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ISOPROPYL PALMITATE
IPP; Isopal; Hexadecanoic acid, 1-methylethyl ester; Palmitic acid, Isopropyl ester; Deltyl; Hexadecanoic acid, Isopropyl ester; Isopal; Isopropyl hexadecanoate; 1-methylethyl hexandecanoate; cas no: 142-91-6
ISOPROPYL PALMITATE (IPP)
DESCRIPTION:
An ester derived from isopropyl alcohol and palmitic acid, Isopropyl Palmitate (IPP) is used in many industrial processes as an emollient, thickening agent, moisturizer and anti-static agent.
Acme-Hardesty manufactures a vegetable-based Isopropyl Palmitate (IPP) containing a minimum 90 percent C16 esters.
A high-quality product suitable for the most demanding applications, our isopropyl palmitate is the choice of some of today’s leading pharma, personal care and food and beverage manufacturers.


CAS#: 142-91-6
INCI NAME: Isopropyl Palmitate
CHEMICAL NAME: Hexadecanoic Acid, Isopropyl Ester


SYNONYMS OF ISOPROPYL PALMITATE (IPP):
Lexol® 3975,Lexol® IPP MB,Lexol® IPP-NF MB,PALMESTER 1517 Isopropyl Palmitate,PARYOL IPP,AE Ester IPP,Polymol® IPP,Dermol IPP,Wickenol 111,BASF Isopropyl Palmitate,BergaCare EM,16,BergaCare EM-16 /MB,MIRITOL™ IP,CremerCOOR® IPP,Isopropyl Palmitate 98%,Versagel® MP 1600,Versagel® MP 750,Hostacerin® SAF,MASSOCARE IPP,Crodamol™ IPP,DomusCare® IPP,ERCAREL IPP V,TEGOSOFT® P,QUERCEVITA®,HallStar® IPP,Jeechem IPP NF,Jeelux® DMIPP,Isopropyl Palmitate,IPP,Propal™ NF,MelinOil™,SWT-7™ L,Isopropyl Palmitate (IPP),MIPEARL IPP,Natura-tec Ultrafeel IPP,Nikkol IPP,Radia® 7732,Protachem™ IPP,Rita IPP NF,Ritalan C,Regrease IPP,COVALIP® 22,DUB IPP,Thorcoest IPP,Liponate® IPP,HelioPro IPP 50H



Isopropyl Palmitate (IPP) is fatty acid ester of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) is used in personal care products to enhance their moisturising and skin conditioning properties.
Isopropyl Palmitate (IPP) by McKinley Resources acts as an emollient, moisturizer and thickening agent.

Isopropyl Palmitate (IPP) is a compound of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) contains fatty acid, composed of vitamin A and an antioxidant.
Isopropyl Palmitate (IPP) can easily penetrate the skin and offers softness and suppleness.
Isopropyl Palmitate (IPP) is used in moisturizers, lipstick, facial treatments, eye shadow, hair conditioner, styling gel, concealer, foundation, lip gloss and anti-aging products.
Isopropyl Palmitate (IPP) complies with TSCA and DSL.

Blossom offers premium quality Isopropyl Palmitate/IPP in bulk.
Isopropyl Palmitate (IPP) is in odorless and colorless liquid form for versatile application.
Isopropyl Palmitate (IPP) is produced using isopropyl alcohol and palmitic acid via esterification process.

C16 Ester is 90% minimum.
Isopropyl Palmitate (IPP) is in liquid form at ambient temperature.
Isopropyl Palmitate (IPP) may solidify at cold temperatures (warming up will bring it back to liquid form).

Isopropyl Palmitate (IPP) works as an emollient, thickening agent, lubricant, and texture enhancer in beauty products.
Isopropyl Palmitate (IPP) helps to enhance the penetration of ingredients.
Isopropyl Palmitate (IPP) has skin conditioning, moisturizing, anti-static and binding properties.

Isopropyl Palmitate (IPP) is a common carrier for fragrance oils/deodorants.
Isopropyl Palmitate (IPP) has very good spreading properties and gives a silky touch to the products.
Isopropyl Palmitate (IPP) is one of the favorite ingredient amongst formulators for its versatile application.

Isopropyl Palmitate is a commonly used raw material in the cosmetics industry, known for its versatile properties and various benefits.
Isopropyl Palmitate (IPP) is an ester derived from isopropyl alcohol and palmitic acid.

Isopropyl Palmitate is a widely used raw material in the cosmetics industry, known for its versatile properties and various benefits.
Here are some key benefits of Isopropyl Palmitate as a raw material in cosmetics:

Emollient Properties:
Isopropyl Palmitate acts as an effective emollient, helping to moisturize and soften the skin.
Isopropyl Palmitate (IPP) forms a protective barrier on the skin's surface, preventing moisture loss and enhancing the overall texture and appearance of cosmetic products.

Enhanced Spreadability:
Isopropyl Palmitate improves the spreadability of cosmetic formulations.
Isopropyl Palmitate (IPP) helps the product glide smoothly over the skin, facilitating even distribution and easy application.
This ensures that the product is evenly applied and absorbed, providing uniform coverage.

Smooth and Silky Texture:
This ingredient imparts a smooth and silky texture to cosmetic products.
Isopropyl Palmitate (IPP) gives a luxurious and velvety feel upon application, enhancing the sensory experience for the user.

Non-Greasy Finish:
Isopropyl Palmitate has a non-greasy texture, making it suitable for use in various cosmetic formulations.
Isopropyl Palmitate (IPP) absorbs quickly into the skin, leaving behind a non-oily and lightweight finish without any greasiness or stickiness.

Compatibility:
Isopropyl Palmitate is compatible with a wide range of cosmetic ingredients, making it versatile for use in different formulations.
Isopropyl Palmitate (IPP) blends well with other emollients, oils, and active ingredients, allowing formulators to achieve desired product characteristics and performance.

Solvent and Carrier:
Isopropyl Palmitate acts as a solvent, aiding in the dissolution and dispersion of certain active ingredients within a cosmetic formulation.
Isopropyl Palmitate (IPP) also serves as a carrier, helping deliver other ingredients into the skin effectively.

Stability:
Isopropyl Palmitate contributes to the stability and shelf life of cosmetic products.
Isopropyl Palmitate (IPP) helps prevent the separation of oil and water phases, ensuring the formulation remains well-mixed and consistent over time.

Versatile Application:
Isopropyl Palmitate finds applications in various cosmetic products, including lotions, creams, moisturizers, makeup products, and hair care products.
Its versatility makes it suitable for use in different types of products.

Isopropyl Palmitate, or IPP-NF, is a highly versatile ingredient that finds extensive use in various personal care products such as moisturizers, lotions, creams, and cosmetics.
It is known for its anti-tackiness properties and conforms to the requirements of the National Formulary monograph for Isopropyl Palmitate.

With its low viscosity and surface tension, IPP-NF is an excellent spreading ester, making it a popular choice in various personal care products.
It has a low to no odor, which means it will not affect the fragrance of your final product.
For best results, incorporate Isopropyl Palmitate at recommended levels to achieve desired skin-soothing and textural benefits.

For best results, use at a concentration of 1% to 5% in your formulations.
It's important to store IPP-NF in a cool and dry place, preferably in its original sealed container.

Avoid exposing it to temperatures above 32°C (90°F) for extended periods of time.
Also, make sure to keep it at a temperature above 15°C (59°F) to prevent freezing.
Proper storage will help ensure the quality and effectiveness of the product.


FUNCTIONS OF ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is one of the important additives for high-grade cosmetics.
Isopropyl Palmitate (IPP) can be used as emulsifier and moistening agent for cosmetics. Is derived from palm oil and is used as a thickening agent.
Isopropyl Palmitate (IPP) can also be used as a moisturizer and as an antistatic agent.




USES & APPLICATIONS OF ISOPROPYL PALMITATE (IPP):
Pharmaceuticals:
Topical Medicinal Preparations
Personal Care and Cosmetics:
Emollient, Moisturizer, Thickening Agent
Flavor and Fragrance:
Solvent, Binder, Diluent

Isopropyl palmitate is a colorless liquid with a faint odor.
When stored properly at room temperature, it has a shelf life of up to two years from the date of manufacture.
Our product is tested to ASTM standards to confirm a maximum acid value of 0.5 mg KOH/g, a maximum iodine value of 1g/100g and a moisture content of no more than 0.1 percent.
For a detailed list of specs, download the product data sheet.

Use isopropyl palmitate in the preparation of topical medications, personal care products and cosmetics.
Isopropyl Palmitate (IPP) can also be used a solvent, binder and diluent for food-grade flavors and fragrances.
To obtain more information about potential applications or for answers to any of your questions about our isopropyl palmitate, contact Acme-Hardesty.


Isopropyl Palmitate (IPP) is an economical liquid ester made from the reaction of vegetal Palmitic Acid and petrochemical Isopropyl Alcohol.
Isopropyl Palmitate (IPP) conforms to the requirements of the National Formulary monograph for Isopropyl Palmitate.

Isopropyl Palmitate (IPP) is a light non-occlusive emollient with a soft, dry, non-oily feel.
Isopropyl Palmitate (IPP) is used as pigment binder, diluent, and solubilizing agent for mineral oil, silicones, lanolin, and fragrances in many personal care product applications.


Emollient:
Isopropyl palmitate acts as an emollient, helping to soften and smooth the skin.
Isopropyl Palmitate (IPP) forms a thin, occlusive layer on the skin's surface, preventing moisture loss and improving the overall texture and hydration of the skin.

Texture Modifier:
Isopropyl palmitate is used to modify the texture and sensory feel of cosmetic products.
Isopropyl Palmitate (IPP) imparts a silky, smooth, and non-greasy sensation, enhancing the spreadability and absorption of the formulation.

Solvent:
Isopropyl palmitate functions as a solvent, aiding in the solubilization and dispersion of other ingredients in cosmetic formulations.
Isopropyl Palmitate (IPP) helps to improve the compatibility and stability of various substances, ensuring they are evenly distributed throughout the product.

Enhances Delivery:
Isopropyl palmitate can enhance the penetration and absorption of other active ingredients into the skin.
Isopropyl Palmitate (IPP) helps to facilitate the delivery of beneficial compounds, allowing them to reach deeper layers of the skin and exert their effects.

Hair Care:
Isopropyl palmitate is used in hair care products, including conditioners, styling products, and leave-in treatments.
Isopropyl Palmitate (IPP) helps to improve the manageability, softness, and shine of the hair.

Makeup Formulations:
Isopropyl palmitate is often found in makeup products such as foundations, lipsticks, and eyeshadows.
Isopropyl Palmitate (IPP) helps to create a smooth and even application, improves adherence to the skin, and enhances the color payoff.

Fragrance Ingredient:
Isopropyl palmitate can serve as a carrier for fragrances in perfumes, colognes, and other scented products.
Isopropyl Palmitate (IPP) helps to stabilize and release the fragrance over time, improving the longevity and diffusion of the scent.

Isopropyl Palmitate (IPP) is used for After Sun Skin Care
Isopropyl Palmitate (IPP) is used for Bath Additives
Isopropyl Palmitate (IPP) is used for Cleansing Wipes

Isopropyl Palmitate (IPP) is used for Eye Area Color Cosmetics
Isopropyl Palmitate (IPP) is used for Facial Cleansers
Isopropyl Palmitate (IPP) is used for Facial Color Cosmetics

Isopropyl Palmitate (IPP) is used for Facial Skin Care
Isopropyl Palmitate (IPP) is used for Foot Care
Isopropyl Palmitate (IPP) is used for Hair Conditioners

Isopropyl Palmitate (IPP) is used for Hand & Body Care
Isopropyl Palmitate (IPP) is used for Lip Care
Isopropyl Palmitate (IPP) is used for Nail Care

Isopropyl Palmitate (IPP) is used for Personal Lubricants
Isopropyl Palmitate (IPP) is used for Self-Tanners
Isopropyl Palmitate (IPP) is used for Shaving Products
Isopropyl Palmitate (IPP) is used for Styling Aids



CHEMICAL AND PHYSICAL PROPERTIES OF ISOPROPYL PALMITATE (IPP)

Acid Value (mg KOH/g), 0.5 Max
Saponification Value (mg KOH/g), 185-191
Color (APHA), 25 Max
Moisture Content (%), 0.1 Max
Ash Content (%), 0.1 Max
Peroxide Value (meq/Kg), 0.6 Max
Viscosity (mPa.s) 20℃, 5-10
Density (g/cm3) 20℃, 0.852-0.855
Refractive Index 20℃, 1.436-1.440
Composition (%),
C16, 95 Min
Appearance (25°C), Clear liquid
Odor, Practically none
Color (APHA = PtCo), 15
Acid Value (mg KOH/g), 0.2
Saponification Value (mg KOH/g), 188
Specific Gravity (25°C/25°C), 0.852
Density (g/cc), 0.85
Viscosity (cP, 25°C), 6.7
Viscosity (cps, 60°C), 2.5
Refractive Index (25°C), 1.436
Iodine Value (gI2/100g), 0.4
Actives, %, > 95
Boiling Point (°C), 172
Flash Point (°C), 166
Melting Point (°C), 13
Molecular Weight (daltons), ~298
RVOC, U.S. EPA (%), 0
Dielectric Constant (25°C), 3.18
Insoluble In, Water
Soluble In, Isopropyl AlcoholLanolinMineral OilSiliconesVegetable Oil
Solvency Of, Avobenzone (15%)Bemotrizinol (4.5%)Ethylhexyl Triazone (3%)Oxybenzone (20+%)
Toxicology Profile, CIR Expert Panel: Safe at up to >50% in present practices of useJACT/IJT Reference(s): J. Amer. Coll. Toxicol. JACT 1(2):13-35, 1982LD50: > 5ml/kgOcular / Eye Irritation: MinimalSkin Irritation: Slight
Packaging, Drum - 390, 385.8lbs
Origin: Synthetic
Shelf life: 2 years from mfg. date
Freight Classification: NMFC 43940 S 2 CL 85
Kosher Status: Not Kosher
Flash Point: >230 øF
Melting Point: 11-13 øC
API: NO
Allergen: NO
Hazmat: YES
Molecular Weight: 298.50 g/mol
Appearance, Colorless transparent
Acid Value (mgKOH/g), 0.5 Max
Assay, 98% Min
Freezing Point, 16C Max
Refractive Index (20C), 1.435-1.440
Odor, No peculiar odor
Parameter, Value
CAS Number, 142-91-6
Chemical formula, C19H38O2
Molar mass, 298.51 g•mol−1
Density, 0.8525 g/cm3
Melting point, 13.5 °C (56.3 °F; 286.6 K)
Solubility in water, Insoluble


SAFETY INFORMATION ABOUT ISOPROPYL PALMITATE (IPP):
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


ISOPROPYL PALMITATE (IPP)
Isopropyl Palmitate (IPP) is a fatty acid ester obtained by the formal condensation of carboxy group of palmitic acid with propan-2-ol.
Isopropyl Palmitate (IPP) is in liquid form at ambient temperature.
Isopropyl Palmitate (IPP) is made from vegetable-based C16 Palmitic Acid and Isopropyl Alcohol.


CAS Number: 142-91-6
EC Number: 205-571-1
MDL number: MFCD00008993
CHEMICAL NAME: Hexadecanoic Acid, Isopropyl Ester
Linear Formula: CH3(CH2)14COOCH(CH3)2
Molecular Formula: C19H38O2


Isopropyl Palmitate (IPP) is a clear colorless liquid.
Isopropyl Palmitate (IPP) is a clear, colorless to pale yellow-colored, practically odorless viscous liquid that solidifies at less than 16°C.
Isopropyl Palmitate (IPP) is an analog of isopropyl myristate and an aliphatic ester used as a flavoring ingredient in food industry.


Isopropyl Palmitate (IPP) is one of the volatile compounds found in Psidium salutare fruits and boiled buckwheat flour.
Pharmaceutical secondary standards for application in quality control, provide pharma laboratories and manufacturers with a convenient and cost-effective alternative to the preparation of in-house working standards.


Isopropyl Palmitate (IPP) is a colorless clear oily liquid.
Isopropyl Palmitate (IPP) is a fatty acid ester obtained by the formal condensation of carboxy group of palmitic acid with propan-2-ol.
Isopropyl Palmitate (IPP) has a role as a human metabolite.


Isopropyl Palmitate (IPP) is a fatty acid ester and an isopropyl ester.
Isopropyl Palmitate (IPP) is functionally related to a hexadecanoic acid.
Isopropyl Palmitate (IPP) is a natural product found in Mangifera indica, Apium graveolens, and other organisms with data available.


Isopropyl Palmitate (IPP) is produced using isopropyl alcohol and palmitic acid via esterification process.
Isopropyl Palmitate (IPP) is in liquid form at ambient temperature.
Isopropyl Palmitate (IPP) may solidify at cold temperatures (warming up will bring it back to liquid form).


Isopropyl Palmitate (IPP) is an ester derived from isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) is a versatile ingredient commonly used in the cosmetics and personal care industry.
Isopropyl Palmitate (IPP) is produced adhering to the strictest standards, ensuring superior purity, consistency, and performance.


Isopropyl Palmitate (IPP) is a clear, colorless light liquid, it is an emollient and lubricating agent, commonly used in making cosmetic products, it is a light penetrating oil which doesn't leave skin greasy feel.
Isopropyl Palmitate (IPP) is a commonly used raw material in the cosmetics industry, known for its versatile properties and various benefits.


Isopropyl Palmitate (IPP) is an ester derived from isopropyl alcohol and palmitic acid.
Overall, Isopropyl Palmitate (IPP) offers emollient properties, enhanced spreadability, smooth texture, compatibility, stability, and versatility, making it a valuable raw material in the cosmetics industry.


Isopropyl Palmitate (IPP) is made from vegetable-based C16 Palmitic Acid and Isopropyl Alcohol.
Isopropyl Palmitate (IPP) is a fatty acid ester of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) is produced by the transesterification of the methyl ester with isopropyl alcohol.


The process includes the removal of methanol by distillation or esterification of the fatty acid with isopropyl alcohol.
Multi-functional fatty acid made of the ester of isopropyl alcohol and palmitic acid derived from renewable vegetable oils.
Isopropyl Palmitate (IPP) acts is an emollient, moisturizer, wetting agent, and anti-static agent.


Isopropyl Palmitate (IPP) is readily biodegradable and is GMO-free.
Saponification value of Isopropyl Palmitate (IPP) is 183-193.
Isopropyl Palmitate (IPP) is a fatty acid ester of isopropyl alcohol and palmitic acid.


Isopropyl Palmitate (IPP) is the ester of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) is an emollient, moisturizer, thickening agent, and anti-static agent .
The chemical formula of Isopropyl Palmitate (IPP) is CH3(CH2)14COOCH(CH3)2.


Isopropyl Palmitate (IPP) is related to isopropyl myristate (IPM), the difference being IPP is derived from palmitic fatty acid (C16) and IPM is derived from myristic fatty acid (C14).
Since we’re a little more familiar with IPM, we’ll end up contrasting and comparing the two at some point, so…


Isopropyl Palmitate (IPP) is an ester of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) is a non-branched saturated fatty acid ester obtained from isopropanol and palmitic acid, from palm oil.
Isopropyl Palmitate (IPP) is a clear liquid with a melting point of 13 ºC.


Isopropyl Palmitate (IPP) is produced from palmitic acid, derived from vegetable oil & isopropanol (or isopropyl alcohol).
Isopropyl Palmitate (IPP) is the ester of palmitic acid and isopropanol.
Isopropyl Palmitate (IPP) is a colorless and oily liquid.


Isopropyl Palmitate (IPP) is a fatty acid ester obtained by the formal condensation of carboxy group of palmitic acid with propan-2-ol.
Isopropyl Palmitate (IPP) has a role as a human metabolite.
Isopropyl Palmitate (IPP) is a fatty acid ester and an isopropyl ester.


Isopropyl Palmitate (IPP) derives from a hexadecanoic acid.
Isopropyl Palmitate (IPP) is fatty acid ester of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) is used in moisturizers, lipstick, facial treatments, eye shadow, hair conditioner, styling gel, concealer, foundation, lip gloss and anti-aging products.


Isopropyl Palmitate (IPP) complies with TSCA and DSL.
Isopropyl Palmitate (IPP), a clear colorless liquid, is chemically an ester of isopropanol and palmitic acid.
Isopropyl Palmitate (IPP) also has an influence on the viscosity of the formulation and prevents greasy glossiness on the skin.


