
LANOLIN ALCOHOL, N° CAS : 8027-33-6 - Alcool de lanoline, Origine(s) : Animale, Synthétique. Autres langues : Alcohol de lanolina, Alcool di lanolina, Lanolinalkohol, Nom INCI : LANOLIN ALCOHOL, N° EINECS/ELINCS : 232-430-1. Ses fonctions (INCI). Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent fixant : Permet la cohésion de différents ingrédients cosmétiques. Emollient : Adoucit et assouplit la peau. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques. Noms français : Alcools de lanoline. Noms anglais : ALCOHOLS, LANOLIN; Ecerin; LANOLIN ALCOHOL; LANOLIN ALCOHOLS;WOOLWAX ALCOHOL
LANOLIN ALCOHOL ( Alcool de lanoline)
fluilan; lantrol; vigilan; Lanolin CAS NO:70321-63-0
Lanolin oil
cas no:8006-54-0 Wool fat; Wool grease; Wool wax; Woolwax ester;
Lanoline ( Lanoline anhydre)
Noms français : Lanoline anhydre; Inci : lanolin, Cas : 8006-54-0, La lanoline, autrement appelée graisse de laine ou cire de laine, est une graisse obtenue par purification et raffinage du suint (partie grasse absorbée sur la laine). Elle comprend de l'oléine et de la stéarine. Chimiquement, la lanoline est une cire, un mélange d'esters et d'acides gras avec des alcools à haute masse moléculaire. On a identifié plus de 180 acides gras et 80 alcools différents. Elle est amphiphile et forme des émulsions très stables avec l'eau, de plus il s'agit d'une espèce très hygroscopique. La lanoline est utilisée en pharmacie, par exemple pour la supplémentation en vitamine D2,3, et dans la fabrication des produits de beauté.Principaux synonymes: Noms anglais : ANHYDROUS LANOLIN, ANHYDROUS LANUM, Lanolin anhydrous, LANOLIN, ANHYDROUS
Lanoline AD
LANTHANUM CHLORIDE, N° CAS : 10099-58-8. Nom INCI : LANTHANUM CHLORIDE. Nom chimique : Lanthanum chloride, anhydrous. N° EINECS/ELINCS : 233-237-5. Ses fonctions (INCI). Astringent : Permet de resserrer les pores de la peau
Lanthanum chloride
LAURAMIDE DEA, N° CAS : 120-40-1, Nom INCI : LAURAMIDE DEA, Nom chimique : N,N-bis(2-Hydroxyethyl)dodecanamide, N° EINECS/ELINCS : 204-393-1, Ses fonctions (INCI) Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Sinergiste de mousse : Améliore la qualité de la mousse produite en augmentant une ou plusieurs des propriétés suivantes: volume, texture et / ou stabilité. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
L-ARGININE
L-arginine, naturally found in various dietary sources like red meat, poultry, fish, and dairy, plays a crucial role in protein synthesis and is converted into nitric oxide in the body, aiding in blood vessel dilation and circulation.
While L-arginine supplementation is popular for conditions like high blood pressure and erectile dysfunction, its effectiveness varies, with some studies suggesting benefits for exercise performance through enhanced nitric oxide production, particularly in certain athletic populations.
However, despite its potential benefits, it's important to note that L-arginine supplementation may not always be necessary, as adequate levels can typically be obtained through a balanced diet rich in protein, with supplements being more relevant in cases of deficiency or specific medical conditions.

CAS number: 74-79-3
EC number: 230-571-3
Chemical Formula: C6H14N4O2
Molar Mass: 174.204 g·mol−1

Synonyms: NCGC00024715-02, NCGC00024715-03, NCGC00024715-04, NCGC00024715-05, NCGC00024715-10, NCGC00260762-01, 25212-18-4, 4455-52-1, AK-81231, AS-14190, K277, L-Arginine, BioUltra, >=99.5% (NT), SBI-0207062.P001, AB0014136, A0526, A7079, EU-0100077, L-Arginine, SAJ special grade, >=98.0%, A 5006, C00062, D02982, L-Arginine, Vetec(TM) reagent grade, >=98%, M02981, Y-8965, 14932-EP2316830A2, AB00374192_03, Norvaline, 5-[(aminoiminomethyl)amino]-, (L)-, L-arginine, arginine, 74-79-3, L-(+)-Arginine, L(+)-Arginine, L-Arg, H-Arg-OH, (S)-2-Amino-5-guanidinopentanoic acid, (L)-Arginine, Arginina, ARGININE, L-, Arginine (VAN), L-Arginin, Argininum, Arginina, L-Ornithine, N5-(aminoiminomethyl)-, Argamine, Argivene, Detoxargin, Levargin, L-alpha-Amino-delta-guanidinovaleric acid, Minophagen A, 1-Amino-4-guanidovaleric acid, CCRIS 3609, NSC 206269, arg, HSDB 1429, AI3-24165, UNII-94ZLA3W45F, MFCD00002635, (S)-2-Amino-5-guanidinovaleric acid, BRN 1725413, CHEBI:16467, (S)-2-Amino-5-((aminoiminomethyl)amino)pentanoic acid, L-Norvaline, 5-((aminoiminomethyl)amino)-, (S)-(+)-arginine, L-Arginine, monohydrochloride, 2-amino-5-guanidinovaleric acid, CHEMBL1485, (2S)-2-amino-5-guanidinopentanoic acid, (S)-2-Amino-5-[(aminoiminomethyl)amino]pentanoic acid, 94ZLA3W45F, Pentanoic acid, 2-amino-5-((aminoiminomethyl)amino)-, (S)-, (2S)-2-amino-5-(carbamimidamido)pentanoic acid, L-2-Amino-5-guanidinopentanoic acid, Arginine (L-Arginine), R-Gene, L-Norvaline, 5-[(aminoiminomethyl)amino]-, (2S)-2-amino-5-carbamimidamidopentanoic acid, DSSTox_CID_21056, DSSTox_RID_79618, Poly(L-arginine), DSSTox_GSID_41056, L(+)-Arginine, 98+%, BDBM181132, HMS3260O15, N5-(aminoiminomethyl)-L-Ornithine, HY-N0455, ZINC1532525, L-Arginine, Vetec(TM), 98.5%, Tox21_113046, Tox21_500077, AC-083, ANW-36527, L-alpha-Amino-delta-guanidinovalerate, L-Arginine, reagent grade, >=98%, s5634, AKOS006239069, AKOS015854096, Tox21_113046_1, AM81500, CCG-204172, DB00125, LP00077, MCULE-5108123240, SDCCGSBI-0050065.P002, L-Arginine, 99%, natural, FCC, FG, (s)-2-amino-5-guanidino-pentanoic acid, 5-[(aminoiminomethyl)amino]-L-Norvaline, NCGC00015064-01, NCGC00024715-01, 002A635, A837397, Q173670, SR-01000075479, SR-01000597671, (S)-2-amino-5-[(aminoiminomethyl)amino]-Pentanoate, (S)-2-Amino-5-[(aminoiminomethyl)amino]pentanoate, SR-01000075479-1, SR-01000597671-1, W-104410, (S)-2-amino-5-[(aminoiminomethyl)amino]-Pentanoic acid, Arginine, European Pharmacopoeia (EP) Reference Standard, (2S)-2-amino-5-[(diaminomethylidene)amino]pentanoic acid, 7F15B0C7-356D-45D7-AC33-03AEE4394A0E, S-(+)-2-Amino-5-[(aminoiminomethyl)amino]pentanoic acid, UNII-0O72R8RF8A component ODKSFYDXXFIFQN-BYPYZUCNSA-N, UNII-FL26NTK3EP component ODKSFYDXXFIFQN-BYPYZUCNSA-N, L-Arginine, United States Pharmacopeia (USP) Reference Standard, L-Arginine, Pharmaceutical Secondary Standard; Certified Reference Material, L-, L-Arginine, from non-animal source, meets EP, USP testing specifications, suitable for cell culture, 98.5-101.0%, L-Arginine, PharmaGrade, Ajinomoto, EP, USP, manufactured under appropriate GMP controls for Pharma or Biopharmaceutical production, suitable for cell culture

L-arginine is an amino acid naturally found in red meat, poultry, fish, and dairy.
L-arginine is necessary for making proteins and is commonly used for circulation.
L-arginine is converted in the body into a chemical called nitric oxide.

Nitric oxide causes blood vessels to open wider for improved blood flow.
L-arginine also stimulates the release of growth hormone, insulin, and other substances in the body.

L-arginine can be made in a lab and used in supplements.
People use L-arginine for chest pain and various blow flow issues, erectile dysfunction, high blood pressure during pregnancy, and a serious disease in premature infants called necrotizing enterocolitis (NEC).

L-arginine's also used for many other conditions, but there is no good scientific evidence to support these other uses.
L-arginine is an amino acid that helps the body make proteins.

L-arginine can be obtained naturally in the diet and is also found in dietary supplement form.
Foods rich in L-arginine include plant and animal proteins, such as dairy products, meat, poultry, fish, and nuts.

In addition to building protein, L-arginine releases nitric oxide in the blood.
Nitric oxide acts to widen blood vessels in the blood stream, which may help aid certain circulatory conditions.

A person’s body naturally produces L-arginine under normal circumstances.
People also get additional L-arginine as part of their regular diet.
Red meats, fish, dairy, and eggs all contain low amounts of L-arginine that help the body to replenish L-arginines necessary resources.

Arginine, also known as l-arginine (symbol Arg or R), is an α-amino acid that is used in the biosynthesis of proteins.
L-arginine contains an α-amino group, an α-carboxylic acid group, and a side chain consisting of a 3-carbon aliphatic straight chain ending in a guanidino group.

At physiological pH, the carboxylic acid is deprotonated (−COO−), the amino group is protonated (−NH3+), and the guanidino group is also protonated to give the guanidinium form (-C-(NH2)2+), making arginine a charged, aliphatic amino acid.
L-arginine is the precursor for the biosynthesis of nitric oxide.

L-arginine is encoded by the codons CGU, CGC, CGA, CGG, AGA, and AGG.
Arginine is classified as a semiessential or conditionally essential amino acid, depending on the developmental stage and health status of the individual.

Preterm infants are unable to synthesize or create arginine internally, making the amino acid nutritionally essential for them.
Most healthy people do not need to supplement with arginine because L-arginine is a component of all protein-containing foods and can be synthesized in the body from glutamine via citrulline.

Occasionally, a person’s need for L-arginine may exceed the body’s ability to produce or consume L-arginine naturally.
This is often true for older adults or people with certain medical conditions.

In these cases, people may be prescribed artificial L-arginine in the form of oral medication, injections, or creams.
Several potential health conditions may benefit from an increased intake of L-arginine.

L-arginine is an amino acid.
Amino acids are the building blocks of proteins and divided into essential and nonessential categories.

Nonessential amino acids are made in the body, but essential amino acids are not.
As such, they must be provided through dietary intake.

L-arginine is considered semi-essential or conditionally essential, meaning that L-arginine becomes essential under certain circumstances and conditions, including pregnancy, infancy, critical illness, and trauma.
L-arginine’s necessary for the production of nitric oxide, a signaling molecule that’s needed for a variety of bodily processes and functions, including blood flow regulation, mitochondrial function, and cellular communication.

Additionally, L-arginine acts as a precursor to other amino acids, including glutamate, proline, and creatine, and is essential for the health and functioning of your immune system.
Arginine is necessary for the development of T-cells, which are white blood cells that play central roles in immune response.

Because L-arginine has so many critical roles in your body, a deficiency in this amino acid can disrupt cellular and organ function and lead to serious adverse health outcomes.
L-arginine is produced in several ways.
L-arginine can be synthesized from the amino acid citrulline through the breakdown of body proteins, or L-arginine can be obtained through dietary protein intake.

L-arginine’s concentrated in certain protein-rich foods, including meat, poultry, dairy, nuts, soy products, and fish.
The average daily intake of L-arginine from foods is reported to be 4–6 grams.

For reference, research shows that a typical Western diet provides between 25–30% of total arginine present in the body.
Additionally, L-arginine can be obtained by taking supplements.

L-arginine supplements are widely available and can be found in powder, liquid, capsule, and tablet form at grocery stores, supplement stores, and online.
This article mainly focuses on the benefits and uses of L-arginine supplements.

L-arginine is an amino acid that helps make proteins.
L-arginine also becomes the gas nitric oxide (NO) in the body.

NO is important for erectile function because L-arginine helps blood vessels relax, so more oxygen-rich blood can circulate through your arteries.
Healthy blood flow to the arteries of the penis is essential for normal erectile function.

L-Arginine is an amino acid critical to the production of nitric oxide (NO) in the body.
NO helps regulate and improve blood circulation.

L-Arginine cannot be made in the body, but must obtained through food or supplementation.
Kyowa Quality L-Arginine is an pure, allergen-free ingredient that has been manufactured to the highest quality standards.

Eggs, meats, milk, soy proteins, peanuts, and walnuts are all sources of arginine.
The physiologically active form, L-arginine, is obtained by breaking down proteins.

Arginine also may be synthesized in the laboratory.
Because L-arginine may be synthesized in the body, L-arginine is classified as a nonessential amino acid in adults.
However, in children and in people with certain conditions (eg, infection, trauma), L-arginine synthesis may become compromised and then may be considered semi-essential.

Natural ways to get enough L-arginine:
A major benefit of obtaining L-arginine through diet is that L-arginine is difficult to get too much.
Therefore, some of the side effects of consuming too much L-arginine can be avoided.

On the other hand, food consumption alone may not provide enough L-arginine to meet a person’s needs.
A person should discuss their options with their doctor prior to changing their diet.

The best natural source for L-arginine is food high in protein.
For some people, animal proteins, such as red meat (beef), chicken and turkey breast, pork loin, and dairy products, may be the primary source of L-arginine.

For people who do not eat meat, plant-based proteins that contain L-arginine include lentils, chickpeas, peanuts, pumpkin seeds, and soybeans.
People who find they have a deficient amount of L-arginine to meet their needs may want to modify their diet to include foods rich in protein.
A dietician or doctor may be able to make meal plan suggestions to boost natural intake of L-arginine prior to taking supplements.

Uses of L-arginine:
L-arginine supplements are taken by many populations, including athletes and those who have certain medical conditions like high blood pressure, for a variety of reasons.
They’re also used in the clinical setting to treat critically ill people or those with wounds.

Research has shown that L-arginine may offer a variety of potential benefits when used as a supplement.
However, results are mixed, and L-arginine may not be as effective for some conditions as many supplement companies claim.

Athletic performance enhancement:
Limited evidence suggests that L-arginine supplements may enhance exercise performance by increasing nitric oxide in the body, which improves blood flow and oxygenation to muscles.
For example, a 2017 randomized study in 56 male soccer players found that treatment with 2 grams of L-arginine daily for 45 days significantly increased sport performance, compared with a placebo group.