Isopropyl Palmitate (IPP) is Hexadecanoic acid, 1-methylethyl ester.
Isopropyl Palmitate (IPP) is a fatty acid ester of propan-2-ol and palmitic acid.
Isopropyl Palmitate (IPP) is supplied as a clear oily liquid that may be colourless or slightly yellow, but practically odourless.



USES and APPLICATIONS of ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is used pharmaceutic aid (vehicle, oleaginous).
Isopropyl Palmitate (IPP) is an emollient and moisturizer, it also acts as a binder and solvent.
Similar to isopropyl myristate, it is produced from the combination of palmitic acid (coconut or palm oil) and isopropyl alcohol. enzymes are able to metabolize Isopropyl Palmitate (IPP) and studies do not show allergic reactions or toxicity.


Isopropyl Palmitate (IPP) is used to formulate and evaluate the suitability of pluronic lecithin organogels containing flurbiprofen for topical application and to characterize microemulsion systems of Isopropyl Palmitate (IPP).
Isopropyl Palmitate (IPP) is a fatty acid ester obtained by the formal condensation of carboxy group of palmitic acid with propan-2-ol.


Isopropyl Palmitate (IPP) works as an emollient, thickening agent, lubricant, and texture enhancer in beauty products.
Isopropyl Palmitate (IPP) helps to enhance the penetration of ingredients.
Isopropyl Palmitate (IPP) has skin conditioning, moisturizing, anti-static and binding properties.


Isopropyl Palmitate (IPP) is a common carrier for fragrance oils/deodorants.
Isopropyl Palmitate (IPP) has very good spreading properties and gives a silky touch to the products.
Isopropyl Palmitate (IPP) is one of the favorite ingredient amongst formulators for its versatile application.


Isopropyl Palmitate (IPP) is used Skin Care, Hair Care, Baby Care, Nail Care, Lip Care, Cosmetics, Massage, and Aromatherapy.
Isopropyl Palmitate (IPP) is used emollient & emulsifier in cosmetic creams, cosmetic oils, in hair tonics, hair dressings, hair pomades, sun tan & other lotions, other cosmetics, topical medicinal preparations.


Isopropyl Palmitate (IPP) is used Cosmetics, Personal care, Moisturisers, Sun care, Body care, Face care, and Hair care.
Isopropyl Palmitate (IPP) is used in these perfume types but not limited to them.
Unleash the full potential of your products with our high-grade Isopropyl Palmitate (IPP).


This versatile ingredient, Isopropyl Palmitate (IPP), is widely used across multiple industries due to its superb qualities and wide range of applications.
Within the realm of cosmetics and personal care, Isopropyl Palmitate (IPP) is a favored emollient that moisturizes and softens the skin, offering a silky, non-greasy feel to lotions, creams, and other skincare products.


Isopropyl Palmitate (IPP)'s ability to help other ingredients penetrate the skin makes it a staple in many cosmetic formulations.
Additionally, Isopropyl Palmitate (IPP) serves as a fragrance ingredient, enhancing the scent profile of perfumes, body sprays, and other scented products.
In the food and beverage industry, Isopropyl Palmitate (IPP) functions as an effective food additive and flavor ingredient, improving the texture and taste of a broad spectrum of food and drink items, thereby enriching the consumer’s culinary experience.


The pharmaceutical industry also harnesses the benefits of Isopropyl Palmitate (IPP).
As an excipient, Isopropyl Palmitate (IPP) aids in the delivery of active pharmaceutical ingredients, optimizing the effectiveness of medications and ensuring maximum therapeutic benefits.


Isopropyl Palmitate (IPP) serves as a chemical intermediate in the chemical industry, facilitating the creation of a variety of essential products.
Isopropyl Palmitate (IPP)'s role as a plasticizer in the plastics and polymer industry enhances the flexibility and workability of plastic products, contributing to their longevity and performance.


Isopropyl Palmitate (IPP) is a commonly used raw material in the cosmetics industry, known for its versatile properties and various benefits.
Isopropyl Palmitate (IPP) is a widely used raw material in the cosmetics industry, known for its versatile properties and various benefits.
This specialty cosmetic ingredient, Isopropyl Palmitate (IPP), have excellent emollient and spreading properties, and exceptional oxidative stability which make it perfect for cosmetic applications.


Isopropyl Palmitate (IPP) makes the skin smooth and soothing without leaving a greasy and oil feeling on the skin.
Isopropyl Palmitate (IPP) is used in many personal care and cosmetic products such as facial creams, lotions, tanning gels, deodorants, perfumes, make-up, aftershave, lip balm, pharmaceutical creams, etc.


Isopropyl Palmitate (IPP) is suitable for the most demanding applications, like pharma, personal care, and food and beverages.
Isopropyl Palmitate (IPP) is used Bath oils, skin creams, sunscreens, shaving creams, vanishing creams, hair conditioner, pre-shaves & aftershaves, shampoos, bath oils, aerosol antiperspirants and deodorants.


Isopropyl Palmitate (IPP) is an emollient, moisturizer, thickening agent, and anti-static agent.
Isopropyl Palmitate (IPP) is a traditional, fast spreading emollient for modern cosmetic applications.
Isopropyl Palmitate (IPP) is a clear, colorless and nearly odorless oil of intermediate polarity, with a low molecular weight, and a spreading value of approx. 1000 mm²/10 min.


Isopropyl Palmitate (IPP) has a cloud point of < 15°C, a viscosity (20°C) of 7-8 mPas, and a saponification value of 185-190.
Isopropyl Palmitate (IPP) is the ester of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) has the functions of moistening, penetrating when used in cosmetics.


The use level in cosmetics of Isopropyl Palmitate (IPP) is 2-10%.
Isopropyl Palmitate (IPP) can be used in sol, hair conditioner, bath oil, skin cream, sunblocking cream and shaving cream.
Isopropyl Palmitate (IPP) is suitable for the most demanding applications, like pharma, personal care, and food and beverages.


Isopropyl Palmitate (IPP) acts as topical medicinal preparations in pharmaceuticals; emollient, moisturizer, thickening agent in personal care and cosmetics; solvent, binder, diluent in flavor and fragrance.
Isopropyl Palmitate (IPP) is also used in hair care to improve luster, quality, and silkiness.


Isopropyl Palmitate (IPP) is widely used in cosmetics.
As a moisturizer for skin care, Isopropyl Palmitate (IPP) can be effectively absorbed by the skin.
As awetting agent and penetrant, Isopropyl Palmitate (IPP) can be used in sol products, bath oil, skin cream, sunscreen, shaving cream, and hair conditioner, among others.


Isopropyl Palmitate (IPP) is used as emollient and emulsifier (cosmetics and topical medicines) and as plasticizer.
Isopropyl Palmitate (IPP) is used for chemical synthesis, metal extraction or refining and processing of metals, textile processing, and in lubricants and additives.


Cosmetic formulations of Isopropyl Palmitate (IPP): binding, fragrance, perfuming, emollient.
Industrial uses of Isopropyl Palmitate (IPP): manufacturer of washing and cleaning products, polymers, textile treatment products and dyes, lubricants and greases, adhesives, sealants, polishes and waxes.


Isopropyl Palmitate (IPP) is a fast-spreading emollient suitable for all cosmetic applications.
Isopropyl Palmitate (IPP) is used as a cosmetics deep agent and skin moisturizer, penetrant.
Isopropyl Palmitate (IPP) has excellent penetration, moisturizing and softening effect on the skin, and is used for emulsifiers and moisturizers for cosmetics.


Isopropyl Palmitate (IPP) can be used in cosmetics such as sol product, hair conditioner, skin cream, sunscreen and shaving cream.
Isopropyl Palmitate (IPP) is widely used in cosmetics and pharmaceuticals (where it is emulsified with water to improve absorption of the product into the skin).


Isopropyl Palmitate (IPP) is used raw material for spin finishes and oiling agent for textile, Rubber processing agent, Plastic lubricant, Paint additive, Ink additive.
Isopropyl Palmitate (IPP) is used additives for pharmaceuticals and Friction modifier.


Isopropyl Palmitate (IPP) is a solvent fixative skin-perfumes.
Isopropyl Palmitate (IPP) acts as a physical fixative for perfumes.
Isopropyl Palmitate (IPP) acts as an emollient, moisturizer and thickening agent.


Isopropyl Palmitate (IPP) is a compound of isopropyl alcohol and palmitic acid.
Isopropyl Palmitate (IPP) contains fatty acid, composed of vitamin A and an antioxidant.
Isopropyl Palmitate (IPP) can easily penetrate the skin and offers softness and suppleness.


Isopropyl Palmitate (IPP) is used in personal care products to enhance their moisturising and skin conditioning properties.
An ester derived from isopropyl alcohol and palmitic acid, Isopropyl Palmitate (IPP) is used in many industrial processes as an emollient, thickening agent, moisturizer and anti-static agent.


Acme-Hardesty manufactures a vegetable-based Isopropyl Palmitate (IPP) containing a minimum 90 percent C16 esters.
A high-quality product suitable for the most demanding applications, Isopropyl Palmitate (IPP) is the choice of some of today’s leading pharma, personal care and food and beverage manufacturers.


Isopropyl Palmitate (IPP) is used in Pharmaceuticals, Topical Medicinal Preparations, Personal Care and Cosmetics, Emollient, Moisturizer, Thickening Agent, Flavor and Fragrance, Solvent, Binder, Diluent.


-Solvent uses of Isopropyl Palmitate (IPP):
Isopropyl Palmitate (IPP) functions as a solvent, aiding in the solubilization and dispersion of other ingredients in cosmetic formulations.
Isopropyl Palmitate (IPP) helps to improve the compatibility and stability of various substances, ensuring they are evenly distributed throughout the product.


-Enhances Delivery uses of Isopropyl Palmitate (IPP):
Isopropyl palmitate can enhance the penetration and absorption of other active ingredients into the skin.
Isopropyl Palmitate (IPP) helps to facilitate the delivery of beneficial compounds, allowing them to reach deeper layers of the skin and exert their effects.


-Hair Care uses of Isopropyl Palmitate (IPP):
Isopropyl palmitate is used in hair care products, including conditioners, styling products, and leave-in treatments.
Isopropyl Palmitate (IPP) helps to improve the manageability, softness, and shine of the hair.


-Makeup Formulations uses of Isopropyl Palmitate (IPP):
Isopropyl palmitate is often found in makeup products such as foundations, lipsticks, and eyeshadows.
Isopropyl Palmitate (IPP) helps to create a smooth and even application, improves adherence to the skin, and enhances the color payoff.


-Fragrance Ingredient uses of Isopropyl Palmitate (IPP):
Isopropyl palmitate can serve as a carrier for fragrances in perfumes, colognes, and other scented products.
Isopropyl Palmitate (IPP) helps to stabilize and release the fragrance over time, improving the longevity and diffusion of the scent.


-Emollient uses of Isopropyl Palmitate (IPP):
Isopropyl Palmitate (IPP) acts as an emollient, helping to soften and smooth the skin.
Isopropyl Palmitate (IPP) forms a thin, occlusive layer on the skin's surface, preventing moisture loss and improving the overall texture and hydration of the skin.


-Texture Modifier uses of Isopropyl Palmitate (IPP):
Isopropyl Palmitate (IPP) is used to modify the texture and sensory feel of cosmetic products.
Isopropyl Palmitate (IPP) imparts a silky, smooth, and non-greasy sensation, enhancing the spreadability and absorption of the formulation.


-Applications in Pharmaceutical Formulation or Technology uses of Isopropyl Palmitate (IPP):
Isopropyl Palmitate (IPP) is a nongreasy emollient with good spreading characteristics, used in topical pharmaceutical formulations and cosmetics such as: bath oils; creams; lotions; make-up; hair care products; deodorants; lip products; suntan preparations; and pressed powders.
Isopropyl Palmitate (IPP) is an established penetration enhancer for transdermal systems.
Isopropyl Palmitate (IPP) has also been used in controlled-release percutaneous films.



PHARMACEUTICAL APPLICATIONS OF ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is a nongreasy emollient with good spreading characteristics, used in topical pharmaceutical formulations and cosmetics such as: bath oils; creams; lotions; make-up; hair care products; deodorants; lip products; suntan preparations; and pressed powders.
Isopropyl Palmitate (IPP) is an established penetration enhancer for transdermal systems.
Isopropyl Palmitate (IPP) has also been used in controlled-release percutaneous films.



APPLICATIONS AND CHARACTERISTICS OF ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is a colorless liquid with a faint odor. When stored properly at room temperature, it has a shelf life of up to two years from the date of manufacture.
Isopropyl Palmitate (IPP) is used in the preparation of topical medications, personal care products and cosmetics.

Isopropyl Palmitate (IPP) can also be used a solvent, binder and diluent for food-grade flavors and fragrances.
Isopropyl Palmitate (IPP) has rapid spreading properties and can be used as an emulsifier, solvent, humectant and penetration enhancer in creams, lotions, sprays, and gels.



PROPERTIES OF ISOPROPYL PALMITATE (IPP):
Cosmetic and pharmaceutical uses of Isopropyl Palmitate (IPP): Oil base with low viscosity, good adaptation to skin.
Isopropyl Palmitate (IPP) is colorless no odor.
Isopropyl Palmitate (IPP) is suitable for cream-milk lotion, emollient and shampoo.



KEY BENEFITS OF ISOPROPYL PALMITATE (IPP) AS A RAW MATERIAL IN COSMETICS:
*Emollient Properties:
Isopropyl Palmitate (IPP) acts as an effective emollient, helping to moisturize and soften the skin.
Isopropyl Palmitate (IPP) forms a protective barrier on the skin's surface, preventing moisture loss and enhancing the overall texture and appearance of cosmetic products.


*Enhanced Spreadability:
Isopropyl Palmitate (IPP) improves the spreadability of cosmetic formulations.
Isopropyl Palmitate (IPP) helps the product glide smoothly over the skin, facilitating even distribution and easy application.
This ensures that Isopropyl Palmitate (IPP) is evenly applied and absorbed, providing uniform coverage.


*Smooth and Silky Texture:
Isopropyl Palmitate (IPP) imparts a smooth and silky texture to cosmetic products.
Isopropyl Palmitate (IPP) gives a luxurious and velvety feel upon application, enhancing the sensory experience for the user.

*Non-Greasy Finish:
Isopropyl Palmitate (IPP) has a non-greasy texture, making it suitable for use in various cosmetic formulations.
Isopropyl Palmitate (IPP) absorbs quickly into the skin, leaving behind a non-oily and lightweight finish without any greasiness or stickiness.


*Compatibility:
Isopropyl Palmitate (IPP) is compatible with a wide range of cosmetic ingredients, making it versatile for use in different formulations.
Isopropyl Palmitate (IPP) blends well with other emollients, oils, and active ingredients, allowing formulators to achieve desired product characteristics and performance.


*Solvent and Carrier:
Isopropyl Palmitate (IPP) acts as a solvent, aiding in the dissolution and dispersion of certain active ingredients within a cosmetic formulation.
Isopropyl Palmitate (IPP) also serves as a carrier, helping deliver other ingredients into the skin effectively.


*Stability:
Isopropyl Palmitate (IPP) contributes to the stability and shelf life of cosmetic products.
Isopropyl Palmitate (IPP) helps prevent the separation of oil and water phases, ensuring the formulation remains well-mixed and consistent over time.


*Versatile Application:
Isopropyl Palmitate (IPP) finds applications in various cosmetic products, including lotions, creams, moisturizers, makeup products, and hair care products.
Its versatility makes Isopropyl Palmitate (IPP) suitable for use in different types of products.



PRODUCTION METHODS OF ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is prepared by the reaction of palmitic acid with propan-2-ol in the presence of an acid catalyst.
A high-purity material is also commercially available, which Isopropyl Palmitate (IPP) is produced by enzymatic esterification at low temperatures.



FUNCTION OF ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is one of the important additives for high-grade cosmetics.
Isopropyl Palmitate (IPP) can be used as emulsifier and moistening agent for cosmetics.
Isopropyl Palmitate (IPP) is derived from palm oil and is used as a thickening agent.
Isopropyl Palmitate (IPP) can also be used as a moisturizer and as an antistatic agent.



KEY PROPERTIES OF ISOPROPYL PALMITATE (IPP):
*Emollient with good spreading properties
*Halal
*Kosher
*Non-GMO
*RSPO MB available



BENEFIT OF ISOPROPYL PALMITATE (IPP):
*Highly Moisturizing
*Emollient
*Fast Absorption
*Good Cleaning Properties



METHOD OF MANUFACTURE OF ISOPROPYL PALMITATE (IPP):
Isopropyl Palmitate (IPP) is prepared by the reaction of palmitic acid with propan-2-ol in the presence of an acid catalyst.
A high-purity material is also commercially available, which is produced by enzymatic esterification at low temperatures.



PHYSICAL and CHEMICAL PROPERTIES of ISOPROPYL PALMITATE (IPP):
Physical state: liquid
Color: colorless
Odor: No data available
Melting point/freezing point:
Melting point/freezing point: 13,5 °C
Initial boiling point and boiling range: 160 °C at 3 hPa
Flammability (solid, gas): No data available
Upper/lower flammability or explosive limits: No data available
Flash point: 113 °C - closed cup
Autoignition temperature: 235 °C
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: 0,0000745 hPa at 25 °C
Density: 0,853 g/cm3
Relative density: No data available
Relative vapor density: No data available

Particle characteristics: No data available
Explosive properties: No data available
Oxidizing properties: No data available
Other safety information: No data available
IUPAC Name: propan-2-yl hexadecanoate
INCHI: InChI=1S/C19H38O2/c1-4-5-6-7-8-9-10-11-12-13-14-15-16-17-19(20)21-18(2)3/h18H,4-17H2,1-3H3
InChi Key: XUGNVMKQXJXZCD-UHFFFAOYSA-N
Canonical SMILES: CCCCCCCCCCCCCCCC(=O)OC(C)C
Molecular Formula: C19H38O2
PubChem CID: 8907
Beilstein: 1786567
Molecular Weight: 298.5
Solubility: Not miscible or difficult to mix with water.
Boil Point(°C): 160°/2mmHg
Melt Point(°C): 13°C
Refractive Index: 1.438
Flash Point(°F): 235.4 °F
Flash Point(°C): 183°C
Boiling point: 1608C at 266 Pa (2 mmHg)
Freezing point: 13–158C
Refractive index: 1.436 at 258C for Propal.
Solubility: Soluble in acetone, chloroform, ethanol (95%), ethyl
acetate, mineral oil, propan-2-ol, silicone oils, vegetable oils, and
aliphatic and aromatic hydrocarbons; practically insoluble in
glycerin, glycols, and water.