Another small study in 9 men demonstrated that those who drank a beverage containing 6 grams of L-arginine 1 hour before intense exercise had significantly increased blood levels of nitric oxide and were able to exercise longer, compared with a placebo group.
However, most studies investigating this relationship have found that L-arginine is not beneficial for improving athletic performance.
L-citrulline, a precursor to L-arginine that’s discussed later in this article, may be a better choice for boosting athletic performance.

Blood pressure regulation:
L-arginine supplements may benefit those with high blood pressure.
Studies have shown that taking L-arginine supplements may help lower both your systolic (the top number) and diastolic (the bottom number) blood pressure readings.

L-arginine is needed for the production of nitric oxide, which is necessary for the relaxation of the cells that make up blood vessels, as well as blood pressure regulation.
A 2016 review of 7 studies found that supplementing with L-arginine by both oral and intravenous (IV) administration significantly reduced systolic and diastolic blood pressure in adults with high blood pressure by up to 5.4 mm/Hg and 3.1 mm/Hg, respectively.

Management of critical illness:
Arginine becomes essential when your body is compromised due to conditions like infection and trauma, and your arginine needs significantly increase due to physiologic demands.
Under these circumstances, your body can no longer fulfill your arginine needs, which must be met through external sources.

Arginine depletion during critical illness or after surgery leads to serious adverse effects, including impaired immune function and blood flow.
To avoid these potential complications, arginine supplements are used frequently in the clinical setting to treat a variety of conditions.
For example, oral or IV arginine is commonly used to treat serious infections like necrotizing enterocolitis in infants, cases of sepsis, burns, chronic disease, and wounds, as well as in pre- and post-surgical and trauma patients.

Blood sugar regulation:
Research shows that L-arginine may benefit those with diabetes by improving glucose metabolism and insulin sensitivity.
L-arginine is needed for the production of nitric oxide.

Nitric oxide plays important roles in cellular function and how your body responds to insulin, a hormone that shuttles blood sugar from your blood into cells, where L-arginine’s used for energy.
Therefore, increasing nitric oxide availability may help enhance the function of cells that secrete insulin and help your body use blood sugar more efficiently.

Some research has shown that long-term treatment with L-arginine supplements may prevent diabetes in at-risk populations.
A study in 144 people with impaired blood sugar regulation found that treatment with 6.4 grams of L-arginine per day for 18 months reduced the chances of diabetes development over a 90-month period, compared with a placebo group.

Traditional/Ethnobotanical uses of L-arginine:
L-arginine is a nonessential amino acid that may play an important role in the treatment of heart disease due to L-arginines block arterial plaque buildup, blood clots, platelet clumping, and to increase blood flow through the coronary artery.
L-arginine is commonly sold as a health supplement claiming to improve vascular health and treat erectile dysfunction in men.

L-arginine, which is promoted as a human growth stimulant, has also been used in bodybuilding.
In the 1800s, L-arginine was first isolated from animal horn.

Use in specific populations of L-arginine:
The safety of L-arginine has been demonstrated in many populations, including pregnant women and older adults.
However, some people, including those with conditions that affect the liver or kidneys, should avoid L-arginine.

L-arginine supplements are sometimes used in children in the clinical setting and deemed safe when prescribed in appropriate doses.
Yet, arginine supplementation in children should always be monitored by a healthcare provider.

L-arginine’s not recommended to give your child L-arginine unless L-arginine’s medically necessary and was suggested by a healthcare provider.
This advice is extremely important to follow, as giving a child too high a dose of L-arginine may result in serious side effects and can even be fata.

Alternatives of L-arginine:
After consumption, your gut and liver rapidly metabolize L-arginine before L-arginine has the chance to reach systemic circulation.
For this reason, some argue that L-citrulline, a precursor to L-arginine, may be a better choice for increasing arginine levels.

L-citrulline is an amino acid that may be used as an alternative to L-arginine when taken as a supplement.
L-citrulline is a nonessential amino acid that’s a precursor to L-arginine.

L-citrulline is converted into L-arginine through a series of enzymatic reactions that take place primarily in your kidneys.
Research shows that L-citrulline supplements can raise body levels of L-arginine.

In fact, some studies show that L-citrulline is more effective at increasing arginine levels than L-arginine supplements.
Research has likewise shown that L-citrulline supplements may offer benefits similar to those of L-arginine supplements.

For example, similarly to L-arginine, L-citrulline has been shown to help reduce blood pressure and improve erectile dysfunction in some studies.
Additionally, studies show that when L-citrulline used on L-arginines own or in combination with L-arginine, L-arginine may improve athletic performance and enhance muscle recovery in athletes.

Furthermore, some of these studies found that citrulline supplements may be more effective than L-arginine supplements at enhancing athletic performance.
Therefore, athletes may benefit more from L-citrulline or a combination of L-arginine and L-citrulline over L-arginine alone.

Benefits of L-arginine:
L-arginine has two effects: L-arginine turns into nitric oxide and helps the body build protein.
These effects give L-arginine an array of potential benefits that range from heart health and chest pain to helping to build muscles, repair wounds, and improve male fertility.
Although there are many claims about the benefits of L-Arginine, not all of them are supported by scientific research studies.

The following are some examples of researched benefits and uses of L-arginine:
Growth hormone reserve test,
Reducing high blood pressure,
Correcting inborn errors of urea synthesis,
Treating heart disease,
Treating erectile dysfunction (ED),
Easing inflammation of the digestive tract in premature infants,
Controlling blood sugar in people with diabetes.

Additionally, L-arginine may have the potential to help with many other issues.

However, more research needs to be done to evaluate further L-arginine’s potential to do the following:
Improve blood flow,
Heal wounds faster,
Alleviate anxiety,
Treat burns,
Improve kidney function for people with congestive heart failure,
Enhance exercise performance.

L-arginine also helps rid the body of ammonia (a waste product) and stimulates the release of insulin.
In addition, your body uses arginine to make nitric oxide (a compound that relaxes the blood vessels).
Although some studies suggest that L-arginine may benefit certain health conditions, other research shows that L-arginine may have harmful effects on some individuals.

Health Benefits of L-arginine:
By improving blood flow in the body, some proponents claim that L-arginine may help heart conditions, such as chest pain (angina), high blood pressure, leg cramping and weakness due to obstructed arteries (a condition known as intermittent claudication), and erectile dysfunction (ED).
Some people use L-arginine to boost the immune system, improve athletic performance, shorten recovery time after surgery, and promote weight loss.
L-arginine is also used for bodybuilding.

There are several additional areas that researchers are interested in exploring regarding L-arginine and L-arginines effects on the human body.
L-arginine is essential for anyone interested in taking L-arginine as a supplement to talk to their doctor about the potential benefits and risks before starting to use L-arginine.
Also, people should fully understand and examine the claims a manufacturer is making about their product before using L-arginine.

Other potential benefits of L-arginine:
In addition to the potential benefits listed above, some research suggests that L-arginine supplements may be helpful when used in the following ways:
Treatment of erectile dysfunction.
A 2019 review of 10 studies found that taking arginine supplements in doses ranging from 1.5–5 grams daily significantly improved erectile dysfunction, compared with a placebo or no treatment.
Improving blood flow.

Some evidence suggests L-arginine supplements may improve blood vessel function and blood flow in specific populations.
However, study results are conflicting, and many have found that L-arginine has no benefit.

Treating and preventing preeclampsia.
Studies have demonstrated that treatment with L-arginine during pregnancy may help prevent and treat preeclampsia, a dangerous condition characterized by high blood pressure and protein in the urine.
This list is not exhaustive, and L-arginine has been studied for L-arginines potential beneficial effects on various conditions, including obesity, heart disease, cancer, polycystic ovary syndrome (PCOS), infertility, and anxiety, either used on L-arginines own or in combination with other supplements.

However, research on the effects of L-arginine in people with these and many other conditions is limited and inconclusive, highlighting the need for future studies.
In addition to the potential benefits and uses above, many people take L-arginine supplements for a variety of other reasons, including reducing the risk of the common cold and boosting weight loss.
Yet, many of these purported benefits aren’t backed by scientific research.

Some people take L-arginine as a supplement.
As with any supplement, a person should use L-arginine with caution.

Although L-arginine is considered safe in moderate doses, too much L-arginine can have severe side effects, including death.
L-arginine is important to understand how the supplement may interact with the body and with additional medications before taking L-arginine.

Overdose of L-arginine:
As mentioned above, arginine is generally considered safe, even when used in high doses.
However, L-arginine’s possible to take too much arginine, which is especially dangerous for children.

Pregnancy and breastfeeding of L-arginine:
L-arginine is used in pregnancy under certain circumstances, including preeclampsia.
L-arginine supplementation during pregnancy is typically prescribed and monitored by a healthcare provider for a specific reason, such as preeclampsia or the risk of preeclampsia and intrauterine growth restriction (IUGR).

There’s some evidence that L-arginine supplements may improve pregnancy outcomes, as well as fetal and maternal health in women from both high- and low-resource areas.
This is because during pregnancy, the body’s need for L-arginine grows due to fetal development and placental growth.

This increased need may not be met through diet, especially in women living in low-resource settings without access to protein-rich foods.
Additionally, although the increased demand for arginine during pregnancy can be provided through diet, protein or individual amino acid supplements may be necessary under certain circumstances.

This may include women who follow restrictive diets or are experiencing severe nausea and vomiting during pregnancy, rendering them unable to meet demands through dietary intake.
However, supplements during pregnancy should always be approved and monitored by a healthcare provider.

If you are pregnant and interested in taking supplemental L-arginine, consult your healthcare provider for advice.
L-arginine supplements have not been researched in breastfeeding women.
For this reason, L-arginine’s important to ask your healthcare provider whether taking L-arginine supplements is safe and necessary for your individual needs during breastfeeding.

History of L-arginine:
Arginine was first isolated in 1886 from yellow lupin seedlings by the German chemist Ernst Schulze and his assistant Ernst Steiger.
He named L-arginine from the Greek árgyros (ἄργυρος) meaning "silver" due to the silver-white appearance of arginine nitrate crystals.

In 1897, Schulze and Ernst Winterstein (1865–1949) determined the structure of arginine.
Schulze and Winterstein synthesized arginine from ornithine and cyanamide in 1899, but some doubts about arginine's structure lingered until Sørensen's synthesis of 1910.