Specific gravity: 0.852 at 258C for Propal.
Surface tension: 29 mN/m for Tegosoft P at 258C
Viscosity (dynamic): 5–10 mPa s (5–10 cP) at 258C
Molecular Weight: 298.5 g/mol
XLogP3-AA: 8.2
Hydrogen Bond Donor Count: 0
Hydrogen Bond Acceptor Count: 2
Rotatable Bond Count: 16
Exact Mass: 298.287180451 g/mol
Monoisotopic Mass: 298.287180451 g/mol
Topological Polar Surface Area: 26.3Ų
Heavy Atom Count: 21
Formal Charge: 0
Complexity: 224
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
IUPAC Name: propan-2-yl hexadecanoate
INCHI: InChI=1S/C19H38O2/c1-4-5-6-7-8-9-10-11-12-13-14-15-16-17-19(20)21-18(2)3/h18H,4-17H2,1-3H3

InChi Key: XUGNVMKQXJXZCD-UHFFFAOYSA-N
Canonical SMILES: CCCCCCCCCCCCCCCC(=O)OC(C)C
Molecular Formula: C19H38O2
PubChem CID: 8907
Beilstein: 1786567
Molecular Weight: 298.5
Solubility: Not miscible or difficult to mix with water.
Boil Point(°C): 160°/2mmHg
Melt Point(°C): 13°C
Refractive Index: 1.438
Flash Point(°F): 235.4 °F
Flash Point(°C): 183°C
IUPAC Name: Propan-2-yl hexadecanoate
Molecular Weight: 298.5
Molecular Formula: C19H38O2
Canonical SMILES: CCCCCCCCCCCCCCCC(=O)OC(C)C
InChI: XUGNVMKQXJXZCD-UHFFFAOYSA-N
InChI Key: InChI=1S/C19H38O2/c1-4-5-6-7-8-9-10-11-12-13-14-15-16-17-19(20)21-18(2)3/h18H,4-17H2,1-3H3
Boiling Point: 160 ℃ at 2mmHg
Melting Point: 13 °C
Flash Point: 183 °C
Density: 0.852g/ml
Solubility: Water insoluble, soluble in alcohol, acetone

Appearance: Colorless, slightly viscous liquid
Storage: Store in a closed container at a dry place at room temperature
Alpha Sort: Isopropyl palmitate
Complexity: 224
Composition: Isopropyl palmitate
Covalently-Bonded Unit Count: 1
Defined Atom Stereocenter Count: 0
Exact Mass: 298.287180451
Heavy Atom Count: 21
Hydrogen Bond Acceptor Count: 2
Hydrogen Bond Donor Count: 0
Monoisotopic Mass: 298.287180451
Physical State: Liquid
Refractive Index: 1.438
Rotatable Bond Count: 16
Stability: Stable.
Topological Polar Surface Area: 26.3 Ų
IUPAC Name: propan-2-yl hexadecanoate
INCHI: InChI=1S/C19H38O2/c1-4-5-6-7-8-9-10-11-12-13-14-15-16-17-19(20)21-18(2)3/h18H,4-17H2,1-3H3
InChi Key: XUGNVMKQXJXZCD-UHFFFAOYSA-N
Canonical SMILES: CCCCCCCCCCCCCCCC(=O)OC(C)C
Molecular Formula: C19H38O2
PubChem CID: 8907

Beilstein: 1786567
Molecular Weight: 298.5
Chemical formula: C19H38O2
Molar mass: 298.511 g·mol−1
Density: 0.8525 g/cm3
Melting point: 13.5 °C (56.3 °F; 286.6 K)
Solubility in water: Insoluble
CAS Number:142-91-6
Chemical formula: C19H38O2
Molar mass: 298.51 g·mol−1
Density: 0.8525 g/cm3
Melting point: 13.5 °C (56.3 °F; 286.6 K)
Solubility in water: Insoluble
Melting point: 11-13 °C (lit.)
Boiling point: 160°C 2mm
Density: 0.852 g/mL at 25 °C (lit.)
vapor pressure: 0.007Pa at 25℃
refractive index: n20/D 1.438(lit.)
Flash point: >230 °F
storage temp.: 2-8°C
solubility: <0.001g/l
form: neat
color: Colourless

Odor: very sl. odor
Water Solubility: Not miscible or difficult to mix with water.
BRN: 1786567
InChIKey: XUGNVMKQXJXZCD-UHFFFAOYSA-N
LogP: 8.16
CAS DataBase Reference: 142-91-6(CAS DataBase Reference)
Substances Added to Food (formerly EAFUS): ISOPROPYL PALMITATE
FDA 21 CFR: 310.545
EWG's Food Scores: 1
FDA UNII: 8CRQ2TH63M
NIST Chemistry Reference: Isopropyl palmitate(142-91-6)
EPA Substance Registry System: Isopropyl palmitate (142-91-6)
Cosmetics Info: Isopropyl Palmitate
Molecular Weight: 298.5
Exact Mass: 298.50
BRN: 1786567

EC Number: 205-571-1
UNII:8CRQ2TH63M
NSC Number: 69169
DSSTox ID: DTXSID9027104
Color/Form: Colorless liquid
HScode: 2915709000
PSA: 26.3
XLogP3: 8.2
Appearance: DryPowder
Density: 0.8404 g/cm3 @ Temp: 38 °C
Melting Point: 13.5 °C
Boiling Point: 160 °C @ Press: 2 Torr
Flash Point: >230 °F
Refractive Index: 1.443
Water Solubility: Not miscible or difficult to mix with water.
Storage Conditions: 2-8°C
Vapor Pressure: 5.59X10-5 mm Hg at 25 deg C (extrapolated)
Odor: Almost odorless
Henrys Law Constant: Henry's Law constant = 4.66X10-2 atm-cu m/mol at 25 °C (est)
Experimental Properties: Hydroxyl radical reaction rate constant = 2.21X10-11 cu cm/molec-sec at 25 °C (est)



FIRST AID MEASURES of ISOPROPYL PALMITATE (IPP):
-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 ISOPROPYL PALMITATE (IPP):
-Environmental precautions:
No special environmental precautions required.
-Methods and materials for containment and cleaning up:
Keep in suitable, closed containers for disposal.



FIRE FIGHTING MEASURES of ISOPROPYL PALMITATE (IPP):
-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 ISOPROPYL PALMITATE (IPP):
-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: 0,4 mm
Break through time: 480 min
Splash contact:
Material: Nitrile rubber
Minimum layer thickness: 0,4 mm
Break through time: 480 min
*Body Protection:
Impervious clothing.
*Respiratory protection:
Respiratory protection not required.
-Control of environmental exposure:
No special environmental precautions required



HANDLING and STORAGE of ISOPROPYL PALMITATE (IPP):
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Store in cool place.
Keep container tightly closed in a dry and well-ventilated place.



STABILITY and REACTIVITY of ISOPROPYL PALMITATE (IPP):
-Reactivity:
No data available
-Chemical stability:
Stable under recommended storage conditions.
-Possibility of hazardous reactions:
No data available
-Conditions to avoid:
No data available



SYNONYMS:
Emerest 2316
hexadecanoic acid isopropyl ester
hexadecanoic acid 1-methylethyl ester
isopropyl hexadecanoate
isopropylis palmitas
Isopropylpalmitat
Kessco IPP
Lexol IPP-NF
Liponate
IPP
palmitic acid isopropyl ester
Propal
Protachem IPP
Rita IPP
Stepan IPP
Super Refined Crodamol IPP
Tegosoft P
Unimate
IPP
Waglinol 6016
Wickenol 111
Isopropyl Palmitate (IPP)
Upmate IPP
Unipro IPP-20
1-Methylethyl ester1-methylethyl hexandecanoate
Crodamol IPP
1-methylethyl hexadecanoate
ISOPROPYL PALMITATE
142-91-6
Isopropyl hexadecanoate
Hexadecanoic acid, 1-methylethyl ester
Isopalm
Wickenol 111
Deltyl
Isopal
Propal
Deltyl prime
Emerest 2316
Tegester isopalm
Ja-fa ippkessco
Sinnoester PIT
Crodamol IPP
Plymouth IPP
Starfol IPP
Unimate IPP
Kessco IPP
Emcol-IP
Isopropyl n-hexadecanoate
Nikkol IPP
Stepan D-70
Palmitic acid, isopropyl ester
Estol 103
Usaf ke-5
JA-FA Ipp
1-Methylethyl hexadecanoate
Kessco isopropyl palmitate
Hexadecanoic acid, isopropyl ester
Hariol ipp
propan-2-yl hexadecanoate
Palmitic Acid Isopropyl Ester
NSC 69169
Estol 1517
HSDB 2647
Tegosoft P
Liponate IPP
UNII-8CRQ2TH63M
EINECS 205-571-1
Lexol IPP
8CRQ2TH63M
NSC-69169
BRN 1786567
CHEBI:84262
2-propyl hexadecanoate
AI3-05733
Isopropyl palmitate (NF)
Isopropyl palmitate [NF]
DTXSID9027104
EC 205-571-1
4-02-00-01167 (Beilstein Handbook Reference)
Isopropyl ester of hexadecanoic acid
NCGC00164128-01
WE(2:0(1Me)/16:0)
DTXCID507104
ISOPROPYL PALMITATE (II)
ISOPROPYL PALMITATE [II]
ISOPROPYL PALMITATE (MART.)
ISOPROPYL PALMITATE [MART.]
ISOPROPYL PALMITATE (USP-RS)
ISOPROPYL PALMITATE [USP-RS]
ISOPROPYL PALMITATE (EP IMPURITY)
ISOPROPYL PALMITATE [EP IMPURITY]
CAS-142-91-6
ISOPROPYL PALMITATE (EP MONOGRAPH)
ISOPROPYL PALMITATE [EP MONOGRAPH]
MFCD00008993
iso-propylpalmitate
isopropyl-palmitate
Hexadecanoic acid 1-methylethyl ester
Radia 7200
1-methylethyl hexandecanoate
SCHEMBL7743
Palmitic acid-isopropyl ester
Isopropyl palmitate, >=90%
CHEMBL139055
Hexadecanoic acid isopropyl ester
Hexadecanoic acid, 1-methyl ester
ISOPROPYL PALMITATE [HSDB]
ISOPROPYL PALMITATE [INCI]
WLN: 15VOY1 & 1
ISOPROPYL PALMITATE [VANDF]
NSC69169
Tox21_112085
Tox21_202558
ISOPROPYL PALMITATE [WHO-DD]
LMFA07010675
AKOS015902011
Tox21_112085_1
CS-W012142
HY-W011426
NCGC00164128-02
NCGC00260107-01
BS-15396
Hexadecanoic acidisopropyl n-hexadecanoate
Isopropyl palmitate, technical grade, 90%
FT-0631830
P0005
1-Methylethyl ester1-methylethyl hexandecanoate
D04632
A885074
SR-01000944752
J-007718
Q2631777
SR-01000944752-1
Isopropyl hexadecanoate, European Pharmacopoeia (EP) Reference Standard
Isopropyl palmitate, United States Pharmacopeia (USP) Reference Standard
Isopropyl palmitate, Pharmaceutical Secondary Standard; Certified Reference Material
Hexadecanoic acid, 1-methylethyl ester
Palmitic acid, isopropyl ester
Crodamol IPP
Deltyl
Deltyl Prime
Emcol-IP
Emerest 2316
Hexadecanoic acid, isopropyl ester
Isopal
Isopalm
Kessco IPP
Propal
Sinnoester PIT
Stepan D-70
Wickenol 111
Estol 103
Isopropyl n-hexadecanoate
Ja-fa ippkessco
Plymouth IPP
Starfol IPP
Tegester isopalm
Unimate IPP
USAF KE-5
Isopropyl hexadecanoate
Ja-fa ipp
Kessco isopropyl palmitate
Isopropyl ester of hexadecanoic acid
1-methylethyl hexandecanoate
Lexol IPP
Liponate IPP
Radia 7200
Tegosoft P
1-methylethyl hexadecanoate
2-propyl hexadecanoate
NSC 69169
Nikkol IPP
1-Methylethyl hexadecanoate
Crodamol IPP
Deltyl
Deltyl Prime
Emcol-IP
Emerest 2316
Estol 103
Hexadecanoic acid, 1-methylethyl ester
Hexadecanoic acid, isopropyl ester
Isopal
Isopalm
Isopropyl hexadecanoate
Isopropyl n-hexadecanoate
JA-FA IPP
JA-FA IPPKessco
Kessco IPP
Kessco isopropyl palmitate
Nikkol IPP
Palmitic acid, isopropyl ester
Plymouth IPP
Propal
Sinnoester PIT
Starfol IPP
Stepan D-70
Tegester isopalm
Unimate IPP
Wickenol 111
Propan-2-yl hexadecanoate
Isopropyl hexadecanoatel
Hexadecanoic acid isopropyl ester
Hexadecanoic acid
1-methylethyl ester
ISOPROPYL HEXADECANOATE
Deltyl
plymouthipp
ISOPROPYLPALMITAT
kesscoisopropylpalmitate
Isopal
Isopalm
Emcol-IP
estol103
ja-faipp
Hexadecanoic acid,1-methylethyl ester
Palmitic acid,isopropyl ester
Deltyl
Deltyl Prime
Emcol IP
Isopal
Isopropyl palmitate
Propal
Sinnoester PIT
Kessco IPP
Wickenol 111
Crodamol IPP
Emerest 2316
Isopalm
Stepan D 70
Isopropyl hexadecanoate
Nikkol IPP
IPP
1-Methylethyl hexadecanoate
Exceparl IPP
Estol 1517
IPP-EX
Palmsurf IPP 98
Lexol IPP
NSC 69169
Versagel MP 1600
Stepan IPP
Neoderm IPP
Nikkol IPP-EX
SR Crodamol IPP-LQ
IPP-R
Radia 7732




ISOPROPYL SALICYLATE
cas no 607-85-2 Salicylic acid isopropyl ester; Isopropyl o-hydroxybenzoate; 2-Hydroxybenzoic acid 1-methylethyl ester;
ISOPROPYL STEARATE
propan-2-yl octadecanoate; ISOPROPYL STEARATE, N° CAS : 112-10-7, Nom INCI : ISOPROPYL STEARATE, Nom chimique : Isopropyl stearate, N° EINECS/ELINCS : 203-934-9. Ses fonctions (INCI): Agent fixant : Permet la cohésion de différents ingrédients cosmétiques. Emollient : Adoucit et assouplit la peau.Agent d'entretien de la peau : Maintient la peau en bon état. Noms français : ESTER ISOPROPYLIQUE DE L'ACIDE STEARIQUE; STEARATE D'ISOPROPYLE. Noms anglais : ISOPROPYL STEARATE; OCTADECANOIC ACID, 1-METHYLETHYL ESTER; OCTADECANOIC ACID, ISOPROPYL ESTER; STEARIC ACID, ISOPROPYL ESTER. Utilisation et sources d'émission: Produit organique. 112-10-7 [RN] 203-934-9 [EINECS] Isopropyl stearate [ACD/IUPAC Name] Isopropylstearat [German] [ACD/IUPAC Name] MFCD00026666 Octadecanoic acid, 1-methylethyl ester [ACD/Index Name] Stéarate d'isopropyle [French] [ACD/IUPAC Name] [112-10-7] 10/7/112 1-METHYLETHYL OCTADECANOATE 4-02-00-01219 [Beilstein] 4-02-00-01219 (Beilstein Handbook Reference) [Beilstein] 7/10/112 EINECS 203-934-9 https://mcule.com/MCULE-3731648811 isopropyl octadecanoate Octadecanoic acid 1-methylethyl ester octadecanoic acid isopropyl ester Octadecanoic acid, isopropyl ester Octadecanoic acid,1-methylethyl ester propan-2-yl octadecanoate Revenge Stearic acid isopropyl ester Stearic acid, isopropyl ester Tegosoft S Wickenol 127
ISOPROPYLAMINE
SYNONYMS 2-Aminopropane; Monoisopropylamine; MIPA 2-Propanamine; sec-Propylamine; Propan-2-Amine; CAS NO. 75-31-0
Isopropylamine (MIPA)
2-Aminopropane; Monoisopropylamine; MIPA ; -Propanamine; sec-Propylamine; Propan-2-Amine; 2-Amino-propaan (Dutch); 2-amino-propano (Italian); 2-aminopropan (German); Isopropilamina (Italian); Isopropilamina (Spanish); Isopropylamine (French); cas no: 75-31-0
Isopropylated Triphenyl Phosphate
cas no: 27138-31-4 2-(1-benzoyloxypropan-2-yloxy)propyl benzoate; dermol DPG-2B; di(propylene glycol) dibenzoate; oxy dipropyl dibenzoate; propanol, oxybis-,dibenzoate; uniplex 50;
Isopropylethanolamine (IPAE)
2-(Diisopropylamino)ethanol; 2-Diisopropylaminoethanol; (Diisopropylamino)ethanol; N,N-Diisopropyl ethanolamine cas no: 96-80-0
Isopropylmyristate
ISOPROPYL MYRISTATE; Tetradecanoic acid 1-methylethyl ester; Estergel; Myristic Acid, Isopropyl Ester; Bisomel; Tegester; Tetradecanoic Acid, Isopropyl; CAS NO:110-27-0
Isopropylpalmitate
ISOPROPYL PALMITATE; IPP; Isopal; Hexadecanoic acid, 1-methylethyl ester; Palmitic acid, Isopropyl ester; Deltyl; Hexadecanoic acid, Isopropyl ester; Isopal; Isopropyl hexadecanoate; 1-methylethyl hexandecanoate; CAS NO:142-91-6
ISOPROPYLPARABEN
2-ETHYLHEXYL DIPHENYL PHOSPHATE; Diphenyloctylphosphate; Diphenyl phosphate, 2-ethyl-1-hexanol ester; 2-ethylhexyl diphenyl phosphorate; diphenyl 2-ethylhexyl phosphate; Ethylhexyl diphenylphosphate; octicizer; Phosphoric acid 2-ethylhexyl diphenyl ester; santicize CAS NO:1241-94-7
ISOPROPYLPEHNYL DIPHENYL PHOSPHATE
ISOSTEARETH-10, N° CAS : 52292-17-8. Nom INCI : ISOSTEARETH-10, 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
Isoquinoline
sec-Propyl bromide; 2-Bromopropane; iso-C3H7Br; 2-Brompropan; 2-bromo-propan;bromo-2propane; 2-BROMOPROPANE; propane,2-bromo-; sec-propylbromide; ISOPROPYL BROMIDE; PropylBromide~98%;sec-Propyl bromide CAS NO:75-26-3
Isosorbide Dicaprylate
isosorbide dicaprylate; diester of isosorbide and caprylic acid; D-Glucitol, 1,4:3,6-dianhydro-, dioctanoate; ISOSORBIDE DICAPRYLATE CAS NO:64896-70-4
ISOSTEARETH-10
ISOSTEARETH-20, N° CAS : 52292-17-8 Nom INCI : ISOSTEARETH-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
ISOSTEARETH-20
ISOSTEARIC ACID; 16-METHYLHEPTADECANOIC ACID; Isooctadecanoic acid CAS Number 2724-58-5
ISOSTEARIC ACID


Isostearic acid is a type of fatty acid that is often used in the cosmetics and personal care industry.
Isostearic acid is derived from the hydrogenation of isostearic acid-rich oils, typically plant-based oils.
Isostearic acid has a similar chemical structure to stearic acid but with a branched chain, which gives it some unique properties.
The chemical formula for isostearic acid is C18H36O2, and its IUPAC (International Union of Pure and Applied Chemistry) name is 2,2,4-trimethylpentanoic acid.

CAS Number: 30399-84-9
EC Number: 250-705-4



APPLICATIONS


Isostearic acid is commonly used as an emollient in skincare products, such as moisturizers and lotions, to provide skin with a soft and smooth feel.
Isostearic acid serves as a key ingredient in lip balms and lipsticks, helping to improve the texture and spreadability of these products.
Isostearic acid is utilized in the formulation of sunscreens to enhance their water resistance and adherence to the skin.

Isostearic acid is an essential component in stick deodorants, contributing to their firm texture and ease of application.
In hair care products like conditioners, isostearic acid helps in providing a silky and manageable texture to the hair.
Isostearic acid is often found in cream-based foundations, helping to create a creamy and blendable consistency.
Isostearic acid is used in body butters and creams, offering long-lasting hydration to the skin.

In mascara formulations, it aids in the even distribution of pigments, preventing clumping.
Isostearic acid plays a role in stabilizing emulsions in cosmetic products, ensuring that oil and water components remain well mixed.
Isostearic acid can be used in the production of solid soaps, contributing to their hardness and durability.
Isostearic acid is employed in the manufacturing of bar soaps to create a luxurious lather and improve the overall texture.

Isostearic acid is used in shaving creams to provide a smooth glide for razors.
Isostearic acid can be found in anti-aging creams, helping to lock in moisture and reduce the appearance of fine lines and wrinkles.
Isostearic acid is used in some pharmaceutical preparations for its emollient properties, aiding in the formulation of topical medications.
In cosmetic serums, isostearic acid can help improve the even distribution of active ingredients.

Isostearic acid is utilized in body washes and shower gels to enhance their lathering properties.
Isostearic acid is employed in the production of solid perfumes, providing a stable base for fragrance.
In lip glosses, it helps create a glossy and smooth finish.
Isostearic acid can be added to nail polishes to enhance their consistency and shine.
Isostearic acid is used in certain personal lubricants to provide a smooth and silky feel.

In hair styling products like pomades, isostearic acid contributes to the product's texture and hold.
Isostearic acid is found in some pharmaceutical ointments to aid in their spreadability and absorption.

Isostearic acid is used in the production of cuticle creams and balms to moisturize and nourish nail cuticles.
In foot creams and balms, it helps soften and hydrate rough and dry skin.
Isostearic acid is a versatile ingredient that finds applications in a wide range of cosmetic and personal care products, contributing to their texture, stability, and overall performance.

Isostearic acid is used in the production of lipstick pencils and crayons, providing them with a smooth and creamy texture for easy application.
Isostearic acid is found in some anti-chafing products, like anti-chafing balms, to reduce friction and irritation on the skin.

Isostearic acid is employed in the formulation of matte makeup products, such as matte foundations and powders, to create a velvety, shine-free finish.
In body scrubs and exfoliating products, it can help bind abrasive particles together and improve their spreadability.
Isostearic acid is used in some mineral makeup formulations, enhancing the adherence of mineral pigments to the skin.
Isostearic acid plays a role in the production of solid stick concealers, aiding in their smooth application and blendability.

In cream eyeshadows, isostearic acid helps create a creamy consistency and prevents creasing.
Isostearic acid is used in the manufacture of solid perfumed body balms, providing a solid base for fragrances.

Isostearic acid is employed in the formulation of waterproof mascaras to ensure they resist smudging and flaking.
In body lotions and creams with shimmer or glitter, it helps disperse the reflective particles evenly for a radiant glow.

Isostearic acid is used in certain specialty hair products, such as hair waxes and pomades, to provide hold and control without a greasy feel.
Isostearic acid can be found in cuticle oils and serums, aiding in the hydration and nourishment of nail cuticles.
Isostearic acid is used in the production of color-correcting makeup products to create a smooth and blendable texture.

In sunless tanning lotions and creams, isostearic acid helps distribute the tanning agent evenly for a streak-free tan.
Isostearic acid is added to some cosmetic primers to improve the overall texture of the skin before makeup application.
Isostearic acid is used in certain under-eye concealers and treatments to provide a smooth and hydrating formula.

In massage oils, it can be used to improve slip and glide during massages.
Isostearic acid is employed in some baby care products, such as baby lotions and diaper creams, to provide gentle moisturization.
Isostearic acid is used in certain specialty balms designed to soothe and protect sensitive areas of the skin.

In body powders, it helps create a smooth and easily applicable formula.
Isostearic acid is employed in some natural and organic cosmetics as an alternative to synthetic emollients.
Isostearic acid is added to certain nail treatments to help strengthen and condition nails.
In specialty skincare products, it can aid in the even distribution of active ingredients for targeted treatments.

Isostearic acid is used in some tattoo aftercare products to moisturize and protect the skin.
Isostearic acid's versatility extends to various niche cosmetic and personal care products, contributing to their functionality and appeal.
Isostearic acid is utilized in the production of solid stick blushes and bronzers, providing a creamy consistency for easy blending.
Isostearic acid can be found in some specialty face masks, contributing to their smooth texture and ease of application.
Isostearic acid is used in the formulation of tinted lip balms to offer both color and hydration to the lips.

In certain nail polishes, it aids in preventing chipping and provides a glossy finish.
Isostearic acid is employed in cuticle creams to soften and moisturize the cuticles around the nails.
Isostearic acid is added to some body sprays to disperse fragrance evenly on the skin.
Isostearic acid is used in sun care products like sunblock sticks, helping to create a water-resistant barrier on the skin.

In certain wound care products, it aids in creating a protective and moisturizing layer over wounds.
Isostearic acid can be found in natural and organic cosmetics as an emollient option with a plant-derived origin.
Isostearic acid is used in the formulation of face serums to enhance the skin's ability to absorb active ingredients.

In massage creams and lotions, it helps maintain smooth glide during massages.
Isostearic acid is employed in the production of solid stick eye treatments to reduce puffiness and dark circles.
In some aftershave products, it contributes to a soothing and moisturizing post-shave experience.
Isostearic acid can be found in certain hand creams and lotions designed to hydrate and protect the hands.

Isostearic acid is used in specialty products for tattoo care, aiding in the healing process and preservation of tattoo colors.
In foot balms and creams, it helps soften and moisturize dry and calloused skin.
Isostearic acid is added to some body wash bars to create a rich lather and improve their cleansing properties.
Isostearic acid is employed in hair pomades to provide a strong hold with a matte finish.

In lip stain formulations, it aids in creating long-lasting color that adheres to the lips.
Isostearic acid is used in some men's grooming products, such as beard balms, to condition facial hair.
Isostearic acid can be found in nail treatments to improve the overall health and appearance of nails.

Isostearic acid is added to some specialty face powders to create a finely milled texture for a flawless complexion.
In cuticle conditioners, it helps repair and protect the nail cuticles from damage.
Isostearic acid is employed in some solid hair conditioners to provide deep hydration without a heavy feel.
In certain intimate care products, it contributes to a gentle and moisturizing formula.

Isostearic acid is used in the production of solid stick highlighters to create a smooth and blendable texture for highlighting the face.
Isostearic acid can be found in some specialty lip scrubs, aiding in the exfoliation of dry and chapped lips.
Isostearic acid is employed in makeup setting sprays to help set makeup in place and provide a long-lasting finish.

In certain hair serums and oils, it contributes to a lightweight and non-greasy formula that adds shine and controls frizz.
Isostearic acid is used in sun care products such as sunblock sticks to ensure even coverage and sun protection.
Isostearic acid can be added to specialty eyeshadow primers to improve the adherence and vibrancy of eyeshadow pigments.

Isostearic acid is employed in the formulation of solid stick blushes and bronzers, enhancing their blendability and longevity.
In certain wound care products, it helps create a moisture-retentive environment to facilitate the healing process.
Isostearic acid is used in the production of solid stick face cleansers for convenient and mess-free cleansing.

Isostearic acid is found in certain cuticle pens designed for easy and precise application.
In hair styling waxes, it provides a pliable hold for shaping and styling hair.
Isostearic acid can be added to body scrubs to create a creamy base that enhances exfoliation.
Isostearic acid is employed in solid perfumed balms, providing a longer-lasting fragrance option.

In some natural and organic baby care products, it serves as an emollient option for gentle moisturization.
Isostearic acid is used in nail polish removers to help dissolve and remove nail polish effectively.
Isostearic acid can be found in makeup remover wipes to help lift and dissolve makeup residues.

In certain hand sanitizers, it contributes to a formula that moisturizes the hands while disinfecting.
Isostearic acid is employed in foot masks to hydrate and soften the skin on the feet.
Isostearic acid can be added to facial cleansing bars for a gentle cleansing experience.

In eyebrow waxes and gels, it helps shape and tame unruly eyebrows.
Isostearic acid is used in solid perfume compacts for easy and precise application of fragrance.
Isostearic acid can be found in some specialty cuticle creams enriched with vitamins and botanical extracts.

In body butters and balms, it helps create a rich and nourishing formula for dry skin.
Isostearic acid is employed in certain acne spot treatments to provide a non-drying and gentle formula.
Isostearic acid is used in specialty facial masks to improve the texture and spreadability of the mask.



DESCRIPTION


Isostearic acid is a type of fatty acid that is often used in the cosmetics and personal care industry.
Isostearic acid is derived from the hydrogenation of isostearic acid-rich oils, typically plant-based oils.
Isostearic acid has a similar chemical structure to stearic acid but with a branched chain, which gives it some unique properties.
The chemical formula for isostearic acid is C18H36O2, and its IUPAC (International Union of Pure and Applied Chemistry) name is 2,2,4-trimethylpentanoic acid.

Isostearic acid is classified as a saturated fatty acid because it lacks double bonds between carbon atoms in its hydrocarbon chain.
Isostearic acid is known for its ability to act as a thickening agent, emollient, and stabilizer in various cosmetic and personal care products, such as creams, lotions, and lipsticks.

Due to its branched structure, isostearic acid has a lower melting point compared to straight-chain fatty acids like stearic acid.
This property makes Isostearic acid useful for formulating products with desirable textures and spreadability.
Additionally, it can help improve the stability and shelf life of certain cosmetic formulations.

Isostearic acid is a saturated fatty acid with a branched molecular structure.
Isostearic acid is derived from the hydrogenation of certain plant-based oils.
Isostearic acid compound is also known as 2,2,4-trimethylpentanoic acid.

Isostearic acid is commonly used in the cosmetics and personal care industry.
Isostearic acid serves as an emollient, providing moisturization to the skin.
Its unique structure gives it a lower melting point than straight-chain fatty acids.
Isostearic acid acts as a thickening agent in various skincare and makeup products.
Isostearic acid helps improve the spreadability of creams and lotions.

Isostearic acid enhances the texture and feel of lipsticks and other cosmetic formulations.
Isostearic acid is often utilized to stabilize emulsions in cosmetics.
Isostearic acid contributes to the long-term stability of certain cosmetic products.
Isostearic acid is generally recognized as safe for topical use.

Isostearic acid is used in both water-in-oil and oil-in-water emulsions.
Its branched chain structure provides flexibility and versatility in formulation.
Isostearic acid can be found in moisturizers, sunscreens, and foundation products.
Isostearic acid is compatible with a wide range of other cosmetic ingredients.

Isostearic acid can help prevent products from separating over time.
Isostearic acid is valued for its ability to create creamy and smooth textures.
Isostearic acid is often used to improve the consistency of stick deodorants.

Isostearic acid may also be used in hair care products like conditioners.
Isostearic acid is odorless and typically does not impact the scent of cosmetic products.
Isostearic acid is considered non-comedogenic and suitable for sensitive skin.
Isostearic acid can be used in both leave-on and rinse-off cosmetic formulations.

Isostearic acid is important for achieving desired product aesthetics.
Its versatility and safety make it a popular choice in the cosmetics industry.



PROPERTIES


Chemical Formula: C18H36O2
IUPAC Name: 2,2,4-Trimethylpentanoic acid
Molecular Weight: Approximately 284.48 grams per mole
Physical State: Solid at room temperature
Appearance: Typically a white to off-white crystalline powder
Odor: Odorless
Solubility: Insoluble in water; soluble in organic solvents like ethanol and oils.
Melting Point: Generally in the range of 45-55°C (113-131°F)
Boiling Point: Decomposes before boiling.
Density: Approximately 0.88 grams per cubic centimeter (g/cm³)
Acid Value: A measure of its acidity due to carboxylic acid groups.
Hydrophilic-Lipophilic Balance (HLB): Typically considered more lipophilic (oil-loving).
Emollient: It acts as an emollient, providing moisturization and softening to the skin.
Thickening Agent: Used as a thickening agent in cosmetic formulations.
Stabilizer: It can stabilize emulsions, preventing separation of oil and water phases.
Texture Enhancer: Improves the texture and spreadability of cosmetic products.
Spreadability: Enhances the even distribution of pigments and active ingredients.
Long-Lasting: Contributes to the long-term stability and shelf life of products.
Hydration: Helps lock in moisture and prevents dehydration of the skin.



FIRST AID


Inhalation:

If isostearic acid fumes or dust are inhaled, remove the affected person from the contaminated area to an area with fresh air.
If breathing difficulties persist, seek immediate medical attention.
Provide artificial respiration if the person is not breathing, and if trained to do so.


Skin Contact:

In case of skin contact, immediately remove contaminated clothing and shoes.
Wash the affected skin area thoroughly with plenty of lukewarm water and mild soap for at least 15 minutes.
Seek medical attention if skin irritation, redness, or rash develops.


Eye Contact:

If isostearic acid comes into contact with the eyes, rinse the affected eye(s) gently with lukewarm water for at least 15 minutes, keeping the eyelid(s) open.
Seek immediate medical attention if eye irritation, redness, or pain persists.


Ingestion:

If isostearic acid is ingested accidentally, do not induce vomiting unless directed to do so by medical professionals.
Rinse the mouth with water if the material is not oil-based or emulsified.
Seek immediate medical attention and provide the medical personnel with information about the ingested substance.



HANDLING AND STORAGE


Handling:

Personal Protective Equipment (PPE):
When handling isostearic acid, wear appropriate PPE, including safety goggles or a face shield, gloves, and a lab coat or protective clothing.
The selection of PPE should be based on the specific hazards and conditions of use.

Ventilation:
Ensure adequate ventilation in the handling area to prevent the buildup of vapors or dust.
Use local exhaust ventilation or work in well-ventilated areas.

Avoid Inhalation:
Avoid inhaling fumes or dust from isostearic acid.
If handling the material in powder form, consider wearing a dust mask or respirator as needed.

Avoid Skin Contact:
Minimize skin contact with isostearic acid.
In case of skin contact, wash affected areas promptly with soap and water.

Eye Protection:
Wear safety goggles or a face shield to protect your eyes from potential splashes or contact with isostearic acid.

Handling Equipment:
Use appropriate handling equipment, such as scoops or spatulas, to transfer isostearic acid from containers to avoid skin contact.

No Smoking or Open Flames:
Do not smoke or use open flames in areas where isostearic acid is handled, as it may be flammable.


Storage:

Container Selection:
Store isostearic acid in containers made of materials compatible with fatty acids, such as high-density polyethylene (HDPE) or stainless steel.
Ensure that the containers are tightly sealed to prevent contamination and moisture ingress.

Temperature Control:
Store isostearic acid in a cool, dry place away from direct sunlight and heat sources.
The storage temperature should typically be within a range of 15°C to 30°C (59°F to 86°F).

Avoid Incompatible Materials:
Keep isostearic acid away from incompatible materials, such as strong oxidizing agents and strong bases, as well as incompatible chemicals.
Store it separately from these substances.

Moisture Control:
Protect isostearic acid from exposure to moisture and humidity, as water can lead to hydrolysis or degradation of the material.
Store it in a moisture-free environment.

Labeling:
Clearly label storage containers with the product name, hazard information, and handling instructions.
Maintain clear identification of the contents to prevent confusion.

Storage Stability:
Check the manufacturer's recommendations for the shelf life and storage conditions of the specific isostearic acid product you are using.
Follow any storage stability guidelines provided.

Fire Safety:
If the material is flammable, store it away from open flames, sparks, and ignition sources.
Ensure that fire extinguishing equipment is available in the storage area.

Spill Containment:
Have spill containment measures in place, including absorbent materials and spill response equipment, to handle any accidental spills or leaks promptly.

Keep Out of Reach:
Store isostearic acid out of reach of children and unauthorized personnel.

Regulatory Compliance:
Comply with all relevant local, state, and national regulations regarding the handling, storage, and transportation of isostearic acid.


Transportation:

When transporting isostearic acid, follow all applicable regulations for hazardous materials, if applicable.
Ensure proper labeling and packaging in accordance with transportation regulations.
Use suitable containers and secure them to prevent spills or leaks during transportation.
Be aware of any special handling or transportation requirements specified by regulatory authorities.



SYNONYMS


2,2,4-Trimethylpentanoic acid
Isooctanoic acid
2,2,4-Trimethylvaleric acid
Isopentanoic acid, 2,2,4-trimethyl-
2,2,4-Trimethyl-n-pentanoic acid
2,2,4-Trimethylvaleric acid
TMVA (Abbreviation for 2,2,4-Trimethylpentanoic acid)
Isotridecyl alcohol
2,2-Dimethylpentanoic acid
2,2-Dimethylvaleric acid
Isoheptanoic acid
2,2-Dimethyl-n-pentanoic acid
2,2-Dimethylvaleric acid
Neododecanoic acid
2,2-Dimethylheptanoic acid
2,2-Dimethyl-n-heptanoic acid
2,2-Dimethyl-n-valeric acid
Isoheptylic acid
2,2-Dimethyl-n-octanoic acid
2,2-Dimethyl-n-nonanoic acid
Isododecanoic acid
2,2-Dimethyl-n-decanoic acid
2,2-Dimethyl-n-undecanoic acid
2,2-Dimethyl-n-dodecanoic acid
Isoarachidic acid
2,2-Dimethyl-n-tetradecanoic acid
2,2-Dimethyl-n-hexadecanoic acid
2,2-Dimethyl-n-octadecanoic acid
Isotetradecyl alcohol
2,2-Dimethylpentadecanoic acid
2,2-Dimethylheptadecanoic acid
2,2-Dimethyloctadecanoic acid
ISOSTEARIC ACID

Isostearic acid is a branched-chain fatty acid derived from oleic acid.
Isostearic acid is characterized by its branched structure, which differs from the linear structure of most common fatty acids.

CAS Number: 22890-21-7
EC Number: 679-818-0

Synonyms: Isomerized fatty acid, Branched-chain fatty acid, Isomerized oleic acid, Branched-chain oleic acid, 2-Methylundecanoic acid, 2-Methyldecanoic acid, 2-Methylundecylic acid, 2-Methyldecylic acid, 2-Methylundecanoate, 2-Methyldecylate, 2-Methylundecylate, 2-Methyldecylate, 2-Methyl-10-undecanoic acid, 2-Methyldecanoate, 2-Methylundecyl ester, 2-Methyldecyl ester, 2-Methyl-10-undecanoate, Isostearate, Isomerized oleate, Branched-chain oleate, Isomerized oleoyl acid, Isomerized oleyl acid, Branched-chain oleyl acid, Branched-chain oleoyl acid, Isomerized 9-octadecenoic acid, Isomerized cis-9-octadecenoic acid, Isomerized 9-octadecylic acid, Isomerized cis-9-octadecylic acid, Isomerized 9-octadecenoate, Isomerized cis-9-octadecenoate, Isomerized 9-octadecyl ester, Isomerized cis-9-octadecyl ester



APPLICATIONS


Isostearic acid is widely used in the cosmetics industry for its versatile applications.
Isostearic acid is a common ingredient in skincare products such as lotions, creams, and moisturizers.

Isostearic acid acts as an emollient, helping to soften and hydrate the skin.
Isostearic acid is valued for its ability to create smooth and creamy textures in cosmetic formulations.

Isostearic acid is often used in lip balms and lipsticks to provide moisture and enhance spreadability.
In hair care products, it helps to condition and tame unruly hair, reducing frizz and improving manageability.

Isostearic acid contributes to the stability of emulsions in creams and lotions, preventing separation of oil and water phases.
Isostearic acid can act as a thickening agent, providing viscosity to cosmetic formulations without feeling heavy or greasy.
Isostearic acid is compatible with a wide range of cosmetic ingredients, allowing for versatile formulation possibilities.

Isostearic acid helps to improve the spreadability and absorption of skincare products, ensuring even application and maximum efficacy.
Isostearic acid is often found in sunscreens, providing emollient properties while enhancing the dispersion of UV filters.

In makeup products, it helps to create smooth and blendable textures in foundations, concealers, and eyeshadows.
Isostearic acid can be used in natural and organic cosmetics as a skin-friendly alternative to synthetic emollients.

Isostearic acid contributes to the overall sensory experience of cosmetic products, imparting a luxurious feel and texture.
Isostearic acid is valued for its non-comedogenic properties, making it suitable for use in products for acne-prone skin.

Isostearic acid helps to improve the stability and shelf life of cosmetic formulations, reducing the risk of rancidity and spoilage.
Isostearic acid is used in baby care products such as diaper creams and lotions for its gentle and soothing properties.
In men's grooming products, it helps to soften facial hair and moisturize the skin after shaving.

Isostearic acid is often included in anti-aging creams and serums for its hydrating and plumping effects on the skin.
Isostearic acid can be used in natural deodorants as an alternative to synthetic emulsifiers, providing moisture and odor control.

Isostearic acid contributes to the overall performance and efficacy of cosmetic formulations, ensuring optimal results for the consumer.
In massage oils and body butters, it helps to nourish and hydrate the skin, leaving it soft and supple.

Isostearic acid can be used in exfoliating scrubs and cleansers to provide moisture and prevent dryness.
Isostearic acid is often found in baby oils and lotions for its gentle and hypoallergenic properties, suitable for sensitive skin.
Isostearic acid is a versatile ingredient with numerous applications in the cosmetics industry, valued for its emollient, thickening, and stabilizing properties.

Isostearic acid is commonly used in the formulation of facial cleansers and makeup removers for its ability to dissolve and lift away dirt, oil, and makeup.
Isostearic acid is a key ingredient in shaving creams and foams, providing lubrication and glide for a smooth shave while moisturizing the skin.

Isostearic acid is utilized in body washes and shower gels to create a rich lather that cleanses and hydrates the skin.
In hand creams and lotions, it helps to replenish moisture lost from frequent washing and exposure to harsh environmental conditions.
Isostearic acid is incorporated into foot creams and balms to soften calluses and soothe dry, cracked heels.

Isostearic acid can be found in cuticle oils and treatments, helping to nourish and condition the nails and cuticles.
Isostearic acid is used in sunless tanning products to enhance the spreadability and absorption of the tanning agent, ensuring a streak-free tan.

In lip scrubs and exfoliators, it helps to gently buff away dead skin cells while moisturizing and conditioning the lips.
Isostearic acid is added to bath oils and bath bombs to create a luxurious bathing experience, leaving the skin soft and hydrated.

Isostearic acid is included in anti-itch creams and lotions to provide relief from dry, irritated skin conditions such as eczema and psoriasis.
Isostearic acid is utilized in barrier creams and ointments to protect the skin from irritation and friction, particularly in sensitive areas.

In baby wipes and diaper rash creams, it helps to soothe and protect delicate skin from diaper rash and irritation.
Isostearic acid can be found in massage oils and lotions used in spa treatments, providing nourishment and hydration to the skin.

Isostearic acid is added to cuticle creams and treatments to soften and moisturize the cuticles, promoting healthy nail growth.
Isostearic acid is used in body scrubs and exfoliating treatments to slough off dead skin cells and reveal smoother, more radiant skin.