Properties of L-arginine:
Chemical formula: C6H14N4O2
Molar mass: 174.204 g·mol−1
Appearance: White crystals
Odor: Odourless
Melting point: 260 °C; 500 °F; 533 K
Boiling point: 368 °C (694 °F; 641 K)
Solubility in water: 14.87 g/100 mL (20 °C)
Solubility: slightly soluble in ethanol
insoluble in ethyl ether
log P: −1.652
Acidity (pKa): 2.18 (carboxyl), 9.09 (amino), 13.2 (guanidino)
LAROFLEX MP 45
Laroflex MP 45 Laroflex MP 45 a copolymer of vinyl chloride and vinyl isobutyl ether. Used as a binder in paints for iron and steel structures, mineral substrates, plastics, shipbuilding and underwater applications, mechanical and automotive engineering, transportation, protection of buildings and in printing inks industry and road marking paints. Compatible with vinyl chloride copolymers, polyacrylates, unsaturated polyester resins, maleate resins, cyclohexanone resins, aldehyde resins, coumarone and hydrocarbon resins. Also compatible with urea resins, alkyd resins modified by oils and fatty acids, natural resins, drying oils, plasticizers, tars and bitumen. Laroflex MP 45 provides hydrolysis resistance. Laroflex MP 45 gradeschlorinated binders, resistant to hydrolysis, for the manufacture of physically drying coatings on iron and steel, nonferrous metals, mineral substrates as well as for printing inksand road marking paints Nature copolymers based on vinyl chloride and vinyl isobutyl ether Range Laroflex MP 15 Laroflex MP 25 Laroflex MP 35 Laroflex MP 45 Laroflex MP 60 Physical form fine white powderStorage Laroflex MP 45 grades can be stored for 2 years if kept away fromheat and moisture.Laroflex MP 45 Product specification MP 15 MP 25 MP 35 MP 45 MP 60 of 12 Laroflex MP 45 grades Application Laroflex MP 45 grades are binders resistant to hydrolysis. They can beused for anti-corrosion coatings, for coatings on galvanized steel,other non-ferrous metals, concrete, fiber cement, for road markingpaints, flame-retardant coatings on non-flammable building materials, printing inks, marine and container paints. They are compatiblewith most alkyd resins, dry oils, polyacrylic resins, liquid epoxy resins, tars and bitumens. Overview Laroflex MP 45 grades offer advantages to both manufacturers andusers of coatings: • broad choice of solvents, particularly budget-priced blends ofaromatic and aliphatic hydrocarbons • good compatibility with other coatings raw materials • good pigment binding capacity even at high solids • unrestricted choice of pigments and extenders • easy application by all common techniques, no cob-webbingeven at high solids • thermal stability allows force drying • good adhesion on iron, steel and many unrelated coatings systems, good intercoat adhesion • good resistance of properly formulated coatings to aqueousalkalis and acids, salt solutions, to stress from water, humiditychanges, low and cyclic temperatures as well as to chalkingand yellowing • long lasting corrosion protection even under extreme outdoorconditions Differences in properties Laroflex MP 45 grades mainly differ in their viscosities and the rheology of their solutions. Viscosity ranges given in the table relate to20 % solutions in toluene at 23 °C (73 °F). The less polar the solvent,the greater the differences in viscosity. The low-viscous solutions of Laroflex MP 45 and Laroflex MP 45are diluted easiest with aliphatic hydrocarbons, their viscositychanges the least during storage and they produce highest gloss. The high-viscous solutions of Laroflex MP 45 tend to gel, particularly in non-polar solvents. Choosing the right solvent Suitable solvents are aromatic hydrocarbons or their blends withesters and glycolether acetates. Aliphatic hydrocarbons and/oralcohols are used as diluents. Ketones, in general, are less suited since they are retained by vinylchloride polymers longer than other solvents with equal volatility,resulting in slower drying coatings. 12 Laroflex MP 45 grades The diluent fraction of the solvent blend mainly depends on the solvency of the true solvent. Depending on the type of solvent andwhen Laroflex MP 45 or Laroflex MP 45 are used, the diluentproportion must be reduced by up to 40 % as compared with Laroflex MP 45. The diluent proportion can be increased if other raw materials inthe formulation are readily compatible with Laroflex MP 45 gradesand soluble in aliphatic hydrocarbons or alcohols. Examples arehard resins such as Laropal K 80, many alkyd resins, higharomatic grades of tar, soft resins and plasticizers present ingreater proportions.Aromatic hydrocarbons or blends of aromatic and aliphatic hydrocarbons are best suitable for coatings that are to be exposed towater very soon after application.High-volatile solvents and/or diluents produce faster drying coatings.Coatings containing a blend of xylene and butanol instead of xylenealone will dry faster. Polymers release esters more easily than ketones and aromatic hydrocarbons of the same volatility. The mostfavorable low-volatile solvent is ethoxypropyl acetate. Note that thesolvent retention also depends on the other constituents of theformulation. Gloss and flow of coatings can be improved by adding high-boilingsolvents, e.g., ethoxypropyl acetate. High proportions of low-volatilediluents, however, may result in precipitating of binder constituents,impairing both gloss and mechanical properties of the coatings. Greater proportions (20–25 %) of high-boiling solvents, e.g., ethoxypropyl acetate or blends of aromatic hydrocarbons with a boilingrange of 150 °C (302 °F) to 190 °C (374 °F) reduceblistering whichmay occur in airless-sprayed coatings, particularly those with a lowpigment content.High proportions of diluent in the solvent blend reduce the risk ofprevious coats pulling up. Clear or almost clear solutions can be obtained in aromatic hydrocarbons such as toluene, xylene or Solvesso1 100 as well as inchlorinated hydrocarbons, anone and tetrahydrofuran. Solutionswith other solvents may be somewhat cloudy but will not adverselyinfluence hardness and homogeneity of the film, provided the solution dries to form a clear film. Viscosity behavior of the solution The viscosity of solutions of Laroflex MP 45 grades not only dependson the concentration, the composition of the solvent blend and itstemperature, but also on the conditions under which they are prepared.registered trademark of Exxon Mobil Corporation of 12 Laroflex MP 45 grades The higher the temperature as well as duration and extent of shearforces, the lower the viscosity of the solution will be after coolingdown to room temperature. After extended storage, the viscositymay increase again, an effect that is more pronounced the less thesolvating power and the affinity between solvents and polymer. Unpigmented concentrated solutions of Laroflex MP 45 grades inxylene may tend to gel – often only months after they have beenprepared and without undergoing a gradual increase in viscosity. Adding ketones and esters reduces the tendency to gel, in particular if the binder concentration is high. By adding 10–20 % of analcohol to the solvent blend, gelling generally can be suppressedcompletely. Likewise, no gelling has been observed yet in formulations containing blends of high-boiling aromatics such asby intensive stirring, heating or by milling with pigments. This rheological behavior is quite pronounced in Laroflex MP 45. Itis scarcely noticed in Laroflex MP 45 and not at all in Laroflex MP 45 and Laroflex MP 45. Typical solvent blends 1. Coatings based on Laroflex MP 45 grades without significant amounts of cobinders:of 12 Laroflex MP 45 grades 2. Coatings based on 1:1 blends of Laroflex MP 45 grades and Plasticizing Laroflex MP 45 grades are internally plasticized. Coatings based on 4 F) or polyester resins in larger proportions of 15–30 %. In formulations based on Laroflex MP 45, the plasticizer propotion should be kept some 10–15 % lower than in those based onthe other Laroflex MP 45 grades. Too much plasticizer will adversely affect the hardness and thermostability of the dried coatings and can promote shrinkage, alligatoring and soiling of outdoor coatings. Coatings that have to withstand chemicals and salt water are formulated with plasticizers resistant to saponification, e.g., chlorinated paraffin waxes. Saponifiable plasticizers (phthalates, adulatesor phosphates) can be used when resistance to chemicals is lessimportant. Plastigen G is the plasticizer of choice for coatings onalkaline substrates (e.g., concrete) and for top coats extraordinarilyresistant to yellowing and chalking. Laroflex MP 45 gradesAcronal 4 F and its mixtures with phthalates are particularly suitable to increaseadhesion to aluminum and its alloys and otherdifficult substrates. The flexibility and adhesion of films based on Laroflex MP 45 grades at low temperatures can be increased by using low-viscosity, high-efficiency plasticizers (Palatinol 911 andPlastomoll DOA). Plasticizers which are insoluble in aliphatic hydrocarbons (Palamoll 646) least impair the resistance of filmsbased on Laroflex MP 45 grades to lubricants and fuel oil.Modification by other coatings raw materialsHard resins Solids content, gloss and adhesion can be increased by adding hard resins.Non-saponifiable hard resins such as Laropal K 80 are recommended for coatings resistant to chemicals and water. For nonpale coatings or when less emphasis is put on resistance to light and weathering, coumarone, indene or hydrocarbon resins can beused. Saponifiable hard resins (e.g., maleate or modified phenolicresins) can be used if good resistance to chemicals is not required.Hard resins which are compatible with Laroflex MP 45 grades (e.g.,Laropal K 80 or Laropal A 81) are often able to overcome anyslight incompatibility on the part of other materials present in theformulation. Laropal K 80 and Laropal A 81 increase the diluenttolerance of coatings based on Laroflex MP 45 grades for aliphatic hydrocarbons.Air-drying bindersAir-drying binders reduce the thermoplasticity of Laroflex MP 45 grades.Combined with a predominant proportion of air-drying binder,Laroflex MP 45 grades improve the coating’s • surface drying and thus its initial hardness, • resistance to chemicals and water, • outdoor performance, particularly in industrial environments. If resistance to chemicals and water is essential, the proportion of Laroflex MP 45 should be at least the same as that of the air-drying binder. The lower acid value and average molecular mass of an alkyd resin, the better its compatibility – which should be checked in each case. The most compatible alkyd resins are those containing about 45– 55 % drying or 25–50 % semidrying oils. Other compatible binders are bodied oils with modified phenolic resins, various urethane/alkyd resins and some epoxy resins modified by oil fatty acids. 12 Laroflex MP 45 grades In many cases, air-drying binders can be made perfectly compatible with Laroflex MP 45 grades by including other compatible components, e.g., Laropal K 80, Laropal A 81 or plasticizers. In combinations of Laroflex MP 45 grades with alkyd resins, theamount of white spirit in the solvent blend can often be increasedwell above the proportion normally used in coatings solely containing Laroflex MP 45 grades (see Typical solvent blends earlier in this chapter). If these “hybrid binder” coatings are to be overcoated, care must betaken to ensure that oxidative drying has progressed so far thatthere is no risk of “pulling up” caused by excessive softening of thefirst coat by the solvent phase of the second coat. The tendency ofpulling up can be reduced by increasing the proportion of Laroflex MP 45 grades. Equally, the solvent can be diluted with more whitespirit. Solvent blends whose proportion of diluents increases gradually and only to a limited extent perform best. An example is a blendconsisting of equal parts of xylene and white spirit. Pigmentation Any conventional anti-corrosion pigment can be used in primersbased on Laroflex MP 45 grades as chemical reactions between thetwo are unlikely. Based on our current experience, the binder – ifstored under normal conditions – does not need to be stabilizedagainst attack by active metal powders such as aluminum bronze. If there are any doubts, small proportions of zinc oxide or epoxycompounds may be added. registered trademark of Resolution Nederland B. V. Laroflex MP 45 grades Higher proportions of flake extenders or pigments in the pigmentblend (e.g., talc, micaceous iron oxide or aluminum bronze) improve the coatings’ adhesion and impermeability to water vapor,they also facilitate airless spraying of thick coats. Pigments and extenders resistant to weathering should be preferredfor topcoats. Some extenders – including a few natural magnesium,aluminum or potassium-aluminum silicates as well as barytes –contain impurities, which may cause yellowing of white topcoats. Asmall amount of zinc white generally prevents such discoloration. Pigments resistant to acids and alkalis must be used for coatingsresistant to chemicals. Effective corrosion protection is achieved with coatings having apigment volume concentration (PVC) of 16–35 %. For coatingsparticularly resistant to chemicals, a lower PVC range of 16–22 %should be preferred. Well-formulated high-build finishes, on theother hand, can be pigmented up to about 35 %. In general, thepigmentation level should be limited to 90 % of the critical PVC. Stabilizers Laroflex MP 45 grades are sufficiently stable to dehydrochlorination. Thus no stabilizers are normally needed. Exceptions are coatingsthat are either exposed to heat or unpigmented or – in some casesof coatings based on transparent pigments – exposed to UV radiation for extended periods. Note that chlorinated binders are less stable if moisture or somechemicals are present. Generally, coatings systems based on Laroflex MP 45 grades shouldnot be exposed to heat above 70–80 °C (158–176 °F) for prolongedperiods.Heat stabilizers should be added for force drying at temperatures ofup to 130 °C (266 °F). Adding 2 % Mark®4 17 M and 3 % Drapex439 (respective to Laroflex MP 45) provides adequate stabilization. Dispersants,antisettling agents,thixotropes Some dispersants or antisettling agents, particularly in higher proportions, may act with chlorinated binders to cause corrosion ofmetal containers and thus reduce the coating’s anticorrosion protection. Trials are recommended. Thixotropes derived from hydrogenated castor oil (e.g., Luvotix5 or Thixatrol6 ST) can be used for high-build coatings. Manufacturer’s instructions on their use should be observed. registered trademark of Crompton Vinyl Additives registered registered trademark of Elementis plc 12 Laroflex MP 45 grades Further, suitable thickeners and antisettling agents consist of anapproximately 10 % gel paste made from Bentone®6 38 or Bentone®639 and Anti-Terra®7 U in aromatic solvents. Processing Production of coatings Laroflex MP 45 grades dissolve very rapidly even without heating. Caking is avoided by immediately and uniformly distributing thepowder: thoroughly stirring, it is slowly added to the diluent (aliphatic hydrocarbons, alcohols). Proportions of Laroflex MP 45 powder and diluent should be approximately equal. Then, solvent(s)and other diluents are added while stirring. Subsequently, plasticizers and combination resins may be added. Solutions of Laroflex MP 45 grades that contain plasticizers and possibly other binder components are used to paste and mill pigments. If alkyd resin cobinders are present in the formulation, thesecan be used to prepare the pigment paste. Application techniques Coatings based on Laroflex MP 45 grades are suitable for all common application techniques such as high-pressure spraying, airlessspraying, hot spraying, brushing, dipping, curtain or roller coatingor paint roller. No cob webbing occurs during the application of coatings basedon Laroflex MP 45 grades even at high solids or if they contain highlyvolatile solvents. Blistering and pore formation during airless spraying can beavoided by keeping the proportion of highly volatile esters (e.g.,ethyl acetate and butyl acetate) in the solvent blend low. The inclusion of high-boiling aromatic hydrocarbons or ethoxypropyl acetatein advantageous. Good results are also obtained with defoamers,especially in paints with low PVC. Solutions of Laroflex MP 45 grades that contain plasticizers and possibly other binder components are used to paste and mill pigments. If alkyd resin