In foot scrubs and treatments, it helps to soften rough, dry skin and calluses, leaving feet feeling soft and refreshed.
Isostearic acid is incorporated into face masks and treatments to hydrate and nourish the skin, promoting a healthy, glowing complexion.

Isostearic acid can be found in hand sanitizers and antibacterial gels to moisturize and protect the skin from dryness and irritation.
Isostearic acid is added to cuticle oils and serums to hydrate and strengthen the nails, preventing breakage and splitting.

In body oils and serums, it helps to lock in moisture and nourish the skin, leaving it feeling soft and supple.
Isostearic acid is utilized in facial toners and mists to hydrate and refresh the skin, restoring its natural balance.

Isostearic acid can be found in makeup setting sprays and primers to create a smooth, even base for makeup application while providing hydration.
Isostearic acid is added to body lotions and creams to replenish moisture and soothe dry, rough skin.

In cuticle creams and treatments, it helps to soften and moisturize the cuticles, promoting healthy nail growth.
Isostearic acid is used in bath salts and soaks to soften the skin and relax tired muscles, providing a luxurious bathing experience.


Isostearic acid is compatible with a wide range of cosmetic ingredients, allowing for versatile formulation possibilities.
Isostearic acid functions as a co-emulsifier, assisting primary emulsifiers in stabilizing oil-in-water and water-in-oil emulsions.
Isostearic acid is often found in lip balms, body lotions, and facial creams, providing nourishment and protection.

Its emulsifying properties make it useful in formulating creams and lotions with high oil content.
Isostearic acid helps create smooth and uniform textures in cosmetic products, enhancing their application and absorption.

Isostearic acid contributes to the overall performance and stability of skincare and personal care formulations.
Isostearic acid is known for its ability to improve the spreadability and blending of makeup products.

In hair care, it helps reduce frizz and static while enhancing shine and manageability.
Isostearic acid is often used in natural and organic cosmetics for its skin-friendly properties.
Its mild and non-irritating nature makes it suitable for use in products for sensitive skin types.

Isostearic acid contributes to the luxurious feel and sensory experience of high-quality cosmetic formulations.
Isostearic acid is a versatile ingredient valued for its emollient, surfactant, and thickening properties in skincare and personal care products.



DESCRIPTION


Isostearic acid is a branched-chain fatty acid derived from oleic acid.
Isostearic acid is characterized by its branched structure, which differs from the linear structure of most common fatty acids.
Isostearic acid is used in various cosmetic and personal care products as an emollient, surfactant, and thickening agent due to its unique properties.

Isostearic acid is a branched-chain fatty acid derived from oleic acid.
Its unique structure features branching at the carbon chain, distinguishing it from linear fatty acids.

Isostearic acid is typically a white to pale yellow solid at room temperature, with a slightly waxy texture.
Isostearic acid is soluble in organic solvents like ethanol and acetone but insoluble in water.
Isostearic acid is valued in cosmetics for its emollient properties, which help soften and moisturize the skin.

Isostearic acid acts as a surfactant, allowing it to stabilize emulsions and disperse ingredients in cosmetic formulations.
As a thickening agent, it contributes to the viscosity and consistency of creams, lotions, and other skincare products.

Isostearic acid can be synthesized from oleic acid through isomerization or dimerization processes.
In addition to skincare, it is used in hair care products for its conditioning and smoothing effects.

Isostearic acid plays a role in improving the spreadability and texture of cosmetic formulations.
Its mild and gentle properties make it suitable for sensitive skin formulations.
Isostearic acid helps enhance the sensory experience of cosmetic products, imparting a luxurious feel.
This fatty acid contributes to the long-lasting hydration and moisturization of the skin.



PROPERTIES


Physical Properties:

Appearance: White to off-white solid or waxy substance
Odor: Generally odorless or has a faint, characteristic odor
Melting Point: Typically between 45°C to 55°C
Boiling Point: Decomposes before reaching a boiling point
Density: Approximately 0.9 to 0.95 g/cm^3
Solubility in Water: Insoluble
Solubility in Organic Solvents: Soluble in organic solvents such as ethanol, acetone, and chloroform
pH: Not applicable (as it is a solid)


Chemical Properties:

Chemical Formula: C18H36O2
Molar Mass: Approximately 284.48 g/mol
Hydrogen Bond Acceptor Count: 2
Hydrogen Bond Donor Count: 1
Rotatable Bond Count: 16
Complexity: 179
Isomeric SMILES: CCC(CCC(C)(C)CCCCCC(C)C)CCCCC(O)=O
Topological Polar Surface Area: 37.3 Ų
Refractive Index: Typically around 1.450-1.460
Flash Point: Typically above 100°C (closed cup)
Vapor Pressure: Negligible at room temperature
Octanol/Water Partition Coefficient (Log P): Approximately 8.35



FIRST AID


1. Inhalation:

If inhaled, remove the affected person to fresh air immediately.
Keep the individual calm and at rest.
If breathing is difficult, administer oxygen if trained to do so.
Seek medical attention if symptoms persist or worsen.


2. Skin Contact:

Remove contaminated clothing and footwear immediately.
Wash the affected area with soap and water thoroughly for at least 15 minutes.
If irritation or rash develops, seek medical advice.
If skin irritation persists, seek medical attention.


3. Eye Contact:

Flush the eyes with gently flowing lukewarm water for at least 15 minutes, holding the eyelids open to ensure thorough rinsing.
Seek immediate medical attention and bring the product container or label if available.


4. Ingestion:

Rinse the mouth thoroughly with water if the product has been swallowed.
Do not induce vomiting unless directed by medical personnel.
Do not give anything by mouth to an unconscious person.
Seek medical attention or contact a poison control center immediately.


5. Notes to Physician:

No specific antidote is available.
Treat symptomatically and supportively.
In case of skin burns, treat as thermal burns.
Monitor vital signs and provide appropriate medical care as necessary.


6. Advice to First Aid Providers:

Ensure that personal protective equipment (PPE) is worn when providing first aid.
Follow standard precautions for handling chemical exposures.
Provide comfort and reassurance to the affected individual.
If symptoms persist or worsen, seek medical advice promptly.



HANDLING AND STORAGE


1. Handling:

Handle isostearic acid in a well-ventilated area to minimize inhalation exposure.
Use appropriate personal protective equipment (PPE) such as safety goggles, gloves, and protective clothing to prevent skin and eye contact.
Avoid breathing vapors, mist, or dust generated during handling.
Do not eat, drink, or smoke while handling isostearic acid.
Wash hands thoroughly after handling to remove any residual product.
Prevent skin and eye contact by avoiding splashing and spills.


2. Storage:

Store isostearic acid in a cool, dry, well-ventilated area away from heat, sparks, and open flames.
Keep containers tightly closed when not in use to prevent contamination and evaporation.
Store away from incompatible materials such as strong oxidizing agents.
Do not store near sources of ignition or in direct sunlight.
Ensure storage area is equipped with appropriate containment measures to contain spills.
Maintain good housekeeping practices to minimize the risk of accidental exposure.
Store in containers made of compatible materials, such as high-density polyethylene (HDPE) or glass.
Check containers regularly for signs of damage or leakage and replace if necessary.
Follow all applicable regulations and guidelines for the safe storage of chemicals.


3. Transportation:

Transport isostearic acid in accordance with applicable regulations for the transport of hazardous materials.
Ensure containers are securely sealed and properly labeled with appropriate hazard warnings.
Use suitable packaging materials to prevent breakage or leakage during transportation.
Avoid transportation with incompatible materials or substances that may react with isostearic acid.


4. Spill and Leak Procedures:

In case of spillage, contain the spill to prevent further spread and minimize exposure.
Wear appropriate PPE, including gloves and safety goggles, during cleanup.
Absorb spilled liquid with inert absorbent material (e.g., sand, earth) and collect in suitable containers for disposal.
Avoid creating dust or aerosols during cleanup by using dampened materials.
Dispose of contaminated materials in accordance with local regulations and guidelines.
Clean spill area thoroughly with soap and water to remove any residue.


5. Waste Disposal:

Dispose of unused or contaminated isostearic acid in accordance with local, state, and federal regulations.
Follow appropriate waste disposal procedures and guidelines for chemical waste.
Do not dispose of via sewerage systems or in domestic waste.
Consult with regulatory authorities or waste disposal experts for proper disposal methods.
Empty containers may be recycled or disposed of in accordance with applicable regulations.


6. Emergency Procedures:

Familiarize yourself and your staff with emergency procedures in case of spills, leaks, or exposure incidents.
Maintain emergency eyewash stations and safety showers in areas where isostearic acid is handled.
Keep a spill kit and absorbent materials readily available for immediate response to spills.
Train personnel on proper handling procedures and emergency response protocols.
ISOSTEARIC ACID
Isostearic acid is a fatty acid molecule with an 18-carbon atom chain backbone.
Isostearic Acid is an isomer of stearic acid
Isostearic Acid's chemical formula is C18H36O2


CAS NUMBER: 2724-58-5

EC NUMBER: 250-178-0

MOLECULAR FORMULA: C18H36O2

MOLECULAR WEIGHT: 284.5 g/mol

IUPAC NAME: 16-methylheptadecanoic acid




While stearic acid has a linear carbon chain with 18 carbon atoms, isosteric acid as a carbon chain with 17 atoms and a single carbon branch at the 16th carbon atom.
Isostearic Acid's chemical structure can be represented as (CH3)2CH(CH2)14CO2H.

Isostearic Acid is found naturally in meat products and vegetable oils.
Isostearic acid has a wide range of industrial uses.

Isostearic Acid is mainly used as an additive in adhesives or lubricants for both paints
Isostearic Acid can be used in personal care products.

Being a fatty acid, Isostearic Acid is also amphiphilic
Isostearic Acid is a molecule with a hydrophobic end and a hydrophilic end.

As such, Isostearic Acid can have favorable interactions with both polar and non-polar molecules, enabling it to act as a surfactant.
Isostearic Acid is also soluble in many oils, which allows it to be used as an emulsifier or dispersant.

With this set of properties, isostearic acid is a useful additive in a variety of applications, including:
-Adhesives
-Coatings and paints
-Finishing agents
-Lubricants
-Sealants
-Solvents
-Surfactants
-Viscosity adjusters

Isostearic Acid is used in personal care products
Isostearic Acid is also used in cosmetic industry

Isostearic Acid has lubricating or adhesive properties
Isostearic Acid is also used in paper products.

Isostearic Acid is a lightly-branched, liquid fatty acid produced by the reaction of oleic acid with a natural mineral catalyst
There is no chemical addition in this reaction, Isostearic Acid is based 100% on the parent oil or fat.

Isostearic acid is used in applications which require a liquid fatty acid with exceptional stability: thermal stability in the case of a lubricant, odour stability for a cosmetic formulation, and oxidation stability for products with long shelf-life requirements.
The branching structure of isostearic acid also enhances its dispersing power

Isostearic Acid is used in cosmetic and industrial applications for the stabilisation of pigments and mineral particles in oils and solvents.
Isostearic Acid is used for a cosmetic formulations

Isostearic Acid can be used in industrial applications for the stabilisation of pigments mineral particles in oils and solvents
Isostearic Acid differs from other C18 fatty acids of the same category in a number of ways.

While other C18 fatty acids are produced by splitting fats or oils, isostearic acid is manufactured as a coproductof a tightly controlled reaction to synthesize dimerized fatty acids.
The structural makeup of isostearic acid also has a valuable combination of saturation and branching, when compared to other fatty acids like stearic acid and oleic acid.

This set of features make isostearic acid a versatile building block for high-value applications in synthetic lubricants, metal stamping and forming, coatings, and personal care products.
Isostearic Acid's features impart thermal stability, oxidative stability, surface activity, lubricity, low color, and feel in multiple formulations. Isostearic acid is used as-is in some cases, but is also derivatized to form isostearyl alcohols, amides, and esters to further expand its reach across many industries and applications.

APPLICATIONS:
*Synthetic lubricants – Isostearic Acid has good thermal and oxidative stability

*Lubricant additives – Isostearic Acid is derivatized to isostearyl amide to provide boundary lubrication and detergency

*Coatings – Isostearic Acid imparts flexibility and durability properties to industrial coatings

*Metalworking – Isostearic Acid has good surface activity for protective coatings and thermal stability for rolling and stamping

*Personal care products – Isostearic Acid is derivatized to isostearyl alcohol to impart feel and texture to creams and lotions.


Isostearic Acid is a unique fatty acid.
Isostearic Acid combines the best properties of stearic acid with the best properties of oleic acid.

Isostearic acid is an 18-carbon branched-chain fatty acid naturally found in plants and animals.
However, Isostearic Acid's a blend of many octadecanoic acids, found in vegetables and animals fat.

Isostearic Acid is prepared from soybean oil and tallow.
Isostearic Acid comes as white to pale yellow, clear oily liquid.

Isostearic Acid is liquid at room temperature.
Isostearic Acid is chemically, a carboxyl group attached to alkyl chain, methylated, branched at various carbons makes it much more stable compared to other linear chain fatty acids, including oxidation potential.

Isostearic Acid can be used as a lubricant, that can improve flow of a powder mixture.
Isostearic Acid has excellent spreadability without oiliness


PHYSICAL PROPERTIES:

-Molecular Weight: 284.5 g/mol

-XLogP3: 7.2

-Exact Mass: 284.271530387 g/mol

-Monoisotopic Mass: 284.271530387 g/mol

-Topological Polar Surface Area: 37.3Ų

-Physical Description: Colorless Liquid

-Boiling Point: 400 °C

-Melting Point: 69.5 °C

-Solubility: 0.007116 mg/L

-LogP: 7.674

-Refractive Index: 1.4440 (estimate)

-Storage Temperature: 2-8°C

-pka: 4.78


Isostearic Acid can be easily used in a cosmetic which not only moisturizes skin but also does not leave any oily feel.
However, in cosmetic formulation Isostearic Acid is used as a binder to form cake-like compact powder or eye shadow.

Isostearic Acid is also used in cleansing and emulsifying agent, because of presence of both ionic and nonionic groups.
Isostearic Acid is used in varieties of cosmetic and personal care products.


CHEMICAL PROPERTIES:

-Hydrogen Bond Donor Count: 1

-Hydrogen Bond Acceptor Count: 2

-Rotatable Bond Count: 15

-Heavy Atom Count: 20

-Formal Charge: 0

-Complexity: 212

-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


Isostearic Acid is a synthetically created fatty acid
Isostearic Acid is used as a binder in skin and beauty products

Although Isostearic Acid is also seen in products as a surfactant and emulsifier
Isostearic Acid is used to thicken most formulas as a binder and emulsifier.

As a fatty acid, Isostearic Acid is a component of a complex mixture that also has the added benefit of protecting the skin from oxidative damage
Isostearic Acid is used to thicken most formulas as a binder and emulsifier.

Isostearic Acid is a clear, oily liquid that is used in a wide variety of cosmetics and personal care products.
Isostearic acid (16-Methylheptadecanoic acid) is used in the synthesis of methyl-branched poly(hydroxyalkanoate)s, biosurfactants and silver nanoparticles.

Isostearic acid is a fatty acid that is used as an emollient in pharmaceutical preparations.
Isostearic acid has been shown to have skin-moisturizing and anti-inflammatory properties, which are due to its ability to inhibit the activity of phospholipase A2.

Isostearic acid also has a high degree of chemical stability and adsorption capacity.
Isostearic Acid's adsorption mechanism is not yet well understood, but it appears to be related to its hydroxyl group.

Isostearic Acid has been used successfully in the treatment of congestive heart failure and can prevent the accumulation of lipids on the surface of blood vessels, thereby reducing atherosclerosis.
Isostearic Acid also functions as a substrate for the synthesis of isovaleric acid, which can be used as a fragrance ingredient in cosmetic products.

Isostearic Acid is a fatty acid which contains 18-carbon atom chain.
The IUPAC name of Isostearic Acid is octadecanoic acid.

Isostearic Acid is used in the following products:
-washing & cleaning products
-adhesives and sealants
-fuels
-lubricants and greases
-coating products
-fertilisers

Isostearic Acid is used in biocides (e.g. disinfectants, pest control products)
Isostearic Acid is also used in pH regulators and water treatment products

Isostearic Acid can be used in laboratory chemicals, plant protection products, water softeners and water treatment chemicals.
Isostearic Acid is used in formulation of mixtures
Isostearic Acid is used for the manufacture of chemicals.

Isostearic Acid is a yellow solution and its chemical formula is C18H36O2.
Isostearic Acid is a saturated carbon solution.

Isostearic Acid is found naturally in meat products and vegetable oils.
The molecular mass of Isostearic Acid is 284.48 g/mol.

Isostearic Acid is soluble in many oils and is used as an emulsifier or dispersant.
Isostearic Acid acid is a methyl-branched fatty acid

Isostearic Acid is heptadecanoic acid (margaric acid) substituted by a methyl group at position 16.
Isostearic Acid is a branched-chain saturated fatty acid

Isostearic Acid is a long-chain fatty acid
Isostearic Acid is functionally related to a heptadecanoic acid.
Isostearic Acid is a natural product found in Aristolochia grandiflora, Streptomyces, and other organisms with data available.


SYNONYMS:

ISOOCTADECANOIC ACID
isostearic
16-METHYLHEPTADECANOIC ACID
Isostearinsure
ISOSTEARIC ACID
16-methyl-heptadecanoicaci
Heptadedecanoicacid,16-Methyl
ISOSTEARIC ACID MIXED ISOMERS
Heptadecanoic acid, 16-methyl-
heptadecanoic acid, 16-methyl-
jaric I-18CG
jaric I-18IG
jaric I-18LG
liponate ISA
16-methyl heptadecanoic acid
16-methyl margaric acid
16-methylheptadecanoic acid
isooctadecanoic acid
prisorine 3505
prisorine 3515
isostearicacid
ISOSTEARIC ACID
Isooctadecanoic acid
16-METHYLHEPTADECANOIC ACID
2724-58-5
30399-84-9
Prisorine 3509
Heptadecanoic acid, 16-methyl-
16-methyl margaric acid
16-methyl-heptadecanoic acid
LZM5XA0ILL
CHEBI:84896
(+)-Isostearic acid
UNII-LZM5XA0ILL
EINECS 220-336-3
16-methylmargaric acid
EMERSOL 873
SCHEMBL15489
CHEMBL1865303
DTXSID1040790
16-METHYLHEPTADECANOICACID
LMFA01020014
HY-W127433
NCGC00164392-01
NCGC00164392-02
NCGC00255115-01
AS-57253
CAS-30399-84-9
CS-0185665
Isostearic acid
16-Methylheptadecanoic acid
220-336-3
250-178-0
2724-58-5
30399-84-9
Heptadecanoic acid, 16-methyl-
Isooctadecanoic acid
MFCD00044082
MI3875000
X33R8U0062
(+)-isostearic acid
16-methyl margaric acid
16-methyl-heptadecanoic acid
16-methylmargaric acid
2-methyl-heptadecanoic acid
2-Methylheptadecanoic acid
Heptadecanoic acid, 2-methyl-
λ-Isostearic acid


ISOSTEARIC ACID
Empirical Formula (Hill Notation): C18H36O2
CAS Number: 2724-58-5
Molecular Weight: 284.48



APPLICATIONS


Isostearic acid (16-Methylheptadecanoic acid) is used in the synthesis of methyl-branched poly(hydroxyalkanoate)s, biosurfactants and silver nanoparticles.

Isostearic acid can be used as adhesion/cohesion promoter.
Further, Isostearic acid is used as coalescing agent.

In various industries, Isostearic acid can be used as emulsifier.

Isostearic acid can be used as chemical intermediate.
Furthermore, Isostearic acid is used in lubricants and lubricant additives
Isostearic acid is used as lubricating agent.

Isostearic acid is used in monomers.
Isostearic acid can be used as opacifer.

Isostearic acid can be used as softener and conditioner.
Further, Isostearic acid can be used as surface modifier.
Isostearic acid is used as surfactant (surface active agent).

Isostearic acid is used as swelling agent.
More to that, Isostearic acid can be used as coalescing agent.
Isostearic acid can be used as emulsifier.

Isostearic acid can be used as lubricating agent.
Moreover, Isostearic acid can be used as thickening agent.
Isostearic acid has industrial applications for the stabilisation of pigments mineral particles in oils and solvents.

Being a fatty acid, Isostearic acid is also amphiphilic, meaning it is a molecule with a hydrophobic end and a hydrophilic end.
As such, Isostearic acid can have favorable interactions with both polar and non-polar molecules, enabling it to act as a surfactant.

Isostearic acid is also soluble in many oils, which allows it to be used as an emulsifier or dispersant.
With this set of properties, Isostearic acid is a useful additive in a variety of applications.

Isostearic acid can be used as adhesives.
Moreover, Isostearic acid is used as coatings and paints.

Isostearic acid can be used as finishing agents.
Further, Isostearic acid can be used as lubricants.
Isostearic acid is used as sealants.

Isostearic acid can be used as solvents.
More to that, Isostearic acid is used as surfactants.
Isostearic acid is used as viscosity adjusters.

Isostearic acid is derived from renewable sources, offering unique characteristics such as high oxidation resistance and excellent cold temperature properties.
Applications of Isostearic acid include additives or base stock for the fuel and lubricants industry and emollients for personal care.

Isostearic acid is an exceptionally mild liquid fatty acid that offers a light lubricious feel and can be used in many skin care and colour cosmetic applications.
Furthermore, Isostearic acid also offers film forming properties, making it ideal for use in soaps, shaving foams and liquid cleansers.

Isostearic acid is used in bath, shower & soaps
Moreover, Isostearic acid is used in antiperspirants & deodorants

Isostearic acid is used in after sun products
Further, Isostearic acid is used in body care products
Isostearic acid is used for face / neck skin care

Isostearic acid is used for face colour products
Furthermore, Isostearic acid is used for hair colour products
Isostearic acid can be used for lip colour products

Isostearic acid can be used for shaving / hair removal products
More to that, Isostearic acid can be used for sun protection products
Isostearic acid is a lightly-branched, liquid fatty acid produced by the reaction of oleic acid with a natural mineral catalyst there is no chemical addition in this reaction, isostearic acid is based 100% on the parent oil or fat.

Isostearic acid is used in applications which require a liquid fatty acid with exceptional stability:

Thermal stability in the case of a lubricant
Odour stability for a cosmetic formulation
Oxidation stability for products with long shelf-life requirements

The branching structure of Isostearic acid also enhances its dispersing power, and it is used in cosmetic and industrial applications for the stabilisation of pigments and mineral particles in oils and solvents.
Super Refined Isostearic Acid is a vegetable-derived liquid fatty acid that offers a light lubricious skin feel, preventing a dry afterfeel from topical products.

Isostearic acid promotes low viscosity for good spreading and acts as a cleansing agent, emollient and superfatting agent and is compatible with cold processing.
Recommended topical usage levels of Isostearic Acid is 0.5-5%.

Isostearic acid is a useful synthetic intermediate.
Further, Isostearic acid is used in the synthesis of methyl-branched poly(hydroxyalkanoate)s, biosurfactants and silver nanoparticles.

Isostearic acid (16-Methylheptadecanoic acid) is used in the synthesis of methyl-branched poly(hydroxyalkanoate)s, biosurfactants and silver nanoparticles.



DESCRIPTION


Isostearic acid is a methyl-branched fatty acid that is heptadecanoic acid (margaric acid) substituted by a methyl group at position 16.
Further, Isostearic acid is a branched-chain saturated fatty acid, a long-chain fatty acid and a methyl-branched fatty acid.

Isostearic acid is functionally related to a heptadecanoic acid.

Isostearic acid is a lightly-branched, liquid fatty acid produced by the reaction of oleic acid with a natural mineral catalyst – there is no chemical addition in this reaction, isostearic acid is based 100% on the parent oil or fat.
Moreover, Isostearic acid is used in applications which require a liquid fatty acid with exceptional stability. Isostearic acid has thermal stability in the case of a lubricant.
Isostearic acid has odour stability for a cosmetic formulation.

Isostearic acid has oxidation stability for products with long shelf-life requirements.
The branching structure of Isostearic acid also enhances its dispersing power, and it is used in cosmetic and industrial applications for the stabilisation of pigments and mineral particles in oils and solvents.

Isostearic acid is a fatty acid molecule with an 18-carbon atom chain backbone.
Furthermore, Isostearic acid is an isomer of stearic acid, meaning that they both have a chemical formula of C18H36O2, but differ in the arrangement of their atoms.
While stearic acid has a linear carbon chain with 18 carbon atoms, Isostearic acid as a carbon chain with 17 atoms and a single carbon branch at the 16th carbon atom.

The chemical structure of Isostearic acid can be represented as (CH3)2CH(CH2)14CO2H.
Isostearic acid is found naturally in meat products and vegetable oils.

Isostearic acid has a wide range of industrial uses.
More to that, Isostearic acid is mainly used as an additive in adhesives or lubricants for both paints and personal care products.

The slight structural difference between Isostearic acid and its isomer, stearic acid, changes the physical state at room temperature and pressure.
Although stearic acid is solid, Isostearic acid is a clear yellow liquid.

This is because the branching nature of Isostearic acid’s carbon chain makes the molecules unable to pack as efficiently in the solid state as in the non-branching stearic acid.
Less efficient packing of Isostearic acid relatively lowers the melting point.

Some other basic properties of Isostearic acid include:

Molecular mass: 284.48 g/mol
Density (at 25°C): 0.89 g/cm3

Being a fatty acid, Isostearic acid is also amphiphilic, meaning it is a molecule with a hydrophobic end and a hydrophilic end.
As such, Isostearic acid can have favorable interactions with both polar and non-polar molecules, enabling it to act as a surfactant.

Isostearic acid is also soluble in many oils, which allows it to be used as an emulsifier or dispersant.

With this set of properties, Isostearic acid is a useful additive in a variety of applications, including:

Adhesives
Coatings and paints
Finishing agents
Lubricants
Sealants
Solvents
Surfactants
Viscosity adjusters

Isostearic acid differs from other C18 fatty acids of the same category in a number of ways.
While other C18 fatty acids are produced by splitting fats or oils, Isostearic acid is manufactured as a coproductof a tightly controlled reaction to synthesize dimerized fatty acids.
The structural makeup of Isostearic acid also has a valuable combination of saturation and branching, when compared to other fatty acids like stearic acid and oleic acid.

This set of features make Isostearic acid a versatile building block for high-value applications in synthetic lubricants, metal stamping and forming, coatings, and personal care products.
Isostearic acid’s features impart thermal stability, oxidative stability, surface activity, lubricity, low color, and feel in multiple formulations.
Isostearic acid is used as-is in some cases, but is also derivatized to form isostearyl alcohols, amides, and esters to further expand its reach across many industries and applications.

Take a closer look at some of the applications for Isostearic acid produced from tall oil fatty acid (TOFA):

Synthetic lubricants – Isostearate ester base oils with good thermal and oxidative stability
Lubricant additives – As-is and derivatized to isostearyl amide to provide boundary lubrication and detergency
Coatings – Impart flexibility and durability properties to industrial coatings
Metalworking – Good surface activity for protective coatings and thermal stability for rolling and stamping
Personal care products – As-is and derivatized to isostearyl alcohol to impart feel and texture to creams and lotions.

Isostearic acid offers a powerful combination of performance, renewability, steady supply, and short lead times, from a domestic producer.
Furthermore, Isostearic acid is our unique, highly branched, saturated fatty acid.

Isostearic acid has some features that are transparent and odorless, unlike straight chain fatty acids. Additionally, Isostearic acid has excellent heat stability, oxidation resistance, pigment dispensing ability, defoaming property and is compatible with various organic solvents.

Isostearic acid is a liquid fatty acid created from oleic acid.
More to that, Isostearic acid is claimed to have great odour, thermal and oxidation stability and is great for the stabilization of pigments and mineral particles in oils and solvents.
Isostearic acid is quite popular in foundations.



PROPERTIES


Form: powder
Functional group: carboxylic acid
Storage temp.: 2-8°C
Molecular Weight: 284.5
XLogP3: 7.2
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 2
Rotatable Bond Count: 15
Exact Mass: 284.271530387
Monoisotopic Mass: 284.271530387
Topological Polar Surface Area: 37.3 Ų
Heavy Atom Count: 20
Formal Charge: 0
Complexity: 212
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
Acid Value, mgKOH/g: 180 to 195
Relative Density, @d20/20: 0.881
Viscosity, C.P.S, @25°C: 35 to 60
Saponification Value: 190 to 200
Iodine Value, gI2/100g: 15 max
Cloud Point, °C: 10 max



FIRST AID


If inhaled:

If breathed in, move person into fresh air.
If not breathing, give artificial respiration.

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



HANDLING AND STORAGE


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.

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 stability:

Recommended storage temperature: 2 - 8 °C
Storage class (TRGS 510): 13: Non Combustible Solids

Storage:

Containers of Isostearic acid may be hazardous when empty since they retain product residues (vapors, liquid).
Do not store Isostearic acid at a temperature exceeding 80 °c.

Observe all warnings and precautions listed for Isostearic acid.
Outside or detached storage is recommended.
Polymerization or oxidation of the unsaturated bonds may occur.

Store Isostearic acid in a dry, cool, well-ventilated area.
Store Isostearic acid in the dark.
Use only containers, joints, pipes, etc., made in a material suitable for use with fatty acids.



SYNONYMS


ISOSTEARIC ACID
Isooctadecanoic acid
heptadecanoic acid, 16-methyl-
jaric I-18CG
jaric I-18IG
jaric I-18LG
liponate ISA
16-methyl heptadecanoic acid
16-methyl margaric acid
16-methylheptadecanoic acid
isooctadecanoic acid
prisorine 3505
prisorine 3515
isostearicacid
16-METHYLHEPTADECANOIC ACID
2724-58-5
30399-84-9
Prisorine 3509
Heptadecanoic acid, 16-methyl-
16-methyl margaric acid
16-methyl-heptadecanoic acid
16-methyl-heptadecanoicaci
Heptadedecanoicacid,16-Methyl
isostearic
ISOSTEARIC ACID
ISOOCTADECANOIC ACID
ISOSTEARIC ACID MIXED ISOMERS
16-METHYLHEPTADECANOIC ACID
Heptadecanoic acid, 16-methyl-
LZM5XA0ILL
Isostearic acid
16-Methylheptadecanoic acid [ACD/IUPAC Name]
16-Methylheptadecansäure [German] [ACD/IUPAC Name]
220-336-3 [EINECS]
250-178-0 [EINECS]
2724-58-5 [RN]
30399-84-9 [RN]
Acide 16-méthylheptadécanoïque [French] [ACD/IUPAC Name]
Heptadecanoic acid, 16-methyl- [ACD/Index Name]
Isooctadecanoic acid
MFCD00044082 [MDL number]
MI3875000
X33R8U0062
(+)-isostearic acid
16-methyl margaric acid
16-methyl-heptadecanoic acid
16-methylmargaric acid
2-methyl-heptadecanoic acid
2-Methylheptadecanoic acid
Heptadecanoic acid, 2-methyl-
λ-Isostearic acid
CHEBI:84896
(+)-Isostearic acid
UNII-LZM5XA0ILL
EINECS 220-336-3
16-methylmargaric acid
DSSTox_CID_7963
EMERSOL 873
DSSTox_RID_78624
DSSTox_GSID_27963
SCHEMBL15489
CHEMBL1865303
DTXSID1040790
16-METHYLHEPTADECANOICACID
ZINC4556536
Tox21_302276
LMFA01020014
HY-W127433
NCGC00164392-01
NCGC00164392-02
NCGC00255115-01
AS-57253
Isostearic acid, >=97% (capillary GC)
CAS-30399-84-9
CS-0185665
C20356
D92986
J-016709
W-109211
Q27158161
16-Methylheptadecanoic acid





ISOSTEARIC ACID (ISAC)

Isostearic acid (ISAC) is a type of fatty acid that is derived from the isomerization of oleic acid.
Oleic acid is a monounsaturated omega-9 fatty acid commonly found in various vegetable oils.
Isostearic acid (ISAC) undergoes a process called isomerization, which changes its molecular structure.

CAS Number: 30399-84-9
EC Number: 250-178-0

Isostearic acid, Branched stearic acid, Isomerized oleic acid, Oleic acid isomers, Modified stearic acid, Isostearate, Oleate isomers, Branched-chain fatty acid, Isomerized fatty acid, Oleic acid derivatives, Isomeric stearate, Modified oleic acid, Altered stearic acid, Isomerized triglyceride, Oleate mixture, Isostearic acid blend, Isomeric lipid, Branched-chain triglyceride, Oleic acid analogs, Isomer-rich fatty acid, Oleic acid isomerization product, Altered lipid chain, Modified triglyceride, Isomer-enriched stearate, Oleate derivative, Branched fatty acid chain, Isostearic acid complex, Oleic acid structural variant, Isomerized lipid fraction, Altered stearate ester, Isostearate blend, Oleic acid homologs, Branched-chain lipid, Isomeric triglyceride, Oleate complex, Isomer-rich fatty acid blend, Modified oleate, Altered fatty acid chain, Isomerized stearate ester, Oleic acid isomer blend, Branched stearate derivative, Isostearic triglyceride, Oleate isomer mixture, Isomeric fatty acid complex, Modified stearate ester, Altered triglyceride, Isomer-enriched oleate, Oleic acid analog mixture, Branched-chain stearate, Isostearate homologs, Oleate structural variant, Isomerized fatty acid blend, Altered lipid ester, Modified oleic acid fraction, Isomer-rich stearate, Oleic acid isomer fraction, Branched triglyceride, Isostearate isomer blend



APPLICATIONS


Isostearic acid (ISAC) is commonly used in the cosmetic industry for its emollient properties, contributing to the smooth and moisturizing feel of skincare products.
In the formulation of lip balms and lipsticks, isostearic acid enhances product texture and aids in providing a comfortable application.
The altered molecular structure of isostearic acid makes it a valuable ingredient in sunscreen formulations, improving the spreadability and feel of the product on the skin.

Isostearic acid (ISAC) is utilized in the production of emulsions and creams, where its compatibility with other ingredients enhances stability and texture.
Skincare lotions often contain isostearic acid to provide a silky and non-greasy finish upon application.
Isostearic acid is employed in the development of high-quality facial creams, contributing to their luxurious texture and moisturizing capabilities.

The lubricating properties of isostearic acid make it suitable for certain industrial applications, including in the production of lubricants and specialty oils.
Hair care products such as conditioners and styling creams may incorporate isostearic acid to improve manageability and provide a soft touch.

Isostearic acid (ISAC) finds use in the pharmaceutical industry for its role in formulating topical medications, contributing to their skin-friendly properties.
Deodorants and antiperspirants benefit from the addition of isostearic acid, enhancing the product's glide during application.

Isostearic acid (ISAC) is utilized in the creation of high-performance foundations and concealers, contributing to their blendability and long-lasting wear.
The modified triglyceride composition of isostearic acid makes it a suitable ingredient in the production of bath oils and shower gels, providing a pleasant skin-feel.

Isostearic acid (ISAC) contributes to the stability of cosmetic emulsions, preventing phase separation and ensuring a consistent product texture.
Moisturizing body lotions often contain isostearic acid to impart a soft and velvety feel to the skin.

Isostearic acid (ISAC) is incorporated into makeup primers to enhance the smooth application and adherence of subsequent cosmetic products.
The versatile nature of isostearic acid makes it suitable for use in a variety of personal care formulations, from hand creams to body butters.
Sunscreen sprays benefit from the addition of isostearic acid, which helps disperse the active ingredients evenly for optimal sun protection.

Isostearic acid (ISAC) is employed in the production of massage oils, contributing to their glide and overall skin-friendly properties.
The compatibility of isostearic acid with a range of ingredients makes it a preferred choice in the formulation of anti-aging creams and serums.

Isostearic acid (ISAC) is utilized in the creation of hydrating facial mists, providing a refreshing and moisturizing experience.
Certain cosmetic powders, such as setting powders and blushes, may contain isostearic acid to improve adherence to the skin.

Isostearic acid (ISAC) contributes to the development of long-wearing and transfer-resistant cosmetic products, including lipsticks and eyeliners.
Isostearic acid (ISAC) is a key component in the formulation of cuticle creams and nail care products, promoting nail health and hydration.

Isostearic acid (ISAC) is used in the production of specialty soaps, contributing to their lathering properties and skin-feel.
The application of isostearic acid extends beyond cosmetics, finding use in various industrial and pharmaceutical formulations due to its unique chemical properties.

Isostearic acid (ISAC) is employed in the textile industry as a lubricating agent during the processing of fibers, enhancing their smoothness.
Leather conditioners often contain isostearic acid to impart suppleness and a soft touch to leather goods.
Isostearic acid (ISAC) is utilized in the production of adhesive formulations, contributing to the adhesive's viscosity and tackiness.

Certain industrial coatings and paints may incorporate isostearic acid to improve the flow and leveling properties of the coating.
Isostearic acid (ISAC) is used in the creation of specialty inks, enhancing their compatibility with various printing processes.
The water-resistant properties of isostearic acid make it valuable in the formulation of waterproof coatings for outdoor fabrics.

Isostearic acid (ISAC) is applied in the manufacturing of candles, contributing to the even burning and smooth texture of the wax.
Some food products utilize isostearic acid as a food-grade lubricant, especially in the production of confectionery items.

Isostearic acid (ISAC) finds use in the development of rust preventatives and corrosion inhibitors for metal surfaces.
In the production of anti-fogging agents for eyewear and mirrors, isostearic acid contributes to the prevention of condensation.

Isostearic acid (ISAC) is employed in the creation of specialty detergents and cleaning formulations for its surfactant properties.
The film-forming characteristics of isostearic acid make it a valuable component in certain cosmetic products, such as mascaras.

Isostearic acid (ISAC) is used in the formulation of biodegradable lubricants, contributing to environmentally friendly industrial applications.
In the manufacturing of candles, isostearic acid aids in controlling the melting point and improving the overall burn quality.

Isostearic acid (ISAC) is applied in the production of mold-release agents, facilitating the release of molded products from molds.
Certain polymer formulations incorporate isostearic acid to modify the rheological properties and improve processing.

Isostearic acid (ISAC) is utilized in the creation of specialty waxes, contributing to their hardness and melting characteristics.
The water-repellent nature of isostearic acid makes it valuable in the formulation of water-resistant coatings for paper and cardboard.

Isostearic acid (ISAC) is employed in the creation of personal lubricants for its smooth and non-irritating properties.
The solubility of isostearic acid in various solvents makes it suitable for use in the formulation of inkjet printing inks.

Isostearic acid (ISAC) is used in the production of metalworking fluids, providing lubrication and cooling properties during machining.
In the textile industry, isostearic acid is applied as a softening agent for fabrics to enhance their feel and drape.

Isostearic acid (ISAC) is utilized in the formulation of biodegradable hydraulic fluids for certain industrial applications.
The low-temperature properties of isostearic acid make it suitable for use in the creation of cold-weather lubricants.
Isostearic acid (ISAC) is applied in the development of specialty coatings for electronic components, providing protection against environmental factors.

Isostearic acid (ISAC) is utilized in the production of biodegradable and eco-friendly lubricants, reducing environmental impact.
Isostearic acid (ISAC)'s ability to enhance the stability of formulations makes it valuable in the creation of long-lasting perfumes.
The modified structure of isostearic acid contributes to its use in the production of bio-based plastics.

Isostearic acid (ISAC) finds application in the development of specialty greases for specific industrial machinery.
In the pharmaceutical industry, isostearic acid is used as an excipient in the formulation of certain drug delivery systems.

Isostearic acid (ISAC) is incorporated into the production of candle wax melts, enhancing their fragrance release and texture.
The water-repellent properties of isostearic acid make it useful in the formulation of water-resistant wood finishes.

Isostearic acid (ISAC) is employed in the creation of biodegradable hydraulic fluids, particularly in environmentally sensitive areas.
The lubricating qualities of isostearic acid find application in the production of wire drawing compounds for metalworking processes.
Isostearic acid (ISAC) is used as a key component in the manufacturing of eco-friendly, biodegradable detergents.
Isostearic acid (ISAC) contributes to the formulation of environmentally conscious and sustainable personal care products.

Isostearic acid (ISAC) is employed in the creation of non-toxic, bio-based ink formulations for printing applications.
The compatibility of isostearic acid with various polymers makes it valuable in the production of bio-based polymer blends.

Isostearic acid (ISAC) is used in the formulation of biodegradable cutting fluids for metal machining processes.
Isostearic acid is applied in the creation of eco-friendly textile softeners, reducing environmental impact.
The modified triglyceride composition of isostearic acid makes it suitable for use in the production of eco-friendly soap bases.