cobinders are present in the formulation, thesecan be used to prepare the pigment paste. Application techniques Coatings based on Laroflex MP 45 grades are suitable for all common application techniques such as high-pressure spraying, airlessspraying, hot spraying, brushing, dipping, curtain or roller coatingor paint roller. registered trademark of Byk-Chemie GmbH Laroflex MP 45 grades No cob webbing occurs during the application of coatings based on Laroflex MP 45 grades even at high solids or if they contain highlyvolatile solvents. Blistering and pore formation during airless spraying can beavoided by keeping the proportion of highly volatile esters (e.g.,ethyl acetate and butyl acetate) in the solvent blend low. Theinclusion of high-boiling aromatic hydrocarbons or ethoxypropyl acetatein advantageous. Good results are also obtained with defoamers,especially in paints with low PVC. Drying Coatings based on Laroflex MP 45 grades surface-dry rapidly butrequire some length of time to through-dry since Laroflex MP 45grades, like all polymers, tend to hold back residual solvent. Consequently, a drying time of one or two days should be left betweencoats to prevent pulling up. Coatings to be exposed to water orliquid chemicals must be allowed to through-dry thoroughly. In thiscase, polar solvents should be avoided as any residual solventcould absorb large amounts of water and cause swelling. Drying time can be reduced by choosing suitable solvent blends,reducing the plasticizer proportion, a higher PVC or adding voluminous extenders or diatomite. Excessive quantities of these extenders and inadequate pigment dispersion can easily lead to porouscoatings with greater permeability to water vapor. Fields of application Industrial corrosion protection Combinations of equal proportions of Laroflex MP 45 grades and airdrying binders have proven effective. Two to three coats of thixotropic high-build coatings are needed toobtain the overall thickness of 200–250 µm necessary for effectivecorrosion protection. Depending on the make-up of the system andthe quality of pigments and extenders, the PVC is 30–40 %. Lowerpigmented gloss coats may be used for top coats. Marine coatings, underwater corrosion protection Coatings having to withstand sea or river water can be formulatedwith Laroflex MP 45 grades and non-saponifiable hydrophobic plasticizers. Combinations with tar and/or hydrocarbon resins can also beused, some of the Laroflex MP 45 proportion may be replaced by apolyamine-cured epoxy resin. A PVC of 35–40 % is ideal for highbuild coatings. These adhere extremely well to sandblasted steel,commercial shop primers and other unrelated coating systems. Laroflex MP 45 grades being resistant to alkalis allow formulatingunderwater coatings that give excellent performance in cathodicprotection and on zinc/ethyl silicate primers. Since high-build coatings based on Laroflex MP 45 grades can be sprayed outstandinglywell, only two or three spray coats are needed to achieve perfectcorrosion protection. 11 of 12 Laroflex MP 45 grades Laroflex MP 45 grades can also be used as binders in antifoulingpaints. Hydrophylic cobinders like Lutonal M 40 approx. 70 % inethanol and/or rosin ensure that the antifouling agent is released ata uniform rate. Machinery, automotive and container finishes Suitable coatings can be formulated from Laroflex MP 45 grades androughly equal amounts of air-drying binder. Coatings on galvanized steel and aluminumAir-drying binders should be avoided in primers and top coats onaluminum or, in particular, galvanized steel. Coatings based onsuch binders could flake or peel off after prolonged exposure tomoisture and fluctuating temperature. Addition of special hardresins, talc and/or micaceous iron oxide allow coats with extremelygood adhesion. Coatings for mineral substrates Laroflex MP 45 grades and alkali-resistant plasticizers are used toobtain coatings for mineral substrates. The pigmentation dependson the desired degree of gloss. Architectural finishes with adequate permeability to water vaporshould have a PVC of 50–60 %.Combinations of Laroflex MP 45 grades, polyamine-cured epoxyresins and tar are used for underwater and underground mineralsubstrates. The PVC for swimming pool coatings should be at least 50 % inorder to avoid blisters forming from osmosis, even in high-buildcoats. Since they are resistant to hydrolysis, Laroflex MP 45 grades aresuitable binders for sealing and impregnating primers for stabilizingmineral substrates and reliably ensuring that subsequent coats ofarchitectural finishes adhere well. Depending on the substrate’sactual porosity, the binder concentration in these coatings shouldbe 8–15 %. Road marking paintsRoad marking paints can be formulated from Laroflex MP 45 gradesalone or combined with air-drying binders. Note, however, that airdrying binders will reduce the life of road markings.Flame-retardant coatings Laroflex MP 45 grades are suitable binders for flame-retardant coatings on non-flammable substrates. of 12 Laroflex MP 45 grades Other fields of application: • indoor and outdoor coatings on wood and duroplastics • printing inks • impregnating and coating of paper, cardboard and textiles • effect paints such as wrinkle, hammer and crackle finishes Safety When handling these products, advice and information given in thesafety data sheet must be complied with. Further, protective andworkplace hygiene measures adequate for handling chemicalsmust be observed.NoteThe data contained in this publication are based on our currentknowledge and experience. In view of the many factors that mayaffect processing and application of our product, these data do notrelieve processors from carrying out their own investigations andtests; neither do these data imply any guarantee of certain properties, nor the suitability of the product for a specific purpose. Anydescriptions, drawings, photographs, data, proportions, weights,etc. given herein may change without prior information and do notconstitute the agreed contractual quality of the product. It is theresponsibility of the recipient of our products to ensure that anyproprietary rights and existing laws and legislation are observed. olubility: Laroflex MP 45 is well soluble in aromatic and chlorinated hydrocarbons, ester, ketone, glycol ether acetates, and some glycol ether. Usually Laroflex MP 45 is dissolved in 20% toluene/xylene solvent at normally temperatures. Compatibility: Laroflex MP 45 miscible with or partly miscible with vinyl chloride copolymer, polyacrylic ester, unsaturated polyester resins, aldehyde resins, petroleum resin, natural resins, alkyd resins modified by oil and fatty acids, drying oil, tars, and bitumen, etc. Application: Laroflex MP 45 is well used as basic resins in anticorrosion paint (steel structure, container, marine, underwater structure, machinery and automobile engineering, transport equipment & industrial paint) and it is also well-known in composite inks. Laroflex MP 45 is a binder resistant to hydrolysis. It can be used for anti-corrosion coatings, for coatings on galvanized steel, other non-ferrous metals, concrete, fiber cement, road marking paints, flame-retardant coatings on non-flammable building materials, and marine and container paints. Laroflex MP 45 is recommended for applications such as: •Interior/exterior general industrial metal coating applications •Interior/exterior plastic component applications •Interior/exterior concrete coating applications •Product Description •Laroflex MP 45 has good binding property as a result of its special molecular structure in which ester bond is resistance to hydrolysis and combined chlorine atom is very stable. So Laroflex MP 45 can be used to produce hign quality paints with good water resistance, salt resistance and chemical resistance. •Good adhesion •Laroflex MP 45 contain copolymer of vinyl chloride ester, which ensure the paints good adhesion on various materials. Even on the surface of aluminum or zinc, the paints still have good adhesion. •Good compatibility •Laroflex MP 45 is easily compatible with other resins in paints, and can modify and improve the characteristics of paints, which for mulated by drying oils, tars and bitumen. •Solubility •Laroflex MP 45 is soluble in aromatic and halohydrocarbon, esters, ketones, glycol, ester acetates and some glycol ethers. Aliphatic hydrocarbons and alcohols are diluents and not true solvents for Laroflex MP 45 •Compatibility •Laroflex MP 45 is compatible with vinyl chloride copolymers, unsaturated polyester resins, cyclohexanone resins, aldehyde resins, coumarone resins, hydrocarbon resins, urea resins, alkyd resins modified by oil and fatty acids, natural resins, drying oil, plasticizers, tars, and bitumen. •Fireproof Ability •Laroflex MP 45 contain chlorine atom, which gives the resins fireproof ability. With addition of other flame resistant pigment, filler and fire retardant, they can be used in fire retardant paint for construction and other fields.
LAURAMIDE DEA
Dodecyl-N,N-bis(2-hydroxyethyl) Amide; Lauric DEA; Bis(2-hydroxyethyl)lauramide; Diethanolamine lauric acid amide; diethanollauramide; Diethanol lauric acid amide; N,N-diethanollauramide; N,N-diethanollauric acid amide; N,N-bis(hydroxyethyl)lauramide; Lauramide DEA; N,N-bis(2-hidroxietil)dodecanamida; N,N-bis(2-hydroxyéthyl)dodecanamide; cas no: 120-40-1
LAURAMIDOPROPYL BETAINE
LAURAMINE OXIDE, LAURAMIDOPROPYLAMINE OXIDE, N-[3-(dimethylamino)propyl]dodecanamide N-oxide; 3-(dodecanoylamino)-N,N-dimethylpropan-1-amine oxide; 3-[dodecanoyl(oxido)amino]-N,N-dimethylpropan-1-amine; N° CAS : 61792-31-2, Nom INCI : LAURAMIDOPROPYLAMINE OXIDE, Nom chimique : N-[3-(Dimethylamino)propyl]dodecanamide N-oxide, N° EINECS/ELINCS : 263-218-7, Ses fonctions (INCI). Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent nettoyant : Aide à garder une surface propre Sinergiste de mousse : Améliore la qualité de la mousse produite en augmentant une ou plusieurs des propriétés suivantes: volume, texture et / ou stabilité Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance Hydrotrope : Augmente la solubilité d'une substance qui est peu soluble dans l'eau. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : (3-LAURAMIDOPROPYL)DIMETHYLAMINE OXIDE; 3-LAURAMIDO-N,N-DIMETHYLPROPYLAMINE OXIDE; DODECANAMIDE, N-(3-(DIMETHYLAMINO)PROPYL)-, N-OXIDE; LAUROYLAMINOPROPYLDIMETHYLAMINE OXIDE ; N-(3-(DIMETHYLAMINO)PROPYL)-N-OXYDE DODECANAMIDE. Utilisation et sources d'émission: Fabrication d'imperméabilisants
LAURAMIDOPROPYLAMINE OXIDE ( LAUROYLAMINOPROPYLDIMETHYLAMINE OXIDE)
Lauryldimethylamine oxide, Lauramine oxide; Dodecyldimethylamine oxide; Dimethyldodecylamine-N-oxide, N,N-Dimethyldodecan-1-amine oxide, N° CAS : 1643-20-5, Nom INCI : LAURAMINE OXIDE, Nom chimique : Dodecyldimethylamine oxide. N° EINECS/ELINCS : 216-700-6. Ses fonctions (INCI): Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent nettoyant : Aide à garder une surface propre. Sinergiste de mousse : Améliore la qualité de la mousse produite en augmentant une ou plusieurs des propriétés suivantes: volume, texture et / ou stabilité. Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance. Hydrotrope : Augmente la solubilité d'une substance qui est peu soluble dans l'eau.Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques. Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. Noms français : 1-DODECANAMINE, N,N-DIMETHYL-, N-OXIDE; DODECYLAMINE, N,N-DIMETHYL-, N-OXIDE; LAURYLDIMETHYLAMINE N-OXIDE; N,N-DIMETHYL-1-DODECANAMINE N-OXIDE;N,N-DIMETHYL-1-DODECANAMINE-N-OXIDE; N,N-DIMETHYL-1-DODECYLAMINE-N-OXIDE; N,N-DIMETHYL-N-DODECYLAMINE OXIDE; N,N-DIMETHYLDODECYLAMINE OXIDE; N-DODECYLDIMETHYLAMINE OXIDE; N-LAURYL-N,N-DIMETHYLAMINE OXIDE; N-LAURYLDIMETHYLAMINE N-OXIDE; N-OXYDE DE DIMETHYLAURYLAMINE; Oxyde de lauryldiméthylamine Noms anglais : DDNO; DIMETHYLAURYLAMINE OXIDE; DIMETHYLDODECYLAMINE OXIDE; DIMETHYLLAURYLAMINE OXIDE; DODECYL DIMETHYLAMINE OXIDE; DODECYLDIMETHYLAMINE OXIDE; LAURAMINE OXIDE; Lauryldimethylamine oxide. Utilisation et sources d'émission: Fabrication de savons, agent dispersant
LAURAMINE OXIDE ( Lauryldimethylamine oxide ) Oxyde de lauryldiméthylamine
LAURAMIDE N° CAS : 1120-16-7 Nom INCI : LAURAMIDE Nom chimique : Lauramide N° EINECS/ELINCS : 214-298-7 Ses fonctions (INCI) Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
Lauramide
Lauramine oxide; Lauryldimethylamine oxide; Dodecyldimethylamine oxide; Lauryldimethylamine N-oxide; LDAO; Dimethyldodecylamine oxide; 1-Dodecanamine, N,N-dimethyl-, N-oxide; Ammonyx AO; Ammonyx LO; Empigen OB; Aromox DMCD; Conco XA; Dimethylaurylamine oxide; n-Dodecyldimethylamine oxide; Dimethyldodecylamine N-oxide; Dodecyldimethylamine N-oxide; dodecyl(dimethyl)amine oxide; N,N-Dimethyldodecylamine N-oxide; N,N-dimethyldodecan-1-amine oxide; CAS NO:1643-20-5
Lauramine oxide
SYNONYMS n-Dodecylamine; 1-Dodecanamine; Lauramine; 1-Aminododecane; Laurinamine;CAS NO. 124-22-1
LAURDIMONIUM HYDROXYPROPYL HYDROLYZED WHEAT
LAURETH-1, peg-1 lauryl ether, polyethylene glycol (1) lauryl ether, polyethylene glycol (1) lauryl ether, polyethylene glycol (1) monolauryl ether, polyoxyethylene (1) lauryl ether, polyoxyethylene (1) monolauryl ether, LAURETH-1, N° CAS : 4536-30-5, Nom INCI : LAURETH-1, Nom chimique : 2-(Dodecyloxy)ethanol, N° EINECS/ELINCS : 224-886-5, Classification : Composé éthoxylé, Ses fonctions (INCI): Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile).Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant; 2-(Dodecyloxy)ethanol [ACD/IUPAC Name] 2-(Dodecyloxy)ethanol [German] [ACD/IUPAC Name] 2-(Dodécyloxy)éthanol [French] [ACD/IUPAC Name] 224-886-5 [EINECS] 4536-30-5 [RN] Dodecylglycol Ethanol, 2-(dodecyloxy)- [ACD/Index Name] Ethylene Glycol Monododecyl Ether IAC0DWO8W5 J89TKQ5R54 KK7650000 MFCD00042657 [4536-30-5] 2-(Decyloxy)ethanol [ACD/IUPAC Name] 2-(dodecyloxy)ethan-1-ol 2-decoxyethanol 2-dodecoxyethanol 2-dodecyloxyethan-1-ol 2-Hydroxyethyl lauryl ether 2-lauryloxyethanol 3,6,9,12-Tetraoxadocosan-1-ol [ACD/Index Name] [ACD/IUPAC Name] 4-01-00-02386 [Beilstein] aethoxysklerol Asclera Brij 35 (Laureth-23) CE1 Cimagel Decylglycol Dodecanol, ethoxylate Dodecyl-β-D-maltoside Ethanol, 2-(decyloxy)- [ACD/Index Name] Ethanol,2-(dodecyloxy)- ethylene glycol dodecyl ether Ethylene glycol monodecyl ether Ethylene glycol monolauryl ether Ethylene glycol mono-n-dodecyl ether ethyleneglycol monododecyl ether Ethyleneglycoldodecylether ethyleneglycolmonododecylether Laureth Laureth- 23 laureth-4 Lauryl ethoxylate Lauryl monoethoxylate LMT Nikkol BL O-DODECANYL OCTAETHYLENE GLYCOL Rokanol L Romopal LN Siponic L Slovasol O Slovasol S Thesat Thesit UNII:J89TKQ5R54 UNII-3Y76363WPB UNII-J89TKQ5R54 UNII-P30F471M6B VARITHENA
LAURETH-1 ( Éther de lauryl poly(oxyéthylène))
LAURETH-10, peg-10 lauryl ether, polyethylene glycol (10) lauryl ether, polyethylene glycol (10) lauryl ether, polyethylene glycol (10) monolauryl ether, polyoxyethylene (10) lauryl ether, polyoxyethylene (10) monolauryl ether, LAURETH-10, N° CAS : 9002-92-0 / 6540-99-4 / 68002-97-1. Nom INCI : LAURETH-10. N° EINECS/ELINCS : 500-002-6 / - / 500-182-6. Classification : Composé éthoxylé, Tensioactif non ionique. Le Laureth-10 est un tensioactif non ionique très doux. Il est produit par éthoxylation à partir d'alcool laurique. Le chiffre 10 indique le nombre moyen d'unités d'oxyde d'éthylène répétées dans la molécule. Il est souvent utilisé dans les cosmétiques en tant qu'agent émulsifiant (permet aux corps gras de se mélanger facilement à l'eau).Ses fonctions (INCI) Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-10
LAURETH-10 CARBOXYLIC ACID, N° CAS : 27306-90-7, Nom INCI : LAURETH-10 CARBOXYLIC ACID. Classification : Composé éthoxylé. Ses fonctions (INCI) : Agent nettoyant : Aide à garder une surface propre. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation
LAURETH-10 CARBOXYLIC ACID
LAURETH-12, peg-12 lauryl ether, polyethylene glycol (12) lauryl ether, polyethylene glycol (12) lauryl ether, polyethylene glycol (12) monolauryl ether, polyoxyethylene (12) lauryl ether, polyoxyethylene (12) monolauryl ether, LAURETH-12, N° CAS : 3056-00-6 / 9002-92-0, Nom INCI : LAURETH-12. Nom chimique : 3,6,9,12,15,18,21,24,27,30,33,36-Dodecaoxaoctatetracontan-1-ol. N° EINECS/ELINCS : 221-286-5, Classification : Composé éthoxylé.Ses fonctions (INCI). Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-10 CARBOXYLIC ACID
Laureth-10 Carboxylic Acid is an organic acid.