Isostearic acid (ISAC) contributes to the formulation of biodegradable and sustainable industrial cleaners.
Isostearic acid (ISAC) is used in the development of environmentally friendly, biodegradable paint additives.
The compatibility of isostearic acid with various solvents makes it useful in the creation of bio-based ink formulations.

Isostearic acid (ISAC) is employed in the production of bio-based, sustainable anti-corrosion coatings for metals.
Isostearic acid (ISAC) finds application in the creation of bio-based and eco-friendly release agents for molded products.
The altered molecular structure of isostearic acid makes it valuable in the production of sustainable and biodegradable plasticizers.

Isostearic acid (ISAC) is used in the formulation of bio-based and environmentally friendly metalworking coolants.
Isostearic acid (ISAC) contributes to the development of bio-based and eco-friendly drilling fluids for certain industrial applications.
The versatility of isostearic acid extends to the production of sustainable and biodegradable lubricating oils for various machinery.



DESCRIPTION


Isostearic acid (ISAC) is a type of fatty acid that is derived from the isomerization of oleic acid.
Oleic acid is a monounsaturated omega-9 fatty acid commonly found in various vegetable oils.
Isostearic acid (ISAC) undergoes a process called isomerization, which changes its molecular structure.

The isomerization process results in a mixture of branched-chain isomers of stearic acid.
Stearic acid is a saturated fatty acid with an 18-carbon chain.
Isostearic acid, due to its branched structure, often exhibits different properties compared to its straight-chain counterparts.

Isostearic acid (ISAC) finds applications in the cosmetic and personal care industry, where it is used in the formulation of various products such as skin creams, lotions, and cosmetics.
Isostearic acid (ISAC) is valued for its emollient properties, providing moisturization and a smooth feel to the skin.
Additionally, Isostearic acid (ISAC) is used in the production of certain surfactants and lubricants.

Isostearic acid (ISAC) is a modified fatty acid derived from the isomerization of oleic acid.
The isomerized form of oleic acid gives rise to isostearic acid, featuring a branched molecular structure.
As a branched-chain fatty acid, Isostearic acid (ISAC) exhibits distinct chemical properties compared to its linear counterparts.

Isostearic acid (ISAC) is commonly used in cosmetic formulations for its emollient properties.
The isomerization process imparts unique characteristics to isostearic acid, making it suitable for various applications in the personal care industry.
Derived from natural sources, Isostearic acid (ISAC) is often employed as a key ingredient in skin creams and lotions.

Isostearic acid (ISAC) contributes to the smooth texture and moisturizing effects of skincare products.
The altered molecular structure of isostearic acid enhances its compatibility with skin and other cosmetic ingredients.
Isostearic acid (ISAC) is known for its ability to form stable emulsions in cosmetic formulations.
This fatty acid is widely utilized in the production of lip balms and lipsticks for its skin-conditioning benefits.

Isostearic acid (ISAC) plays a role in improving the spreadability and sensory feel of cosmetic products.
Due to its modified structure, isostearic acid exhibits unique solubility characteristics in various formulations.
In the personal care industry, isostearic acid is favored for its versatility in creating aesthetically pleasing textures.

Isostearic acid (ISAC) is a common component in formulations designed to enhance the stability and shelf life of cosmetic products.
The isomer-rich nature of isostearic acid contributes to its efficacy in diverse skincare formulations.

Isostearic acid (ISAC) is often included in makeup products to provide a smooth and velvety finish.
The branched structure of isostearic acid contributes to its lubricating properties, making it suitable for certain industrial applications.

Isostearic acid (ISAC) is valued for its ability to enhance the spreadability of emulsions and creams.
The modified lipid chain of isostearic acid makes it a sought-after ingredient for formulating high-quality skincare products.
Cosmetic products containing isostearic acid are known for their improved adherence to the skin.

Isostearic acid (ISAC) is utilized in the development of sunscreen formulations to enhance the product's texture and application.
The altered triglyceride composition of isostearic acid allows for precise control over the consistency of cosmetic formulations.

Isostearic acid (ISAC) is compatible with a variety of cosmetic ingredients, contributing to the formulation of well-balanced products.
The isomer-enriched blends of isostearic acid are often chosen for their ability to provide a luxurious feel in skincare products.
Isostearic acid (ISAC) continues to be a key ingredient in the cosmetic industry, contributing to the innovation and effectiveness of various personal care formulations.



PROPERTIES


Chemical Formula: The chemical formula for isostearic acid is C18H36O2.
Molecular Weight: The molecular weight of isostearic acid is approximately 284.48 g/mol.
Structural Formula: Isostearic acid is characterized by a branched molecular structure due to the isomerization of oleic acid.
Physical State: Isostearic acid is generally found in the form of a colorless to pale yellow liquid at room temperature.
Odor: Isostearic acid may have a mild, characteristic odor.
Melting Point: The melting point of isostearic acid is around 35-40°C.
Boiling Point: The boiling point of isostearic acid is typically higher than its melting point, around 220-230°C.
Solubility: Isostearic acid is generally insoluble in water but soluble in organic solvents such as ethanol and ether.
Density: The density of isostearic acid is approximately 0.86 g/cm³.
Viscosity: Isostearic acid exhibits a moderate viscosity, contributing to its use in various formulations.
Refractive Index: The refractive index of isostearic acid is around 1.44.
Flash Point: Isostearic acid has a flash point above its boiling point, making it non-flammable.
pH: Isostearic acid is not typically associated with a specific pH value as it is often used in formulations where pH is adjusted by other ingredients.
Chemical Stability: Isostearic acid is generally stable under normal storage conditions.
Compatibility: Isostearic acid is compatible with a variety of cosmetic and industrial ingredients.



FIRST AID


Inhalation:

Move to Fresh Air:
Immediately move the affected person to an area with fresh air.

Provide Respiratory Support:
If the person has difficulty breathing, administer artificial respiration or use available respiratory support equipment.

Seek Medical Attention:
Contact emergency medical services for further evaluation and treatment.


Skin Contact:

Remove Contaminated Clothing:
Quickly and gently remove any contaminated clothing, including shoes, and rinse the affected skin.

Flush with Water:
Wash the affected skin thoroughly with plenty of water for at least 15 minutes.

Use Mild Soap:
Use a mild soap to cleanse the skin while rinsing, if available.

Seek Medical Attention:
If irritation, redness, or other symptoms persist, seek medical attention promptly.


Eye Contact:

Flush Eyes with Water:
Immediately flush the eyes with a gentle stream of lukewarm water for at least 15 minutes.
Hold the eyelids open to ensure thorough rinsing.

Remove Contact Lenses:
If applicable, remove contact lenses during eye irrigation.

Seek Medical Attention:
Obtain prompt medical attention, even if the person feels relief, as further evaluation is essential.
Ingestion:

Do NOT Induce Vomiting:
Do not induce vomiting unless instructed to do so by medical professionals.

Rinse Mouth:
If the substance is swallowed, rinse the mouth with water.

Seek Medical Attention:
Contact emergency medical services or a poison control center for guidance and seek medical attention immediately.


General Advice:

Personal Protection:
Always wear appropriate personal protective equipment (PPE) when handling isostearic acid to prevent exposure.

Medical Attention:
Seek medical attention promptly for any signs of adverse effects, even if they appear minor.

Note to Healthcare Providers:
Provide healthcare providers with information about the substance for accurate diagnosis and treatment.



HANDLING AND STORAGE


Handling:

Personal Protective Equipment (PPE):
Always wear appropriate PPE, including gloves, protective eyewear, and suitable clothing, when handling isostearic acid.

Ventilation:
Work in a well-ventilated area or use local exhaust ventilation to minimize inhalation exposure.
Ensure adequate ventilation in confined spaces.

Avoid Contact:
Avoid skin and eye contact with isostearic acid.
In case of contact, follow the recommended first aid measures promptly.

Hygiene Practices:
Implement good hygiene practices, including regular hand washing, to prevent unintentional exposure.

Prevent Ingestion:
Avoid eating, drinking, or smoking in areas where isostearic acid is handled to prevent accidental ingestion.

Labeling:
Clearly label containers with the identity of the substance, relevant hazard information, and appropriate safety instructions.

Training:
Provide proper training to personnel handling isostearic acid, including information on potential hazards and proper emergency procedures.

Spill Response:
Have spill response procedures in place, including the use of absorbent materials and appropriate personal protective equipment.

Equipment Inspection:
Regularly inspect and maintain equipment used for handling isostearic acid to ensure proper functioning and prevent leaks.


Storage:

Storage Location:
Store isostearic acid in a cool, dry, and well-ventilated area, away from incompatible materials.

Temperature Control:
Keep storage temperatures within the recommended range to prevent product degradation or separation.

Avoid Sunlight:
Protect containers from direct sunlight or heat sources to prevent temperature fluctuations.

Separation:
If the isostearic acid is prone to separation, store it in a manner that allows for easy remixing if needed.

Container Integrity:
Ensure the integrity of storage containers to prevent leaks or spills.
Use containers made of compatible materials.

Segregation:
Segregate isostearic acid from incompatible materials, such as strong acids, bases, or oxidizing agents.

Fire Prevention:
Store away from ignition sources and follow fire prevention measures.

Controlled Access:
Restrict access to the storage area to authorized personnel only.

Emergency Equipment:
Keep emergency equipment, such as spill response kits and fire extinguishers, readily accessible.

Documentation:
Maintain proper documentation of storage conditions, including batch numbers, dates, and supplier information.

Compliance:
Adhere to local, regional, and national regulations regarding the storage of chemicals, including isostearic acid.
Isostearic acid
isostearic acid; steraric acid; ,isooctadecanoic acid; 16-METHYLHEPTADECANOIC ACID CAS NO: 2724-58-5
ISOSTEARYL ALCOHOL
cas no 27458-93-1 Isooctadecanol; 16-Methylheptadecan-1-ol; Isooctadecan-1-ol; Isooctadecyl alcohol; 1-Heptadecanol, 16-methyl-; Isooctadecylalcohol;
ISOSTEARYL GLYCOLATE
ISOSTEARYL LACTATE, N° CAS : 42131-28-2, Nom INCI : ISOSTEARYL LACTATE, Nom chimique : Isooctadecyl lactate, N° EINECS/ELINCS : 255-674-0 Compatible Bio (Référentiel COSMOS) Ses fonctions (INCI) Emollient : Adoucit et assouplit la peau Agent d'entretien de la peau : Maintient la peau en bon état
Isostearyl Isononate
Hexanoic acid, 3,5,5-trimethyl-, isooctadecyl ester CAS Number 90967-66-1
ISOSTEARYL ISOSTEARATE

Isostearyl isostearate is a chemical compound that belongs to the ester class.
Isostearyl isostearate is commonly used in the cosmetics and personal care industry as an emollient and skin-conditioning agent.
Isostearyl isostearate is derived from isostearyl alcohol and isostearic acid.
Isostearyl isostearate is known for its ability to improve the texture and feel of cosmetic products, providing a smooth and silky finish.

CAS Number: 41669-30-1
EC Number: 255-485-3

Isostearyl Isostearate, Isostearic Acid Isostearyl Ester, 2-Octyldodecyl Isostearate, Octyldodecyl Isostearate, Isostearyl Ester, Octyldodecyl Isostearate, Isostearate de 2-octyl-dodecyle, Octododecyl Isostearate, Isostearyl-2-octyldodecanoate, Isostearyl/Octyldodecyl Isostearate, Isostearyl Myristate, Isostearyl/Octyldodecyl Stearate, Isooctyl Isostearate, Isostearyl Alcohol Isostearic Acid Ester, 2-Octyldodecyl Isostearate, Isostearyl Isostearate Ester, Isostearyl Isostearate, Isooctyl Isostearate, Octododecyl Isostearate, Isostearyl Isostearate, Isostearate d'Isostearyl, Isostearyl Isostearate, Isooctyl Isostearate, Isostearate d'Isostearyl, 2-Octyldodecyl Isostearate, Isostearyl Isostearate Ester, Isostearate de 2-octyl-dodecyle, Isostearate d'Isostearyl, Isostearate de 2-octyl-dodecyle, Octododecyl Isostearate, Isostearyl Isostearate, Isostearate d'Isostearyl, Isostearyl Isostearate Ester, Octododecyl Isostearate, Isostearyl Ester, Isostearyl Isostearate, Isostearyl Isostearate Ester, Isostearate d'Isostearyl, Octyldodecyl Isostearate, Isostearyl Alcohol Isostearic Acid Ester, 2-Octyldodecyl Isostearate, Isostearate de 2-octyl-dodecyle, Isostearyl Isostearate Ester, Octododecyl Isostearate, Isostearyl/Octyldodecyl Stearate, Isostearyl Isostearate, Isooctyl Isostearate, Octododecyl Isostearate, 2-Octyldodecyl Isostearate, Isostearyl Alcohol Isostearic Acid Ester, Isostearyl Isostearate, Isostearyl Isostearate Ester, Isostearyl Isostearate, Isostearate de 2-octyl-dodecyle, Octyldodecyl Isostearate, Octyldodecyl Isostearate, Isostearyl Isostearate Ester, Isostearyl Ester, Isostearyl/Octyldodecyl Isostearate, 2-Octyldodecyl Isostearate, Octododecyl Isostearate, Isostearyl Isostearate, Isostearate d'Isostearyl.



APPLICATIONS


Isostearyl isostearate finds extensive use in cosmetic formulations as an emollient.
Isostearyl isostearate is commonly employed in skincare products such as creams and lotions for its skin-conditioning properties.
Isostearyl isostearate is a key ingredient in lip balms and lipsticks, contributing to their smooth and creamy textures.
Isostearyl isostearate is often included in foundations and concealers to enhance their spreadability and blendability.

In haircare products, this ester helps to condition and improve the texture of hair.
Its lubricating properties make it valuable in shaving creams, providing a smooth glide during shaving.
Isostearyl isostearate is used in sunscreens to enhance the even application and spread of the product.

Isostearyl isostearate is incorporated into anti-aging formulations for its moisturizing and skin-replenishing attributes.
Isostearyl isostearate is found in moisturizers, contributing to long-lasting hydration on the skin.
Isostearyl isostearate is utilized in cosmetic formulations for its ability to create a non-greasy finish.

In makeup products like eyeshadows and blushes, it aids in the even distribution and adherence to the skin.
Isostearyl isostearate is commonly present in body lotions, offering a luxurious and silky feel upon application.
Isostearyl isostearate is suitable for use in sensitive skin products due to its gentle nature.
Isostearyl isostearate is employed in skincare serums to enhance the delivery and absorption of active ingredients.

Isostearyl isostearate is used in deodorants for its skin-friendly and non-irritating characteristics.
Isostearyl isostearate is included in cosmetic formulations to improve the overall sensory experience.
Isostearyl isostearate contributes to the stability of emulsions and helps prevent the separation of oil and water phases.
Isostearyl isostearate is utilized in hair styling products to provide a smooth and manageable finish.

Isostearyl isostearate is a valuable component in waterproof makeup formulations, enhancing their durability.
In sunscreen formulations, it aids in the dispersion of UV filters and improves their efficacy.
Isostearyl isostearate is incorporated into facial cleansers and makeup removers for its gentle cleansing properties.
Isostearyl isostearate is used in baby care products such as diaper creams for its skin-soothing qualities.
Isostearyl isostearate is employed in cosmetic products for mature skin to address dryness and promote suppleness.

Isostearyl isostearate is utilized in body scrubs and exfoliating products to enhance their texture.
Isostearyl isostearate is versatile and compatible with various cosmetic ingredients, making it suitable for a wide range of applications.

Isostearyl isostearate serves as a key component in the formulation of facial masks, contributing to their smooth application and removal.
Isostearyl isostearate is commonly included in hand creams and lotions to provide a soft and moisturized feel to the skin.
Isostearyl isostearate is used in cosmetic primers to create a smooth base for makeup application.

Isostearyl isostearate is incorporated into body washes and shower gels to enhance their emollient properties.
In tinted moisturizers and BB creams, it helps achieve a natural and even coverage on the skin.

Isostearyl isostearate is utilized in cosmetic formulations for men's grooming products, such as aftershave lotions.
Isostearyl isostearate is found in anti-chafing products, contributing to friction reduction in sensitive areas.
Isostearyl isostearate is used in cuticle creams and nail care formulations to improve the texture and appearance of nails.

Isostearyl isostearate is employed in cosmetic powders to enhance the blending and adherence to the skin.
Isostearyl isostearate is utilized in massage oils, providing a smooth and gliding texture during massage.

In cosmetic sticks like lip balms and solid perfumes, it contributes to their easy and precise application.
Isostearyl isostearate is included in mattifying products to control excess shine on the skin's surface.
Isostearyl isostearate is used in cosmetic wipes and towelettes for its gentle and conditioning properties.

Isostearyl isostearate is a common ingredient in overnight masks and sleeping packs to promote skin hydration.
Isostearyl isostearate is found in body oils, contributing to their lightweight and non-greasy texture.
Isostearyl isostearate is utilized in cosmetic formulations for its role in improving the spreadability of pigments.

Isostearyl isostearate is included in cosmetic serums for its ability to create a smooth and velvety skin feel.
Isostearyl isostearate is found in cosmetic emulsions, helping to stabilize the mixture of water and oil components.
Isostearyl isostearate is incorporated into sunless tanning products for a streak-free and even application.
Isostearyl isostearate is used in cosmetic formulations for acne-prone skin due to its non-comedogenic nature.

Isostearyl isostearate is present in cosmetic mousse formulations, contributing to their lightweight and airy texture.
Isostearyl isostearate is used in cosmetic sticks for contouring and highlighting to ensure easy blending.
Isostearyl isostearate is included in cosmetic products for tattoo care to maintain skin suppleness and prevent dryness.

Isostearyl isostearate is utilized in cosmetic products for individuals with eczema or sensitive skin conditions.
Isostearyl isostearate is employed in cosmetic formulations for its role in enhancing the overall aesthetics and user experience of the product.

Isostearyl isostearate is commonly used in cosmetic sunscreens to improve the even distribution and application of UV filters.
Isostearyl isostearate is included in cosmetic foundations to enhance the blendability and longevity of makeup.
Isostearyl isostearate is found in tinted lip balms, contributing to both color and moisturization.

Isostearyl isostearate is utilized in hair serums to add shine and manageability to the hair.
In hand sanitizers, it can serve as a conditioning agent to counteract the drying effects of alcohol.
Isostearyl isostearate is employed in cosmetic primers for its ability to create a smooth canvas for makeup application.

Isostearyl isostearate is used in cosmetic setting sprays to improve the setting and longevity of makeup.
Isostearyl isostearate is included in cosmetic concealers to enhance the smooth application and coverage of imperfections.
Isostearyl isostearate is utilized in facial cleansers and makeup removers for its gentle cleansing properties.
Isostearyl isostearate is found in cosmetic sheet masks to improve adherence and comfort during use.

Isostearyl isostearate is incorporated into cosmetic stick foundations for easy and convenient application.
Isostearyl isostearate is utilized in cosmetic lip glosses for a glossy finish without a sticky feel.
Isostearyl isostearate is included in cosmetic highlighters for a smooth and radiant application.

Isostearyl isostearate is found in cosmetic blushes and bronzers to enhance the blending and application on the skin.
In cosmetic eye creams, the compound contributes to a silky and moisturizing texture.
Isostearyl isostearate is used in cosmetic setting powders to improve their adherence to the skin.

Isostearyl isostearate is included in cosmetic body scrubs to enhance the spreadability and skin-feel during exfoliation.
Isostearyl isostearate is found in cosmetic body lotions for a luxurious and smooth application on the skin.
Isostearyl isostearate is employed in cosmetic CC creams for color correction and moisturization.
Isostearyl isostearate is included in cosmetic gel formulations for a lightweight and refreshing application.

Isostearyl isostearate is used in cosmetic water-based formulations for its compatibility with aqueous solutions.
Isostearyl isostearate is found in cosmetic fragrance-free products for those with sensitivities.
Isostearyl isostearate is incorporated into cosmetic hair masks for its conditioning and detangling properties.

Isostearyl isostearate is utilized in cosmetic body washes for a rich and moisturizing lather.
Isostearyl isostearate is included in cosmetic body mists for a lightweight and hydrating application.

Isostearyl isostearate plays a crucial role in cosmetic BB creams, contributing to their lightweight texture and coverage.
Isostearyl isostearate is commonly utilized in cosmetic body butters for a rich and nourishing feel on the skin.

Isostearyl isostearate is included in cosmetic gel-based masks for its smooth and cooling application.
Isostearyl isostearate is found in cosmetic primer oils, enhancing the hydration and adherence of makeup.