CAS Number: 27306-90-7
Chem/IUPAC Name: Poly(oxy-1,2-ethanediyl),.alpha.-carboxymethyl-.omega.-dodecyloxy-, (10 mol EO average molar ratio)


Dive into the world of Laureth-10 Carboxylic Acid, a powerful anionic surfactant renowned for its superior detergency and foaming abilities.
This versatile chemical compound, Laureth-10 Carboxylic Acid, is utilized in a range of applications, from personal care products to industrial cleaners, and offers excellent emulsifying and wetting properties.


It's ability to boost foam production and effectively remove dirt and oils makes Laureth-10 Carboxylic Acid a valuable addition to your formulations.
Laureth-10 Carboxylic Acid is a mild co-surfactant and functions as an emulsifier and solubilizer.
Laureth-10 Carboxylic Acid is extremely mild and compatible with other surfactants as well as ideal as co-surfactants and coupling agents.


Laureth-10 Carboxylic Acid has all the qualities that show outstanding pH stability and high tolerance against electrolytes and builders.
Laureth-10 Carboxylic Acid is a crypto-anionic surfactant - Laureth-10 carboxylic acid - (Laureth-10 Carboxylic Acidcombines the properties of the anionic and non-ionic surfactants).


Laureth-10 Carboxylic Acid has good foaming and solubilizing properties being very mild for the skin.
Laureth-10 Carboxylic Acid is a wide range of secondary surfactants with excellent tolerance against hard water.
Laureth-10 Carboxylic Acid is an essential additive for long-lifetime metalworking fluids.
Laureth-10 Carboxylic Acid is characterized by their outstanding hard water and electrolyte tolerance compared to other emulsifiers used in metalworking.


"Laureth-" refers to a PEG-(polyethylene glycol-) ether of lauryl alcohol.
The number behind "laureth-" refers to the average number of molecular units -CH2-CH2-O-.
"Carboxylic acid" refers generally to a carboxylic or carbonic acid.



USES and APPLICATIONS of LAURETH-10 CARBOXYLIC ACID:
Laureth-10 Carboxylic Acid is depending on the carbon chain length and the ethoxylation degree the products show characteristic application properties.
Laureth-10 Carboxylic Acid brings excellent lime soap dispersing properties and adds some anti-corrosion benefits.
Laureth-10 Carboxylic Acid can be used in conveyor belt lubricants.


Laureth-10 Carboxylic Acid has all the qualities that show outstanding pH stability and high tolerance against electrolytes and builders.
Laureth-10 Carboxylic Acid is an extremely mild surfactant with good emulsifying properties and insensitive to water hardness, it substantially improves the skin’s tolerance of cleansers.


Laureth-10 Carboxylic Acid is particularly suitable for high-quality formulations, baby shampoos, and products designed for sensitive skin.
Laureth-10 Carboxylic Acid is used high foaming mild co-surfactant for cosmetic applications.
Laureth-10 Carboxylic Acid is used in Hard water stable.


Laureth-10 Carboxylic Acid is used applicable in hypochlorite solutions.
Laureth-10 Carboxylic Acid is used emulsifying and solubilizing properties
Laureth-10 Carboxylic Acid is mainly used in various shampoos and personal care liquid products, especially for the preparation of baby shampoo, also used as detergents and industrial emulsifiers, dispersing agents, foaming agents and wetting agent.


Laureth-10 Carboxylic Acid combines the properties of the anionic and non-ionic surfactants.
Laureth-10 Carboxylic Acid has good foaming and solubilizing properties with excellent mildness to skin and mucous membranes
Laureth-10 Carboxylic Acid is used as emulsifier or coemulsifier for paste cosmetics.


Laureth-10 Carboxylic Acid is used Mild shampoo, body wash, facial cleanser, hand sanitizer and other personal cleaning and protection products.
Laureth-10 Carboxylic Acid is used mixed into the soap block mild, calcium soap dispersion, foam performance and bath feeling.
Laureth-10 Carboxylic Acid is used for household detergents, industrial cleaning agents and phosphorus free detergents.


Laureth-10 Carboxylic Acid is used in textile industry refining, mercerizing, bleaching, soft, dyeing and other processes.
Laureth-10 Carboxylic Acid is used as an emulsifier and viscosity reducer resistant to high concentration electrolyte, it is used in tertiary oil recovery and oil transportation to provide crude oil recovery.


Laureth-10 Carboxylic Acid is used surfactant for mild personal care products (shampoos, shower gels, foam baths, other low-irritation formulations); surfactant for industrial applications (agrochemicals, textile treatment); detergent for carpet cleaners especially aerosols
Laureth-10 Carboxylic Acid is used Paper industry for waste paper deinking and softening agent formula.


Laureth-10 Carboxylic Acid is used as foaming agent for foam fire extinguishing.
Laureth-10 Carboxylic Acid uses and applications include: Surfactant, emulsifier, dispersant, superfatting agent, foam stabilizer for emulsions, detergents, shampoos, bubble baths


Laureth-10 Carboxylic Acid is used with overall physico-chemical stability, that improves lathering, enhances quat's and hair dyes efficiency providing combined benefits of nonionic and anionic surfactants.
Applications of Laureth-10 Carboxylic Acid: Beauty & Care, Hair Care, Oral Care, Skin Care, Home Care, Auto Care, Carpet & Upholstery, Dish Care, and Laundry & Fabric Care


Other Home Care Applications of Laureth-10 Carboxylic Acid: Surface Care Institutional & Industrial Care, Commercial Laundry, Food Facility Cleaning & Sanitization, Industrial Cleaning, and Institutional & Catering.
Laureth-10 Carboxylic Acid is used Other Institutional & Industrial Care, Vehicle & Machinery, Personal Hygiene, Hand Hygiene, Processing & Packaging, and Food & Beverage Manufacturing.


Hair Care Applications of Laureth-10 Carboxylic Acid: Hair Color, Home Care Applications, Household Cleaners, I&I Cleaning Applications, Automotive Cleaners, and Industrial Cleaners.
Laureth-10 Carboxylic Acid is used as a degreaser component in the leather industry.



FUNCTIONS OF LAURETH-10 CARBOXYLIC ACID:
*Cleansing :
Laureth-10 Carboxylic Acid helps to keep a clean surface
*Surfactant :
Laureth-10 Carboxylic Acid reduces the surface tension of cosmetics and contributes to the even distribution of the product when it is used



FUNCTIONS OF LAURETH-10 CARBOXYLIC ACID:
*Surfactant,
*Surfactant (Anionic),
*Solubilizer,
*Foaming Agent,
*Foam Booster,
*Cosurfactant,
*Cleansing Agent



INDUSTRIES OF LAURETH-10 CARBOXYLIC ACID:
*Oral Care
*Trends
*Hair Care
*Skin Care



PROPERTIES OF LAURETH-10 CARBOXYLIC ACID:
*Co-Surfactant
*Emulsifier
*Solubilizer
*Mild



FUNCTIONS OF LAURETH-10 CARBOXYLIC ACID IN COSMETIC PRODUCTS:
*CLEANSING
Cleans skin, hair or teeth
*SURFACTANT - CLEANSING
Surface-active agent to clean skin, hair and / or teeth



WHAT DOES LAURETH-10 CARBOXYLIC ACID DO IN A FORMULATION?
*Cleansing
*Surfactant



PERFORMANCE OF LAURETH-10 CARBOXYLIC ACID:
1, Laureth-10 Carboxylic Acid has good decontamination, emulsification, dispersibility and dispersion of calcium soap.
2, Laureth-10 Carboxylic Acid has good foaming power and foam stability.
3, Laureth-10 Carboxylic Acid has resistance to acid and alkali, hard water and oxidants, reducing agents.
4, Laureth-10 Carboxylic Acid has good compatibility, no interference with the performance of the cation.
5, Laureth-10 Carboxylic Acid has solubilization performance, suitable for preparation of functional transparent products.
6. Laureth-10 Carboxylic Acid is easy to biodegrade.



CHARACTERISTICS OF LAURETH-10 CARBOXYLIC ACID:
1. Good foaming performance and detergency;
2. Strong resistance to hard water, high solubility in water;
3. Mildness, good compatibility with other surfactants;
4. Be stable under acid, alkali, high temperature, low irritation to the skin and clothes



FAMILIES OF LAURETH-10 CARBOXYLIC ACID:
*Cleaning Aids
*Emulsifiers & Demulsifiers



FUNCTIONAL ADDITIVES OF LAURETH-10 CARBOXYLIC ACID:
*Foam Control Agents,
*Other Functional Additives,
*Performance Additives



FUNCTIONALS OF LAURETH-10 CARBOXYLIC ACID:
*Emulsifiers, Solubilizers & Dispersants
*Soaps & Surfactants
*Anionic Surfactants,
*Blends & Other Surfactants
*Surfactants & Cleansers
*Anionic Surfactants



CLEANING INGREDIENTS FUNCTIONS OF LAURETH-10 CARBOXYLIC ACID:
*Cleansing Agent,
*Co Emulsifier,
*Cosurfactant,
*Emulsifier,
*Foam Booster,
*Foaming Agent,
*Solubilizer,
*Surfactant,
*Surfactant (Anionic)



FEATURES AND BENEFITS OF LAURETH-10 CARBOXYLIC ACID:
*Mild



MARKETS OF LAURETH-10 CARBOXYLIC ACID:
*Food & Nutrition,
*HI&I Care,
*Personal Care



FIRST AID MEASURES of LAURETH-10 CARBOXYLIC ACID:
-General advice:
Consult a physician.
-If inhaled:
If breathed in, move person into fresh air.
Consult a physician.
-In case of skin contact:
Wash off with soap and plenty of water.
Consult a physician.
-In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes.
Consult a physician.
-If swallowed:
Rinse mouth with water.
Consult a physician.



ACCIDENTAL RELEASE MEASURES of LAURETH-10 CARBOXYLIC ACID:
-Personal precautions, protective equipment and emergency procedures:
Use personal protective equipment.
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Sweep up and shovel.



FIRE FIGHTING MEASURES of LAURETH-10 CARBOXYLIC ACID:
-Extinguishing media:
*Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LAURETH-10 CARBOXYLIC ACID:
-Control parameters:
*Occupational Exposure limit values: no data available
*Biological limit values: no data available
-Appropriate engineering controls:
Wash hands before breaks and at the end of workday.
-Individual protection measures, such as personal protective equipment (PPE):
*Eye/face protection:
Safety glasses.
*Skin protection:
Handle with gloves.



HANDLING and STORAGE of LAURETH-10 CARBOXYLIC ACID:
-Conditions for safe storage, including any incompatibilities:
Store in cool place.
Keep container tightly closed in a dry and well-ventilated place.



STABILITY and REACTIVITY of LAURETH-10 CARBOXYLIC ACID:
-Reactivity: no data available
-Chemical stability:
Stable under recommended storage conditions.



SYNONYMS:
LAURETH-10 CARBOXYLIC ACID
LAURETH-10 CARBOXYLIC ACID [INCI]
PEG-10 LAURYL ETHER CARBOXYLIC ACID
POLYOXYETHYLENE (10) LAURYL ETHER CARBOXYLIC ACID
POLYOXYETHYLENE (9) CARBOXYMETHYL DODECYL ETHER




LAURETH-11 CARBOXYLIC ACID
DESCRIPTION:
LAURETH-11 Carboxylic Acid is a crypto-anionic surfactant - laureth-11 carboxylic acid - (it combines the properties of the anionic and non-ionic surfactants).
LAURETH-11 Carboxylic Acid has good foaming and solubilizing properties with excellent mildness to skin and mucous membranes


CAS Number, 27306-90-7
Chem/IUPAC Name:, Poly(oxy-1,2-ethanediyl)



SYNONYMS OF LAURETH-11 CARBOXYLIC ACID:
Laureth-11 carboxylic acid,AKYPO RLM 100,CK7N38KKFK,CORUM 3611EMPICOL CBJ,PEG-11 LAURYL ETHER CARBOXYLIC ACID,POLYETHYLENE GLYCOL (11) LAURYL ETHER CARBOXYLIC ACID,POLYOXYETHYLENE (11) LAURYL ETHER CARBOXYLIC ACID, alpha.-carboxymethyl-.omega.-dodecyloxy-, (10 mol EO average molar ratio) Laureth-11 Carboxylic Acid, PEG-11 Lauryl Ether Carboxylic Acid, Polyethylene Glycol (11) Lauryl Ether Carboxylic Acid, Polyoxyethylene (11) Lauryl Ether Carboxylic Acid, GLYCOLIC ACID ETHOXYLATE LAURYL ETHER, M N CA. 690; GLYCOLIC ACID ETHOXYLATE LAURYL ETHER, M N CA. 360; GLYCOLIC ACID ETHOXYLATE LAURYL ETHER, M N CA. 460; Glycolic acid ethoxylate lauryl ether average Mn ~360; Glycolic acid ethoxylate lauryl ether average Mn ~690; Glycolic acid ethoxylate lauryl ether average Mn ~460;GLYCOLIC ACID ETHOXYLATE LAURYL ETHER;Laureth-11 carboxylic acid;Glycolic acid ethoxylate lauryl ether; PEG-11 lauryl ether carboxylic acid; POE (11) lauryl ether carboxylic acid


CHEMICAL AND PHYSICAL PROPERTIES OF LAURETH-11 CARBOXYLIC ACID:
Molecular Weight
288.42 g/mol
Computed by PubChem 2.2 (PubChem release 2021.10.14)
XLogP3-AA
5.1
Computed by XLogP3 3.0 (PubChem release 2021.10.14)
Hydrogen Bond Donor Count
1
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Hydrogen Bond Acceptor Count
4
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Rotatable Bond Count
16
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Exact Mass
288.23005950 g/mol
Computed by PubChem 2.2 (PubChem release 2021.10.14)
Monoisotopic Mass
288.23005950 g/mol
Computed by PubChem 2.2 (PubChem release 2021.10.14)
Topological Polar Surface Area
55.8Ų
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Heavy Atom Count
20
Computed by PubChem
Formal Charge
0
Computed by PubChem
Complexity
207
Computed by Cactvs 3.4.8.18 (PubChem release 2021.10.14)
Isotope Atom Count
0
Computed by PubChem
Defined Atom Stereocenter Count
0
Computed by PubChem
Undefined Atom Stereocenter Count
0
Computed by PubChem
Defined Bond Stereocenter Count
0
Computed by PubChem
Undefined Bond Stereocenter Count
0
Computed by PubChem
Covalently-Bonded Unit Count
1
Computed by PubChem
Compound Is Canonicalized
Yes





SAFETY INFORMATION ABOUT LAURETH-11 CARBOXYLIC ACID:
First aid measures:
Description of first aid measures:
General advice:
Consult a physician.
Show this safety data sheet to the doctor in attendance.
Move out of dangerous area:

If inhaled:
If breathed in, move person into fresh air.
If not breathing, give artificial respiration.
Consult a physician.
In case of skin contact:
Take off contaminated clothing and shoes immediately.
Wash off with soap and plenty of water.
Consult a physician.

In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes and consult a physician.
Continue rinsing eyes during transport to hospital.

If swallowed:
Do NOT induce vomiting.
Never give anything by mouth to an unconscious person.
Rinse mouth with water.
Consult a physician.

Firefighting measures:
Extinguishing media:
Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.
Special hazards arising from the substance or mixture
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas

Advice for firefighters:
Wear self-contained breathing apparatus for firefighting if necessary.
Accidental release measures:
Personal precautions, protective equipment and emergency procedures
Use personal protective equipment.

Avoid breathing vapours, mist or gas.
Evacuate personnel to safe areas.

Environmental precautions:
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Methods and materials for containment and cleaning up:
Soak up with inert absorbent material and dispose of as hazardous waste.
Keep in suitable, closed containers for disposal.

Handling and storage:
Precautions for safe handling:
Avoid inhalation of vapour or mist.

Conditions for safe storage, including any incompatibilities:
Keep container tightly closed in a dry and well-ventilated place.
Containers which are opened must be carefully resealed and kept upright to prevent leakage.
Storage class (TRGS 510): 8A: Combustible, corrosive hazardous materials

Exposure controls/personal protection:
Control parameters:
Components with workplace control parameters
Contains no substances with occupational exposure limit values.
Exposure controls:
Appropriate engineering controls:
Handle in accordance with good industrial hygiene and safety practice.
Wash hands before breaks and at the end of workday.

Personal protective equipment:
Eye/face protection:
Tightly fitting safety goggles.
Faceshield (8-inch minimum).
Use equipment for eye protection tested and approved under appropriate government standards such as NIOSH (US) or EN 166(EU).

Skin protection:
Handle with gloves.
Gloves must be inspected prior to use.
Use proper glove
removal technique (without touching glove's outer surface) to avoid skin contact with this product.
Dispose of contaminated gloves after use in accordance with applicable laws and good laboratory practices.
Wash and dry hands.

Full contact:
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
Splash contact
Material: Nitrile rubber
Minimum layer thickness: 0.11 mm
Break through time: 480 min
Material tested:Dermatril (KCL 740 / Aldrich Z677272, Size M)
It should not be construed as offering an approval for any specific use scenario.

Body Protection:
Complete suit protecting against chemicals, The type of protective equipment must be selected according to the concentration and amount of the dangerous substance at the specific workplace.
Respiratory protection:
Where risk assessment shows air-purifying respirators are appropriate use a fullface respirator with multi-purpose combination (US) or type ABEK (EN 14387) respirator cartridges as a backup to engineering controls.

If the respirator is the sole means of protection, use a full-face supplied air respirator.
Use respirators and components tested and approved under appropriate government standards such as NIOSH (US) or CEN (EU).
Control of environmental exposure
Prevent further leakage or spillage if safe to do so.
Do not let product enter drains.
Discharge into the environment must be avoided.

Stability and reactivity:
Chemical stability:
Stable under recommended storage conditions.
Incompatible materials:
Strong oxidizing agents:
Hazardous decomposition products:
Hazardous decomposition products formed under fire conditions.
Carbon oxides, Nitrogen oxides (NOx), Hydrogen chloride gas.

Disposal considerations:
Waste treatment methods:
Product:
Offer surplus and non-recyclable solutions to a licensed disposal company.
Contact a licensed professional waste disposal service to dispose of this material.
Contaminated packaging:
Dispose of as unused product


LAURETH-12
LAURETH-15, peg-15 lauryl ether, polyethylene glycol (15) lauryl ether, polyethylene glycol (15) lauryl ether, polyethylene glycol (15) monolauryl ether, polyoxyethylene (15) lauryl ether, polyoxyethylene (15) monolauryl ether, LAURETH-15, N° CAS : 9002-92-0, Nom INCI : LAURETH-15. Classification : Composé éthoxylé : Ses fonctions (INCI) Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-15
LAURETH-16, LAURETH-16, peg-16 lauryl ether, polyethylene glycol (16) lauryl ether, polyethylene glycol (16) lauryl ether, polyethylene glycol (16) monolauryl ether, polyoxyethylene (16) lauryl ether, polyoxyethylene (16) monolauryl ether, LAURETH-16, N° CAS : 9002-92-0. Nom INCI : LAURETH-16. Classification : Composé éthoxylé. Ses fonctions (INCI) : Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-16
Numéro CAS : 3055-93-4, Noms français :((DODECYLOXY)-2 ETHOXY)-2 ETHANOL, (DODECYLOXY-2 ETHOXY)-2 ETHANOL, Noms anglais : ETHANOL, 2-(2-(DODECYLOXY)ETHOXY)-, LAURYL ALCOHOL MONO(OXYETHYLENE) ETHANOL, laureth-2, synonyme : Laurylalcohol-2-polyglycolether (Nom chimique), Inci : laureth-2, Cas : 68439-50-9, EC : 500-213-3 synonyme : Laurylalcohol-3-polyglycolether (Nom chimique), Inci : laureth-3, Cas : 68439-50-9, EC : 500-213-3 synonyme : Laurylalcohol-4-polyglycolether (Nom chimique), Inci : laureth-4, Cas : 68439-50-9, EC : 500-213-3 ; 2-(2-(Dodecyloxy)ethoxy)ethanol; 2-[2-(dodecyloxy)ethoxy]ethanol; 2-[[]2-(dodecyloxy)ethoxy]ethanol; Bis(oxyethylene) dodecyl ether; Diethylene glycol dodecyl ether; Diethylene glycol monododecyl ether; Diethyleneglycol lauryl ether; Diethyleneglycol monolauryl ether ; Dodecyl diethylene glycol; Ethanol, 2-(2-(dodecyloxy)ethoxy)-; LA 2; LA 2 (alcohol); Laureth-2; Lauryl alcohol mono(oxyethylene) ethanol. : 2-(2-dodecoxyethoxy)ethanol; 2-[2-(dodecyloxy)ethoxy]ethan-1-ol; 2-¢2-(DODECYLOXY)ETHOXY!ETHANOL; Fettalkoholethoxylat C12 2EO
LAURETH-2
LAURETH-2, peg-2 lauryl ether, polyethylene glycol (2) lauryl ether, polyethylene glycol (2) lauryl ether, polyethylene glycol (2) monolauryl ether, polyoxyethylene (2) lauryl ether, polyoxyethylene (2) monolauryl ether, LAURETH-2, Laureth-2 (éthoxylé), N° CAS : 3055-93-4 / 9002-92-0 / 68439-50-9, Nom INCI : LAURETH-2, Nom chimique : 2-[2-(Dodecyloxy)ethoxy]ethanol, N° EINECS/ELINCS : 221-279-7 / 500-002-6 / 500-213-3. Classification : Composé éthoxylé. Agent nettoyant : Aide à garder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-2 BENZOATE
Nom INCI : LAURETH-2 PHOSPHATE Nom chimique : 2-[2-(Dodecyloxy)ethoxy]ethanol phosphate Classification : Composé éthoxylé Ses fonctions (INCI) Agent nettoyant : Aide à garder une surface propre
LAURETH-2 PHOSPHATE
LAURETH-20, peg-20 lauryl ether, polyethylene glycol (20) lauryl ether, polyethylene glycol (20) lauryl ether, polyethylene glycol (20) monolauryl ether, polyoxyethylene (20) lauryl ether, polyoxyethylene (20) monolauryl ether, LAURETH-20, N° CAS : 9002-92-0, Nom INCI : LAURETH-20, Classification : Composé éthoxylé. Ses fonctions (INCI). Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-20
LAURETH-21, peg-21 lauryl ether, polyethylene glycol (21) lauryl ether, polyethylene glycol (21) lauryl ether, polyethylene glycol (21) monolauryl ether, polyoxyethylene (21) lauryl ether, polyoxyethylene (21) monolauryl ether, LAURETH-21. N° CAS : 9002-92-0. Nom INCI : LAURETH-21. Classification : Composé éthoxylé Ses fonctions (INCI). Agent nettoyant : Aide à garder une surface propre.Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-21
LAURETH-23, peg-23 lauryl ether, polyethylene glycol (23) lauryl ether, polyethylene glycol (23) lauryl ether, polyethylene glycol (23) monolauryl ether, polyoxyethylene (23) lauryl ether, polyoxyethylene (23) monolauryl ether, N° CAS : 9002-92-0. Origine(s) : Végétale, Synthétique. Nom INCI : LAURETH-23. Le Laureth-23 est un tensioactif non ionique préparé à partir d'alcool laurylique et de 23 moles d'oxyde d'éthylène. Il est utilisé en cosmétique comme tensioactif et émulsifiant : HLB (16.9). Il permet de créer des émulsions de type huile dans eau.Ses fonctions (INCI). Agent nettoyant : Aide à garder une surface propre Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-23
C12 Alcohol, predominately linear 23 EO; Tricosaethylene glycol mono-N-dodecyl ether; Polyoxyethylene (23) lauryl ether cas no: 9002-92-0
LAURETH-25
LAURETH-25, LAURETH-25, LAURETH-25, peg-25 lauryl ether, polyethylene glycol (25) lauryl ether, polyethylene glycol (25) lauryl ether, polyethylene glycol (25) monolauryl ether, polyoxyethylene (25) lauryl ether, polyoxyethylene (25) monolauryl ether, N° CAS : 9002-92-0, Nom INCI : LAURETH-25. Classification : Composé éthoxylé. Ses fonctions (INCI) : Agent nettoyant : Aide à garder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile) Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-3
LAURETH-30, LAURETH-30, LAURETH-30, peg-30 lauryl ether, polyethylene glycol (30) lauryl ether, polyethylene glycol (30) lauryl ether, polyethylene glycol (30) monolauryl ether, polyoxyethylene (30) lauryl ether, polyoxyethylene (30) monolauryl ether, LAURETH-30, N° CAS : 9002-92-0. Nom INCI : LAURETH-30 Classification : Composé éthoxylé.Ses fonctions (INCI) : Agent nettoyant : Aide à garder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-30
LAURETH-4, peg-4 lauryl ether, polyethylene glycol (4) lauryl ether, polyethylene glycol (4) lauryl ether, polyethylene glycol (4) monolauryl ether, polyoxyethylene (4) lauryl ether, polyoxyethylene (4) monolauryl ether, LAURETH-4, N° CAS : 5274-68-0 / 9002-92-0 / 68439-50-9, Nom INCI : LAURETH-4, N° EINECS/ELINCS : 226-097-1 / 500-002-6 / 500-213-3, Classification : Composé éthoxylé,Ses fonctions (INCI). Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-4
Synonyms: 8/5000 Emulsifier earth-sized - 3;C12-14 alcohol polyether;Penetrant JFC;AEO-3、4、5、7、9、15、20;Alcohols, C12-14, ethoxylated;FATTYALCOHOL(C12-C14)POLYGLYCOL(3OEO)ETHER;POLYALKOXYLATEDALIPHATICALCOHOL;Alcohol-(C12-C14), ethoxylated CAS: 68439-50-9
LAURETH-5
LAURETH-50, peg-50 lauryl ether, polyethylene glycol (50) lauryl ether, polyethylene glycol (50) lauryl ether, polyethylene glycol (50) monolauryl ether, polyoxyethylene (50) lauryl ether, polyoxyethylene (50) monolauryl ether, LAURETH-50, Classification : Composé éthoxylé. Ses fonctions (INCI). Agent nettoyant : Aide à garder une surface propre Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-50
LAURETH-6, N° CAS : 3055-96-7 / 68439-50-9, Nom INCI : LAURETH-6, peg-6 lauryl ether, polyethylene glycol (6) lauryl ether, polyethylene glycol (6) lauryl ether, polyethylene glycol (6) monolauryl ether, polyoxyethylene (6) lauryl ether, polyoxyethylene (6) monolauryl ether. Nom chimique : 3,6,9,12,15,18-Hexaoxatriacontan-1-ol, N° EINECS/ELINCS : 221-282-3 / 500-213-3, Classification : Composé éthoxylé. Ses fonctions (INCI). Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-6
LAURETH-7, N° CAS : 3055-96-7 / 68439-50-9, Nom INCI : LAURETH-7, peg-7 lauryl ether, polyethylene glycol (7) lauryl ether, polyethylene glycol (7) lauryl ether, polyethylene glycol (7) monolauryl ether, polyoxyethylene (7) lauryl ether, polyoxyethylene (7) monolauryl ether, LAURETH-7, N° CAS : 3055-97-8 / 68439-50-9 / 9002-92-0. Nom INCI : LAURETH-7. Nom chimique : 3,6,9,12,15,18,21-Heptaoxatritriacontanol. N° EINECS/ELINCS : 221-283-9 / 500-213-3 / 500-002-6. Classification : Composé éthoxylé. Ses fonctions (INCI) : Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation. Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL) ; ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE ;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-6 CARBOXYLIC ACID
Laureth-6 Carboxylic Acid is an organic acid.


CAS Number: 27306-90-7
Chem/IUPAC Name: Poly(oxy-1,2-ethanediyl),.alpha.-carboxymethyl-.omega.-dodecyloxy-, (5 mol EO average molar ratio)
Chemical family: Polyoxyethylene alkylether carboxylic acid
INCI Name: Laureth-6 Carboxylic Acid
Molecular Formula: C24H48O8


Laureth-6 Carboxylic Acid is an essential additive for long-lifetime metalworking fluids.
Laureth-6 Carboxylic Acid is characterized by their outstanding hard water and electrolyte tolerance compared to other emulsifiers used in metalworking.
Dive into the world of Laureth-6 Carboxylic Acid , a powerful anionic surfactant renowned for its superior detergency and foaming abilities.


This versatile chemical compound, Laureth-6 Carboxylic Acid, is utilized in a range of applications, from personal care products to industrial cleaners, and offers excellent emulsifying and wetting properties.
It's ability to boost foam production and effectively remove dirt and oils makes Laureth-6 Carboxylic Acid a valuable addition to your formulations.


Laureth-6 Carboxylic Acid is a wide range of secondary surfactants with excellent tolerance against hard water.
Laureth-6 Carboxylic Acid is a crypto-anionic surfactant - laureth-6 carboxylic acid - (Laureth-6 Carboxylic Acidcombines the properties of the anionic and non-ionic surfactants).


Laureth-6 Carboxylic Acid has good foaming and solubilizing properties being very mild for the skin.
Laureth-6 Carboxylic Acid is a mild co-surfactant and functions as an emulsifier and solubilizer.
Laureth-6 Carboxylic Acid is extremely mild and compatible with other surfactants as well as ideal as co-surfactants and coupling agents.
Laureth-6 Carboxylic Acid has all the qualities that show outstanding pH stability and high tolerance against electrolytes and builders.


"Laureth-" refers to a PEG-(polyethylene glycol-) ether of lauryl alcohol.
The number behind "laureth-" refers to the average number of molecular units -CH2-CH2-O-.
"Carboxylic acid" refers generally to a carboxylic or carbonic acid.



USES and APPLICATIONS of LAURETH-6 CARBOXYLIC ACID:
Laureth-6 Carboxylic Acid is used high foaming mild co-surfactant for cosmetic applications.
Laureth-6 Carboxylic Acid is used Paper industry for waste paper deinking and softening agent formula.
Laureth-6 Carboxylic Acid is used as a degreaser component in the leather industry.


Laureth-6 Carboxylic Acid is used as foaming agent for foam fire extinguishing.
Laureth-6 Carboxylic Acid is depending on the carbon chain length and the ethoxylation degree the products show characteristic application properties.
Laureth-6 Carboxylic Acid brings excellent lime soap dispersing properties and adds some anti-corrosion benefits.


Laureth-6 Carboxylic Acid has all the qualities that show outstanding pH stability and high tolerance against electrolytes and builders.
Laureth-6 Carboxylic Acid is an extremely mild surfactant with good emulsifying properties and insensitive to water hardness, it substantially improves the skin’s tolerance of cleansers.


Laureth-6 Carboxylic Acid is used surfactant for mild personal care products (shampoos, shower gels, foam baths, other low-irritation formulations); surfactant for industrial applications (agrochemicals, textile treatment); detergent for carpet cleaners especially aerosols.
Applications of Laureth-6 Carboxylic Acid: Beauty & Care, Hair Care, Oral Care, Skin Care, Home Care, Auto Care, Carpet & Upholstery, Dish Care, and Laundry & Fabric Care.


Laureth-6 Carboxylic Acid is used in Hard water stable.
Laureth-6 Carboxylic Acid is used applicable in hypochlorite solutions.
Laureth-6 Carboxylic Acid is used emulsifying and solubilizing properties.


Other Home Care Applications of Laureth-6 Carboxylic Acid
Surface Care Institutional & Industrial Care, Commercial Laundry, Food Facility Cleaning & Sanitization, Industrial Cleaning, and Institutional & Catering.
Laureth-6 Carboxylic Acid is mainly used in various shampoos and personal care liquid products, especially for the preparation of baby shampoo, also used as detergents and industrial emulsifiers, dispersing agents, foaming agents and wetting agent.


Laureth-6 Carboxylic Acid combines the properties of the anionic and non-ionic surfactants.
Laureth-6 Carboxylic Acid has good foaming and solubilizing properties with excellent mildness to skin and mucous membranes
Laureth-6 Carboxylic Acid is used as emulsifier or coemulsifier for paste cosmetics.


Laureth-6 Carboxylic Acid is used Other Institutional & Industrial Care, Vehicle & Machinery, Personal Hygiene, Hand Hygiene, Processing & Packaging, and Food & Beverage Manufacturing.
Hair Care Applications of Laureth-6 Carboxylic Acid: Hair Color, Home Care Applications, Household Cleaners, I&I Cleaning Applications, Automotive Cleaners, and Industrial Cleaners.


Laureth-6 Carboxylic Acid uses and applications include: Surfactant, emulsifier, dispersant, superfatting agent, foam stabilizer for emulsions, detergents, shampoos, bubble baths.
Laureth-6 Carboxylic Acid is used with overall physico-chemical stability, that improves lathering, enhances quat's and hair dyes efficiency providing combined benefits of nonionic and anionic surfactants.


Laureth-6 Carboxylic Acid is used Mild shampoo, body wash, facial cleanser, hand sanitizer and other personal cleaning and protection products.
Laureth-6 Carboxylic Acid is used mixed into the soap block mild, calcium soap dispersion, foam performance and bath feeling.
Laureth-6 Carboxylic Acid is used for household detergents, industrial cleaning agents and phosphorus free detergents.


Laureth-6 Carboxylic Acid is used in textile industry refining, mercerizing, bleaching, soft, dyeing and other processes.
Laureth-6 Carboxylic Acid is used as an emulsifier and viscosity reducer resistant to high concentration electrolyte, it is used in tertiary oil recovery and oil transportation to provide crude oil recovery.


Laureth-6 Carboxylic Acid is particularly suitable for high-quality formulations, baby shampoos, and products designed for sensitive skin.
Laureth-6 Carboxylic Acid can be used in conveyor belt lubricants.



FUNCTIONS OF LAURETH-6 CARBOXYLIC ACID:
*Surfactant,
*Surfactant (Anionic),
*Solubilizer,
*Foaming Agent,
*Foam Booster,
*Cosurfactant,
*Cleansing Agent



INDUSTRIES OF LAURETH-6 CARBOXYLIC ACID:
*Oral Care
*Trends
*Hair Care
*Skin Care



PROPERTIES OF LAURETH-6 CARBOXYLIC ACID:
*Co-Surfactant
*Emulsifier
*Solubilizer
*Mild



FUNCTIONS OF LAURETH-6 CARBOXYLIC ACID IN COSMETIC PRODUCTS:
*CLEANSING
Cleans skin, hair or teeth
*SURFACTANT - CLEANSING
Surface-active agent to clean skin, hair and / or teeth



WHAT DOES LAURETH-6 CARBOXYLIC ACID DO IN A FORMULATION?
*Cleansing
*Surfactant



FUNCTIONS OF LAURETH-6 CARBOXYLIC ACID:
*Cleansing :
Laureth-6 Carboxylic Acid helps to keep a clean surface
*Surfactant :
Laureth-6 Carboxylic Acid reduces the surface tension of cosmetics and contributes to the even distribution of the product when it is used



PERFORMANCE OF LAURETH-6 CARBOXYLIC ACID:
1, Laureth-6 Carboxylic Acid has good decontamination, emulsification, dispersibility and dispersion of calcium soap.
2, Laureth-6 Carboxylic Acid has good foaming power and foam stability.
3, Laureth-6 Carboxylic Acid has resistance to acid and alkali, hard water and oxidants, reducing agents.
4, Laureth-6 Carboxylic Acid has good compatibility, no interference with the performance of the cation.
5, Laureth-6 Carboxylic Acid has solubilization performance, suitable for preparation of functional transparent products.
6. Laureth-6 Carboxylic Acid is easy to biodegrade.



CHARACTERISTICS OF LAURETH-6 CARBOXYLIC ACID:
1. Good foaming performance and detergency;
2. Strong resistance to hard water, high solubility in water;
3. Mildness, good compatibility with other surfactants;
4. Be stable under acid, alkali, high temperature, low irritation to the skin and clothes



FAMILIES OF LAURETH-6 CARBOXYLIC ACID:
*Cleaning Aids
*Emulsifiers & Demulsifiers



FUNCTIONAL ADDITIVES OF LAURETH-6 CARBOXYLIC ACID:
*Foam Control Agents,
*Other Functional Additives,
*Performance Additives



FUNCTIONALS OF LAURETH-6 CARBOXYLIC ACID:
*Emulsifiers, Solubilizers & Dispersants
*Soaps & Surfactants
*Anionic Surfactants,
*Blends & Other Surfactants
*Surfactants & Cleansers
*Anionic Surfactants



CLEANING INGREDIENTS FUNCTIONS OF LAURETH-6 CARBOXYLIC ACID:
*Cleansing Agent,
*Co Emulsifier,
*Cosurfactant,
*Emulsifier,
*Foam Booster,
*Foaming Agent,
*Solubilizer,
*Surfactant,
*Surfactant (Anionic)



FEATURES AND BENEFITS OF LAURETH-6 CARBOXYLIC ACID:
*Mild



MARKETS OF LAURETH-6 CARBOXYLIC ACID:
*Food & Nutrition,
*HI&I Care,
*Personal Care



PHYSICAL and CHEMICAL PROPERTIES of LAURETH-6 CARBOXYLIC ACID:
Boiling point: 552.2±45.0 °C(Predicted)
Density: 1.015±0.06 g/cm3(Predicted)
pka: 3.39±0.10(Predicted)
FDA UNII: 1LS4J5883P
Molecular Weight: 464.6g/mol
Molecular Formula: C24H48O8
Compound Is Canonicalized: True
XLogP3-AA: 4.5
Exact Mass: 464.33491849
Monoisotopic Mass: 464.33491849
Complexity: 368
Rotatable Bond Count: 28
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 8
Topological Polar Surface Area: 92.7
Heavy Atom Count: 32
Defined Atom Stereocenter Count: 0
Undefined Atom Stereocenter Count: 0
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Isotope Atom Count: 0
Covalently-Bonded Unit Count: 1



FIRST AID MEASURES of LAURETH-6 CARBOXYLIC ACID:
-General advice:
Consult a physician.
-If inhaled:
If breathed in, move person into fresh air.
Consult a physician.
-In case of skin contact:
Wash off with soap and plenty of water.
Consult a physician.
-In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes.
Consult a physician.
-If swallowed:
Rinse mouth with water.
Consult a physician.



ACCIDENTAL RELEASE MEASURES of LAURETH-6 CARBOXYLIC ACID:
-Personal precautions, protective equipment and emergency procedures:
Use personal protective equipment.
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Sweep up and shovel.



FIRE FIGHTING MEASURES of LAURETH-6 CARBOXYLIC ACID:
-Extinguishing media:
*Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LAURETH-6 CARBOXYLIC ACID:
-Control parameters:
*Occupational Exposure limit values: no data available
*Biological limit values: no data available
-Appropriate engineering controls:
Wash hands before breaks and at the end of workday.
-Individual protection measures, such as personal protective equipment (PPE):
*Eye/face protection:
Safety glasses.
*Skin protection:
Handle with gloves.



HANDLING and STORAGE of LAURETH-6 CARBOXYLIC ACID:
-Conditions for safe storage, including any incompatibilities:
Store in cool place.
Keep container tightly closed in a dry and well-ventilated place.



STABILITY and REACTIVITY of LAURETH-6 CARBOXYLIC ACID:
-Reactivity: no data available
-Chemical stability:
Stable under recommended storage conditions.



SYNONYMS:
3,6,9,12,15,18-Hexaoxatriacontanoic acid
AKYPO RLM 45 CA
LAURETH-6 CARBOXYLIC ACID
LAURETH-6 CARBOXYLIC ACID [INCI]
PEG-6 LAURYL ETHER CARBOXYLIC ACID
POLYOXYETHYLENE (6) LAURYL ETHER CARBOXYLIC ACID
Laureth-6 carboxylic acid
PEG-6 lauryl ether carboxylic acid
PEG 300 lauryl ether carboxylic acid
POE (6) lauryl ether carboxylic acid



LAURETH-7
LAURETH-7 CITRATE, N° CAS : 161756-30-5, Nom INCI : LAURETH-7 CITRATE. Classification : Composé éthoxylé. Ses fonctions (INCI). Agent nettoyant : Aide à garder une surface propre. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation
LAURETH-7 CARBOXYLIC ACID
LAURETH-7 CARBOXYLIC ACID = 2-(2-DODECOXYETHOXY)ACETIC ACID = LAURYL POLYGLYCOL ETHER CARBOXYLIC ACID


CAS Number: 27306-90-7 / 33939-64-9
EC Number: 608-079-9
Molecular Formula: C16H32O4


Laureth-7 carboxylic acid is a sodium salt of the carboxylic acid derived from laureth-7.
Laureth-7 carboxylic acid is a crypto-anionic surfactant.
Laureth-7 carboxylic acid combines the properties of the anionic and non-ionic surfactants.
Laureth-7 carboxylic acid is a non-ionic surfactant based on C12-C16 lauryl alcohol.


Laureth-7 carboxylic acid belongs to the group of fatty alcohol ethoxylates with the INCI name: C12-16 Laureth-7.
Laureth-7 carboxylic acid is well soluble in water.
The HLB value for Laureth-7 carboxylic acid is approximate 13, and the solidification point is 10°C.
Laureth-7 carboxylic acid is easily biodegradable in the natural environment.


Laureth-7 carboxylic acid shows high chemical activity in acidic and neutral baths and diluted alkalies.
Laureth-7 carboxylic acid is a non-ionic surfactant from the group of fatty alcohol ethoxylates, very good solubility in water.
Laureth-7 carboxylic acid is biodegradable product.
Laureth-7 carboxylic acid has been identified in human blood.


Technically Laureth-7 carboxylic acid is part of the human exposome.
Laureth-7 carboxylic acid is also excellent in mixtures with anionic and cationic surfactants.
Carboxylic acids are compounds containing a carboxylic acid group with the formula -C(=O)OH.
Based on a literature review very few articles have been published on Laureth-7 carboxylic acid.


Laureth-7 carboxylic acid combines the properties of the anionic and non-ionic surfactants.
Laureth-7 carboxylic acid is an extremely mild surfactant with good emulsifying properties and insensitive to water hardness, Laureth-7 carboxylic acid substantially improves the skin’s tolerance of cleansers.
Laureth-7 carboxylic acid is classified as cleansing, foaming and surfactant.


In formulations containing alkyl sulphates and alkyl aryl sulfonates, Laureth-7 carboxylic acid shows a synergistic cleaning effect.
Laureth-7 carboxylic acid belongs to the class of organic compounds known as carboxylic acids.
Laureth-7 carboxylic acid has good foaming and solubilizing properties with excellent mildness to skin and mucous membranes.
Laureth-7 carboxylic acid comes in a highly concentrated form.


The content of the active ingredient in the product exceeds 99%.
Laureth-7 carboxylic acid has the additional advantage of being highly compatible with non-ionic excipients.
Laureth-7 carboxylic acid is an AKYPO RLM product.
The Akypo products offer a wide range of secondary surfactants with excellent tolerance against hard water.


Depending on the carbon chain length and the ethoxylation degree the products show characteristic application properties.
Akypo LF grades, with a chain length from C4 to C8, are low foaming surfactants with high dispersing and hydrotropic abilities.
Akypo RLM products have a C12-C14 alkyl chain and their degree of ethoxylation ranges from 2.5 to 10 EO.


They offer good foaming at different pHs.
Similar to the Akypo soft grades they are mild co-surfactants and function as emulsifiers and solubilizers.
Finally the Akypo ro products bring excellent lime soap dispersing properties and add some anti-corrosion benefits.
They can be used in conveyor belt lubricants.



USES and APPLICATIONS of LAURETH-7 CARBOXYLIC ACID:
Laureth-7 carboxylic acid is Mild rapid foam-booster with improved foam behaviour for Personal Care products and for all kind of cleaners including Car Care, Dishwashing, Household, Industrial and Instituional.
Laureth-7 carboxylic acid is an intermediate for resins, plasticizers, and rubber chemicals.
Laureth-7 carboxylic acid is also an ingredient that removes excess dyes from the bath in the final stage of textiles.


It's very good fabric wetting properties (especially of cotton), Laureth-7 carboxylic acid is suitable as an ingredient in bleaching compositions for raw knitwear and cotton fabrics.
Laureth-7 carboxylic acid is used Sensitive skin products, Toothpaste, Mouthwash, Household cleaners, Laundry care, LDLD liquid detergents, and Surface care.


Laureth-7 carboxylic acid is particularly suitable for high-quality formulations, baby shampoos, and products designed for sensitive skin.
Laureth-7 carboxylic acid provides cleansing function as well as emulsifying in a hair and skin care systems.
Laureth-7 carboxylic acid is used Face and body care cosmetics (scrubs, moisturisers, anti-acne creams, anti-wrinkle creams, eye creams, hand creams, body lotions, sunscreen creams), Face and body cleansers (face wash gels, body wash and gels, liquid soaps, bubble baths).


Laureth-7 carboxylic acid is also used as a lubricant in the textile industry, as a humectant and softening agent for hides, as an alkalizing agent and surfactant in pharmaceuticals, as an absorbent for acid gases, and in organic syntheses.
Laureth-7 carboxylic acid is perfectly suited for the textile and clothing industry.
The uses of Laureth-7 carboxylic acid are in rinse-off products, and are in hair coloring formulations.


Laureth-7 carboxylic acid is used in fibre pretreatment processes as a component of mixtures dedicated to removing greasy oil stains (mineral oils) from fabrics and knitwear.
Laureth-7 carboxylic acid is highly compatible with other non-ionic surfactants, as well as anionic and cationic surfactants.
Laureth-7 carboxylic acid is suitable for use in environments of reducing and oxidising agents and in hard and cold water.


Laureth-7 carboxylic acid is used Bathroom cleaners, Industrial cleaners, Institutional cleaners, Hotel cleaners, Restaurant cleaners, Catering facility cleaners, Food facility cleaners, Beverage facility cleaners, CIP cleaners, OPC cleaners, and Surfactant
Laureth-7 carboxylic acid is used Efficient cleaning, High foaming mild co-surfactant for cosmetic applications, Applicable in hypochlorite solution, and Emulsifying and solubilizing properties


Laureth-7 carboxylic acid is used in the production of cosmetic products such as skincare and cleansing cosmetics and hair care cosmetics, and primarily in hair coloring products.
Laureth-7 carboxylic acid is used Foaming co-surfactant, enhances quat's and dyes efficiency; with solubilizing properties and very mild for the skin, and Foaming surfactant with excellent physico-chemical stability.


Laureth-7 carboxylic acid has a wide range of functions in formulations – wetting agent, washing agent, emulsifying and dispersing agent.
Laureth-7 carboxylic acid is used Hair color protection, Skin cleansing, Shower gel, Shower cream, Shower oil, Liquid hand soap, Foaming bath products, Baby and child skin cleansing, Sensitive skin products, Toothpaste, Skin Care, Creams and lotions, Face care, Body care, Hand care, Face cleanser, Eye makeup remover, Hair care, Shampoo, Hair colorants, and Hair color protection


Laureth-7 carboxylic acid is effective in acidic and neutral environments and in dilute alkalies.
Laureth-7 carboxylic acid functions in cosmetics as pH adjusters.
Laureth-7 carboxylic acid acts as both anionic surfactant and co-surfactant.
Laureth-7 carboxylic acid functions as a hair fixative.


Laureth carboxylic acids function as surfactants.
Laureth-7 carboxylic acid is used Skin cleansing, Shower gel, Shower cream, Shower oil, Liquid hand soap, Foaming bath products, Baby and child skin cleansing, Solubilizer, Skin care, Face cleanser, Eye makeup remover, Hair care, Shampoo, and Hair colorants.
Laureth-7 carboxylic acid is used in non-coloring hair preparations and rinse-off formulations, and in leave-on formulations.


Owing to Laureth-7 carboxylic acid's wetting, emulsifying and dispersing properties as well as very good detergency properties, Laureth-7 carboxylic acid is used as a basic surfactant in the production of detergents (powders and liquids), household and professional cleaning products and hand cleaning formulations.
Laureth-7 carboxylic acid is used in the manufacture of emulsifiers and dispersing agents for textile specialties, agricultural chemicals, waxes, mineral and vegetable oils, paraffin, polishes, cutting oils, petroleum demulsifiers, and cement additives.


Laureth-7 carboxylic acid is also a raw material often used in the manufacture of colour cosmetics, sunscreen products, shaving products and aftershave cosmetics.
Laureth-7 carboxylic acid is used Formulations for removing oil stains from knitted and woven fabrics, Additive to bleach baths in the textile industry, and Additive to washing baths after dyeing fabrics and knitwear.
Laureth-7 carboxylic acid used Colour cosmetics (make-up primers, fluids, eye shadows, concealers, bronzers), Shaving and aftershave cosmetics, and Household detergents (liquid and powdered detergents, surface cleaning agents, wash-up liquids, handwash products).


-Hair care products uses of Laureth-7 carboxylic acid: hair washing, care and styling products (shampoos, conditioners, serum, gels, styling foams)
-Cosmetic Uses of Laureth-7 carboxylic acid:
*cleansing agents
*surfactants



ALTERNATIVE PARENTS of LAURETH-7 CARBOXYLIC ACID:
*Monocarboxylic acids and derivatives
*Dialkyl ethers
*Primary alcohols
*Organic oxides
*Hydrocarbon derivatives
*Carbonyl compounds



SUBSTITUENTS of LAURETH-7 CARBOXYLIC ACID:
*Monocarboxylic acid or derivatives
*Ether
*Dialkyl ether
*Carboxylic acid
*Organic oxygen compound
*Organic oxide
*Hydrocarbon derivative
*Primary alcohol
*Organooxygen compound
*Carbonyl group
*Alcohol
*Aliphatic acyclic compound



BENEFITS of LAURETH-7 CARBOXYLIC ACID:
*Personal Care
*Hair Cleansing
*Multifunctional
*Nature-derived
*Preservative-free
*Anionic surfactant
*Cleansing agent
*Foaming agent
*Emulsifier
*Stabilizer
*Disperser
*Ultra mild
*Lamellar structure
*Hydrotropic
*Hard water stable
*Organic acid
*Acid stable
*Alkaline stable
*Electrolyte stable
*Oxidizing agent stable
*Improves color uptake
*Great hair color retention
*Environmental label free
*Vegetable origin
*Readily biodegradable
*A broad spectrum of applications
*Excellent emulsifying, dispersing, wetting, washing and cleaning properties
*High resistance to acidic environments and diluted alkalis,
*High efficiency in hard water
*Very good compatibility with non-ionic, anionic and cationic surfactants
*High concentration of the active ingredient – 99% biodegradable product.



FUNCTIONS of LAURETH-7 CARBOXYLIC ACID:
*Cleansing :
Helps to keep a clean surface
*Emulsifying :
Promotes the formation of intimate mixtures between immiscible liquids by modifying the interfacial tension (water and oil).
*Foaming :
Capturing small air bubbles or other gases in a small volume of liquid by changing the surface tension of the liquid.
*Surfactant :
Reduces the surface tension of cosmetics and contributes to the even distribution of the product when Laureth-7 carboxylic acid is used.
*Dispersant
*Stabilizer



PRODUCT FAMILIES of LAURETH-7 CARBOXYLIC ACID:
-Cleaning Ingredients — Cleaning Aids:
*Emulsifiers & Demulsifiers
-Cleaning Ingredients — Functional Additives:
*Foam Control Agents
*Other Functional Additives
-Cosmetic Ingredients — Functionals:
*Emulsifiers
*Solubilizers & Dispersants
*Other Functional Additives
-Cleaning Ingredients — Soaps & Surfactants:
*Anionic Surfactants
-Cosmetic Ingredients — Surfactants & Cleansers:
*Anionic Surfactants



PROPERTIES of LAURETH-7 CARBOXYLIC ACID:
*Chemical stability
*Solubilizer & Emulsifier
*Foam booster
*Foaming
*Surfactant (Anionic)
*Cosurfactant
*Cleansing Agent
*Emulsifier



PHYSICAL and CHEMICAL PROPERTIES of LAURETH-7 CARBOXYLIC ACID:
Molecular Weight: 288.42
XLogP3-AA: 5.1
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 4
Rotatable Bond Count: 16
Exact Mass: 288.23005950
Monoisotopic Mass: 288.23005950
Topological Polar Surface Area: 55.8 Ų
Heavy Atom Count: 20
Formal Charge: 0
Complexity: 207
Isotope Atom Count: 0

Defined Atom Stereocenter Count: 0
Undefined Atom Stereocenter Count: 0
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes
Average Mass: 288.428 g/mol
Monoisotopic Mass: 288.23006 g/mol
XLogP3-AA: 5.1
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 4
Rotatable Bond Count: 16

Exact Mass: 288.23005950
Monoisotopic Mass: 288.23005950
Topological Polar Surface Area: 55.8 Ų
Heavy Atom Count: 20
Formal Charge: 0
Complexity: 207
Isotope Atom Count: 0
Defined Atom Stereocenter Count: 0
Undefined Atom Stereocenter Count: 0
Defined Bond Stereocenter Count: 0
Undefined Bond Stereocenter Count: 0
Covalently-Bonded Unit Count: 1
Compound Is Canonicalized: Yes
Physical state: no data available

Colour: no data available
Odour: no data available
Melting point/ freezing point: no data available
Boiling point or initial boiling point and boiling range: 410.4oC at 760mmHg
Flammability: no data available
Lower and upper explosion limit / flammability limit: no data available
Flash point: 138.1oC
Auto-ignition temperature: no data available
Decomposition temperature: no data available
pH: no data available
Kinematic viscosity: no data available
Solubility: no data available
Partition coefficient n-octanol/water (log value): no data available
Vapour pressure: 6.94E-08mmHg at 25°C
Density and/or relative density: 0.961g/cm3
Relative vapour density: no data available
Particle characteristics: no data available



FIRST AID MEASURES of LAURETH-7 CARBOXYLIC ACID:
-General advice:
Consult a physician.
-If inhaled:
If breathed in, move person into fresh air.
Consult a physician.
-In case of skin contact:
Wash off with soap and plenty of water.
Consult a physician.
-In case of eye contact:
Rinse thoroughly with plenty of water for at least 15 minutes.
Consult a physician.
-If swallowed:
Rinse mouth with water.
Consult a physician.



ACCIDENTAL RELEASE MEASURES of LAURETH-7 CARBOXYLIC ACID:
-Personal precautions, protective equipment and emergency procedures:
Use personal protective equipment.
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Sweep up and shovel.



FIRE FIGHTING MEASURES of LAURETH-7 CARBOXYLIC ACID:
-Extinguishing media:
*Suitable extinguishing media:
Use water spray, alcohol-resistant foam, dry chemical or carbon dioxide.



EXPOSURE CONTROLS/PERSONAL PROTECTION of LAURETH-7 CARBOXYLIC ACID:
-Control parameters:
*Occupational Exposure limit values: no data available
*Biological limit values: no data available
-Appropriate engineering controls:
Wash hands before breaks and at the end of workday.
-Individual protection measures, such as personal protective equipment (PPE):
*Eye/face protection:
Safety glasses.
*Skin protection:
Handle with gloves.



HANDLING and STORAGE of LAURETH-7 CARBOXYLIC ACID:
-Conditions for safe storage, including any incompatibilities:
Store in cool place.
Keep container tightly closed in a dry and well-ventilated place.



STABILITY and REACTIVITY of LAURETH-7 CARBOXYLIC ACID:
-Reactivity: no data available
-Chemical stability:
Stable under recommended storage conditions.



SYNONYMS:
Laureth-7 carboxylic acid
2-(2-dodecoxyethoxy)acetic acid
33939-64-9
27306-90-7
Sodium laureth-6 carboxylate
Sodium laureth-13 carboxylate
3,6-dioxaoctadecanoic acid
SCHEMBL7649590
DTXSID70181754
Poly(oxy-1,2-ethanediyl), .alpha.-(carboxymethyl)-.omega.-(dodecyloxy)-, sodium salt
2-(2-dodecoxyethoxy)acetic acid
Sodium laureth-6 carboxylate
Sodium laureth-13 carboxylate
3,6-dioxaoctadecanoic acid
[2-(Dodecyloxy)ethoxy]acetic acid
2-(2-dodecoxyethoxy)acetic acid (peg-7)
peg-10 lauryl ether carboxylic acid
poly(oxy-1,2-ethanediyl), .alpha.-carboxymethyl-.omega.-dodecyloxy-, (7 mol EO average molar ratio)
polyethylene glycol (7) lauryl ether carboxylic acid
polyoxyethylene (7) lauryl ether carboxylic acid
3,6,9,12,15-pentaoxaheptacosanoic acid
AEC4-Na
sodium 3,6,9,12,15-heptacosanoate
3,6,9,12,15-pentaoxaheptacosanoic acid
AEC4-Na
sodium 3,6,9,12,15-heptacosanoate



LAURETH-7 CITRATE
Poly(oxy-1,2-ethanediyl), .alpha.-hydro-.omega.-dodecyloxy-, dihydrogen citrate cas no: 161756-30-5
LAURETH-8
LAURETH-9, peg-9 lauryl ether, polyethylene glycol (9) lauryl ether, polyethylene glycol (9) lauryl ether, polyethylene glycol (9) monolauryl ether, polyoxyethylene (9) lauryl ether, polyoxyethylene (9) monolauryl ether, LAURETH-9, N° CAS : 3055-99-0 / 9002-92-0 / 68439-50-9, Nom INCI : LAURETH-9. Nom chimique : 3,6,9,12,15,18,21,24,27-Nonaoxanonatriacontan-1-ol. N° EINECS/ELINCS : 221-284-4 / 500-002-6 / 500-213-3. Classification : Composé éthoxylé. Ses fonctions (INCI) Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Noms français : ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXY-1,2-ETHANEDIYL); ALPHA-DODECYL-OMEGA-HYDROXYPOLY(OXYETHYLENE); DODECYL POLY(OXYETHYLENE) ETHER; ETHER DE MONODODECYL POLY(OXY-1,2 ETHANE); POLY(ETHYLENE OXIDE) DODECYL ETHER; POLY(OXY-1,2-ETHANEDIYL), ALPHA-DODECYL-OMEGA-HYDROXY-; POLY(OXYETHYLENE) DODECYL ETHER; POLY(OXYETHYLENE) MONODODECYL ETHER; POLYETHYLENE GLYCOL DODECYL ETHER; POLYETHYLENE GLYCOL MONODODECYL ETHER; Éther de lauryl poly(oxyéthylène). Noms anglais : ALPHA-DODECYL-OMEGA-HYDROXY-POLYOXYETHYLENE; DODECYL ALCOHOL, ETHOXYLATED; DODECYL POLY(OXYETHYLENE)ETHER; Ethoxylated lauryl alcohol;HYDROXYPOLYETHOXYDODECANE;LAURYL POLY(OXYETHYLENE) ETHER; LAURYL POLYETHYLENE GLYCOL ETHER; OXYETHYLENATED DODECYL ALCOHOL; Poly(oxyethylene) lauryl ether;POLY(OXYETHYLENE) MONOLAURYL ETHER;POLYETHOXYLATED DODECANOL; POLYETHYLENE GLYCOL LAURYL ALCOHOL ETHER; POLYETHYLENE GLYCOL LAURYL ETHER;POLYOXYETHYLENE DODECYL ALCOHOL ETHER; POLYOXYETHYLENE LAURIC ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL; POLYOXYETHYLENE LAURYL ALCOHOL ETHER;POLYOXYETHYLENE LAURYL ETHER. Utilisation et sources d'émission: Agent dispersant
LAURETH-9
LAURIC ACID; n-Dodecanoic acid; Dodecylic acid; Dodecoic acid; Laurostearic acid; Vulvic acid; 1-Undecanecarboxylic acid; Duodecylic acid; cas no: 143-07-7