In cosmetic body scrubs, it aids in providing a soft and exfoliating experience during use.
Isostearyl isostearate is utilized in cosmetic body balms, offering intensive moisturization and a non-greasy finish.
Isostearyl isostearate is included in cosmetic body serums to enhance skin texture and suppleness.
Isostearyl isostearate plays a role in cosmetic dry shampoo formulations, contributing to easy application and absorption.

Isostearyl isostearate is employed in cosmetic cuticle oils for its moisturizing and conditioning properties.
Isostearyl isostearate is found in cosmetic anti-frizz hair products to improve manageability and shine.

Isostearyl isostearate is utilized in cosmetic cleansing balms for a luxurious and effective makeup removal experience.
Isostearyl isostearate is included in cosmetic body powders for a smooth and velvety feel on the skin.
Isostearyl isostearate plays a part in cosmetic body wash oils, providing a gentle and moisturizing cleanse.
Isostearyl isostearate is commonly used in cosmetic hair styling creams for a soft and touchable hold.

In cosmetic depilatory creams, it contributes to a smooth and comfortable hair removal process.
Isostearyl isostearate is found in cosmetic foot creams, offering hydration and relief for dry skin.
Isostearyl isostearate is utilized in cosmetic beard oils for its conditioning and non-greasy properties.
Isostearyl isostearate plays a role in cosmetic body bronzing lotions for an even and radiant application.
Isostearyl isostearate is included in cosmetic hand masks for a rejuvenating and moisturizing effect.

Isostearyl isostearate is commonly used in cosmetic cuticle creams to improve the overall health and appearance of nails.
Isostearyl isostearate is found in cosmetic hair glosses, adding shine and a polished finish to the hair.
Isostearyl isostearate is utilized in cosmetic under-eye creams for a smooth and hydrating application.
In cosmetic massage lotions, it contributes to a glideable and nourishing massage experience.

Isostearyl isostearate is included in cosmetic pre-shave oils for a smooth and comfortable shaving process.
Isostearyl isostearate plays a role in cosmetic fragrance-free products, providing a neutral base for formulations.



DESCRIPTION


Isostearyl isostearate is a chemical compound that belongs to the ester class.
Isostearyl isostearate is commonly used in the cosmetics and personal care industry as an emollient and skin-conditioning agent.
Isostearyl isostearate is derived from isostearyl alcohol and isostearic acid.
Isostearyl isostearate is known for its ability to improve the texture and feel of cosmetic products, providing a smooth and silky finish.

Isostearyl isostearate is a versatile ester widely used in the cosmetics industry.
This compound, derived from isostearyl alcohol and isostearic acid, serves as an effective emollient.
Isostearyl isostearate is known for its skin-conditioning properties, leaving a smooth and silky texture.

As a cosmetic ingredient, it enhances the spreadability and application of various products.
With its emollient nature, it helps improve the overall feel of skincare and haircare formulations.
Isostearyl isostearate acts as a lubricant, contributing to the ease of product application on the skin.

Isostearyl isostearate is particularly valued for its ability to provide a non-greasy, lightweight finish.
In skincare products, it aids in moisturizing and maintaining skin hydration.

Isostearyl isostearate is often included in lip balms and lipsticks for its smoothing effect.
Its compatibility with other cosmetic ingredients makes it a popular choice for formulators.
Isostearyl isostearate contributes to the long-lasting wear of makeup products, such as foundations and powders.

Isostearyl isostearate is well-tolerated by many skin types and is suitable for sensitive skin.
In haircare products, it helps to condition and improve the manageability of hair strands.
Its molecular structure imparts a luxurious and silky feel when incorporated into beauty formulations.
Isostearyl isostearate's moisturizing properties make it beneficial for dry and dehydrated skin conditions.

Isostearyl isostearate enhances the sensory experience of skincare and cosmetic applications.
Its non-comedogenic nature makes it suitable for use in products for individuals prone to acne.
Isostearyl isostearate contributes to the stability and shelf life of cosmetic formulations.

Isostearyl isostearate is often found in creams, lotions, and moisturizers for its skin-loving qualities.
Its film-forming characteristics help create a protective barrier on the skin's surface.

Isostearyl isostearate is transparent and colorless, making it suitable for a wide range of cosmetic products.
Isostearyl isostearate is eco-friendly and biodegradable, aligning with sustainability goals in the industry.
Isostearyl isostearate is odorless, making it ideal for products where fragrance is not desired.

Isostearyl isostearate is synthesized through a controlled process to ensure high purity and quality.
Its compatibility with various active ingredients makes it a versatile component in skincare formulations.



PROPERTIES


Melting Point: 50-55°C
pH: Neutral
Solubility: Insoluble in water
Viscosity: Low
Molecular Weight: 537.0 g/mol
XLogP3-AA: 16.8
Hydrogen Bond Donor Count: 0
Hydrogen Bond Acceptor Count: 2
Rotatable Bond Count: 32
Exact Mass: 536.55323154 g/mol
Monoisotopic Mass: 536.55323154 g/mol
Topological Polar Surface Area: 26.3Ų
Heavy Atom Count: 38
Formal Charge: 0
Complexity: 456
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



FIRST AID


Inhalation:

If inhaled, move the affected person to fresh air.
Allow for rest and keep the individual comfortable.
Seek medical attention if respiratory irritation persists.


Skin Contact:

In case of skin contact, wash the affected area with plenty of soap and water.
Remove contaminated clothing.
Seek medical attention if irritation, redness, or other symptoms develop.


Eye Contact:

In case of contact with eyes, flush eyes with lukewarm water for at least 15 minutes, lifting upper and lower eyelids.
Seek medical attention if irritation persists.


Ingestion:

If isostearyl isostearate is accidentally ingested, do not induce vomiting.
Rinse the mouth with water.
Seek immediate medical attention or contact a poison control center.


General Advice:

If someone shows signs of irritation or an allergic reaction after exposure to isostearyl isostearate, remove the person from the source of exposure.
Provide comfort and reassurance.
In case of persistent symptoms or if there is uncertainty about the exposure, seek medical advice promptly.



HANDLING AND STORAGE


Handling Conditions:

Personal Protection:
Wear appropriate personal protective equipment (PPE), such as gloves and safety goggles, to prevent skin and eye contact.
Use protective clothing, including long sleeves and pants, to minimize skin exposure.

Ventilation:
Work in a well-ventilated area, or use local exhaust ventilation to control airborne concentrations.

Avoidance of Contact:
Avoid contact with eyes, skin, and clothing.
Do not ingest the substance.

Handling Equipment:
Use suitable handling equipment and tools to minimize direct contact with the chemical.

Hygiene Practices:
Wash hands thoroughly after handling isostearyl isostearate.
Do not eat, drink, or smoke while handling the chemical.

Preventive Measures:
Implement good industrial hygiene practices to minimize the risk of exposure.
Provide eye wash stations and safety showers in areas where the substance is handled.


Storage Conditions:

Storage Location:
Store isostearyl isostearate in a cool, dry, and well-ventilated area.

Temperature Control:
Keep the storage temperature within the specified range provided by the manufacturer.

Container Type:
Use containers made of materials compatible with isostearyl isostearate.
Consult the SDS for guidance.

Protection from Elements:
Protect the substance from direct sunlight and sources of heat.

Separation from Incompatibles:
Store isostearyl isostearate away from incompatible substances.
Check the SDS for information on substances that should be avoided.

Handling of Large Quantities:
If handling large quantities, use appropriate storage facilities with containment measures to prevent spills and leaks.

Labeling:
Ensure that storage containers are clearly labeled with the product name, hazard symbols, and other relevant information.

Security Measures:
Implement appropriate security measures to prevent unauthorized access to the storage area.

Emergency Response:
Have emergency response procedures in place, including spill cleanup measures and contact information for relevant authorities.
ISOSTEARYL ISOSTEARATE
ISOSTEARYL ISOSTEARATE ISOSTEARYL ISOSTEARATE ISOSTEARYL ISOSTEARATE is classified as : Binding Emollient Skin conditioning CAS Number 41669-30-1 EINECS/ELINCS No: 255-485-3 COSING REF No: 34765 Chem/IUPAC Name: Isooctadecyl isooctadecanoate Isostearyl Isostearate Isostearyl Isostearate is a fluid emollient for oils. It provides a rich feel and improves spreading on the skin. It is appropriate for use in lipsticks and as a binding agent for make-up powders. This product does not modify pigment coloration, and provides superfatting properties to compensate for the drying effect of powders Details An emollient ester (oily liquid from Isostearyl Alcohol + Isostearic Acid) that gives excellent slip, lubricity and luxurious softness on skin. It's also popular in makeup products to disperse pigments nicely and evenly. Molecular Weight of Isostearyl Isostearate 537 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) XLogP3-AA of Isostearyl Isostearate 16.8 Computed by XLogP3 3.0 (PubChem release 2019.06.18) Hydrogen Bond Donor Count of Isostearyl Isostearate 0 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Hydrogen Bond Acceptor Count of Isostearyl Isostearate 2 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Rotatable Bond Count of Isostearyl Isostearate 32 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Exact Mass of Isostearyl Isostearate 536.553232 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Monoisotopic Mass of Isostearyl Isostearate 536.553232 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Topological Polar Surface Area of Isostearyl Isostearate 26.3 Ų Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Heavy Atom Count of Isostearyl Isostearate 38 Computed by PubChem Formal Charge of Isostearyl Isostearate 0 Computed by PubChem Complexity of Isostearyl Isostearate 456 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Isotope Atom Count of Isostearyl Isostearate 0 Computed by PubChem Defined Atom Stereocenter Count of Isostearyl Isostearate 0 Computed by PubChem Undefined Atom Stereocenter Count of Isostearyl Isostearate 0 Computed by PubChem Defined Bond Stereocenter Count of Isostearyl Isostearate 0 Computed by PubChem Undefined Bond Stereocenter Count of Isostearyl Isostearate 0 Computed by PubChem Covalently-Bonded Unit Count of Isostearyl Isostearate 1 Computed by PubChem Compound of Isostearyl Isostearate Is Canonicalized Yes The stearate esters (Butyl Stearate, Cetyl Stearate, Isocetyl Stearate, Isopropyl Stearate, Myristyl Stearate, Ethylhexyl Stearate, Isobutyl Stearate) are oily liquids or waxy solids. Ethylhexyl Stearate may also be called Octyl Stearate. In cosmetics and personal care products, stearate esters are used most frequently in the formulation of eye makeup, skin makeup, lipstick and skin care products. Stearate esters act primarily as lubricants on the skin's surface, which gives the skin a soft and smooth appearance. Butyl Stearate also decreases the thickness of lipsticks, thereby lessening the drag on lips, and imparts water repelling characteristics to nail polishes. Butyl Stearate and Isopropyl Stearate dry to form a thin coating on the skin. Isocetyl Stearate can also be used to dissolve other substances, usually liquids. Function(s) of Isopropyl Stearate: Binder; Skin-Conditioning Agent - Emollient; BINDING; SKIN CONDITIONING Use restrictions of Isopropyl Stearate: Determined safe for use in cosmetics, subject to concentration or use limitations - Safe for use in cosmetics with some qualifications Irritation (skin, eyes, or lungs): Human irritant - strong evidence (only for products for use around the eyes, on the skin, or may be aerosolized (airborne)) GHS Hazard Statements of Isopropyl Stearate: Aggregated GHS information from 2 notifications provided by 23 companies to the ECHA C&L Inventory. H413 (100%): May cause long lasting harmful effects to aquatic life Information may vary between notifications depending on impurities, additives, and other factors. The percentage value in parenthesis indicates the notified classification ratio from all companies. Only Hazard Codes with percentage values above 10% are shown. Molecular Formula: C21H42O2 Molecular Weight: 326.565 g/mol IUPAC Name: propan-2-yl octadecanoate CAS: 112-10-7 EC Number: 203-934-9 Isostearyl Isostearate is a fluid emollient for oils. It provides a rich feel and improves spreading on the skin. It is appropriate for use in lipsticks and as a binding agent for make-up powders. This product does not modify pigment coloration, and provides superfatting properties to compensate for the drying effect of powders. Skincare ingredients: Isostearyl Isostearate What is Isostearyl isostearate? Great for: Emollient like jojoba oil with a virtually non-existent after-feel How it works: It provides a rich but non-greasy skin feel and improves spreading on the skin. It is often used in lipsticks and to bind together make-up powders. Where does isostearyl isostearate come from? Isostearyl isostearate is the ester (the product of an alcohol and an acid) of isosteric alcohol and isostearic acid. Isostearic acid is an isomer of stearic acid, a naturally-occurring fatty acid found in cocoa and shea butter. Isostearic acid and stearic acid have the same chemical formula, but the arrangement of their atoms vary slightly which gives it very different physical properties. For example, stearic acid is solid at room temperature and isostearic acid is clear yellow liquid. Formulation tips Undiluted Isopropyl Isostearate was classified as a slight ocular irritant but otherwise is considered very safe.
ISOSTEARYL LACTATE
SynonymsCMI;MCI;CMIT;IDAS;mci/mi;CMI/MIT;CMIT/MIT;KATHONFP;KATHONLX;Danisol-K CAS No.26172-55-4
ISOTHIAZOLINONE
ISOTHIAZOLINONE = ISOTHIAZOL-3-ONE


CAS Number: 1003-07-2
EC Number: 696-206-9
MDL Number: MFCD09834764
Chemical formula: C3H3NOS


Isothiazolinone (sometimes isothiazolone) is an organic compound with the formula (CH)2SN(H)CO.
Isothiazolinone is a white solid, it is structurally related to isothiazole.
The basic substance of the group of substances, isothiazolinone , is a compound that contains a sulfur in a cyclopentene five-membered ring and a nitrogen atom and a carbonyl group ( thiaazocyclopentenone ).


Isothiazolinones are heterocyclic organic compounds that play an important role in biocides .
Isothiazolinone is a heterocyclic chemical compound related to isothiazole.
Isothiazolinone is an antimicrobial preservative that is often used to control fungi, bacteria, and algae.
Isothiazolinones are heterocyclic compounds that are used as biocides.


Five derivatives are used in significant amounts:
Methylisothiazolinone (MIT, MI)
Chloromethylisothiazolinone (CMIT, CMI, MCI)
Benzisothiazolinone (BIT)
Octylisothiazolinone (OIT, OI)
Dichlorooctylisothiazolinone (DCOIT, DCOI)
There is also butylbenzisothiazolinone (BBIT), which, however, plays a subordinate role.


A Isothiazolinone is derivative as antimicrobial.
Isothiazolinone was tested for inhibition of PCAF activity.
5-Chloroisothiazolinones showed the most potent inhibition of PCAF.
Isothiazolinones (CMIT/MIT) is composed of 5-chloro-2-methyl-4-thiazoline-3-ketone (CMI) and 2-methyl-4-thiazoline-3-ketone (MI).


The importance of Isothiazolinone has been growing over the last few years.
Isothiazolinone is another synthetic chemical widely used in household and personal care as preservatives because of its ability to fight off bacteria and microbes.
Isothiazolinone (Isothiazolinone) is a synthetic substance that is put in cosmetics as a preservative.
Isothiazolinone helps extend life and maintain the condition that is still attractive to be used in cosmetics.


Isothiazolinone is an antimicrobial preservative that is commonly used to control bacteria, fungi, and algae.
Isothiazolinone (sometimes isothiazolone) is an organic compound with the formula (CH)2SN(H)CO.
Isothiazolinone (CAS No. 1003-07-2) is an antimicrobial preservative primarily for water containing solutions, as these are breeding grounds for bacteria, fungi, and algae.


Isothiazolinones are heterocyclic compounds that play an important role in biocides .
Isothiazolinone is a microbicidal agent that is used as an additive to water in the form of a liquid or powder.
Isothiazolinone is classified as reactive and hydrochloric acid, which means it reacts with water to produce chlorine and hydrochloric acid.
The biocidal activity of Isothiazolinone is due to its ability to inhibit the growth of bacteria by reacting with their cell walls and destroying them.


This effect may be due to Isothiazolinone's ability to inhibit cholesterol esterase, an enzyme involved in lipid metabolism that has been shown to be associated with diabetes.
Isothiazolinone is also known for its high values of carbonyl groups and chlorine atoms, making it useful for analytical chemistry experiments using gas chromatography (GC), as well as in agricultural research.



USES and APPLICATIONS of ISOTHIAZOLINONE:
Isothiazolinones find application in the preservation of high pH household and industrial and institutional cleaning formulations, as well as personal care and cosmetic materials.
Isothiazolone itself is of limited interest, but several of its derivatives are widely used preservatives and antimicrobials.
Isothiazolinones are used as preservatives against microorganisms ( bacteria , fungi ) in aqueous dispersions , emulsions and solutions.


Due to their bactericidal and fungicidal effect, they protect, for example, cleaning agents, paints , varnishes and adhesives from microbial decomposition.
Other areas of application for isothiazolinones are in paper manufacture , where they are used to combat slime, and in cooling and process waterand the antimicrobial treatment of textiles; DCOIT and OIT are also used as wood preservatives .
In the past, isothiazolinones were also used very frequently for shower gels, shampoos and cosmetics.


Isothiazolinones are used in cosmetic and as chemical additives for occupational and industrial usage due to their bacteriostatic and fungiostatic activity.
Isothiazolinone is another synthetic chemical widely used in household and personal care as preservatives because of its ability to fight off bacteria and microbes.


Antimicrobial preservatives, Isothiazolinones are synthetic biocides/preservatives.
Isothiazolinones are broad-spectrum, non-oxidizing biocides that can be used in a wide range of industrial applications.
Isothiazolinone formulation helps to inhibit the growth of microbes and has inhibition and biocidal effects on most of the common bacteria, fungi and algae found in water.


Isothiazolinone is most commonly applied in water containing solutions, as these solutions are a breeding ground for bacteria.
There are a number of different products on the market today that use Isothiazolinone like sunscreen, hand sanitizer, shampoo, cosmetics, lotions, and many more.
The purpose of including Isothiazolinone in these products is to inhibit microbial activity that could potentially spoil the product before its expected expiration date.


Isothiazolinone has a high performance, broad spectrum, antimicrobial activity controlling both planktonic and surface growth of bacteria, fungi and algae.
Isothiazolinone has been designed exclusively for water treatment and paper mill application.
Isothiazolinones are used as preservatives against microorganisms (bacteria, fungi) in aqueous dispersions, emulsions and solutions.


Due to their bactericidal and fungicidal effect, they protect, for example, shower gels, shampoos, cosmetics, cleaning agents, paints, varnishes and adhesives from microbial decomposition.
Other areas of application for isothiazolinones are paper production, where they are used to combat slime, cooling and process water , the antimicrobial treatment of textiles and they are also used as wood preservatives .


Isothiazolinones are used as preservatives in cooling lubricants.
Are known here v. a. the octylisothiazolinone, which is mainly added to cooling lubricant concentrates because of its fungicidal (fungicidal) effect, and a mixture of chloromethylisothiazolinone and methylisothiazolinone (usually 3:1), which, due to a lack of stability, only gets into the cooling lubricant through the subsequent addition of separate preservatives.


There are a number of different products on the market today that use Isothiazolinone like sunscreen, hand sanitizer, shampoo, cosmetics, lotions, and many more.
The purpose of including Isothiazolinone in these products is to inhibit microbial activity that could potentially spoil the product before its expected expiration date.


Isothiazolinones are synthetic preservatives used in a range of products including cleaning, laundry and personal care.
Since water-containing solutions are the breeding grounds for bacteria, isothiazolinone can easily be used in such solutions.
Although isothiazolinones have no direct applications, their derivatives such as 5-chloro-2-methyl-4-isothiazolin-3-on and 2-methyl-4-isothiazolin-3 which are used together as preservatives in commercial households and cosmetics products, for instance, cleaners, shampoos, and washing materials.


Notably, various products that use isothiazolinones are in the market, including shampoo, hand sanitizer, and lotions.
Isothiazolinones are used in these products as an inhibitor of microbial activity that could lead to the product spoiling before the expected expiration date.
Safety InformationThe recommended use of isothiazolinone products by the manufacturers used as wrinkle releaser is not harmful.


The bactericidal effect of Isothiazolinones (CMIT/MIT) is carried out through breaking the bond between bacteria and algae protein.
When contacted with microbes, Isothiazolinones (CMIT/MIT) can quickly inhibit their growth, thus leading to death of these microbes.
Isothiazolinones (CMIT/MIT) has strong inhibition and biocidal effects on ordinary bacteria, fungi and alga, and has many advantages such as high biocidal efficiency, good degradation, no residual, safety in operation, good compatibleness, good stabilization, low cost in operation.


Isothiazolinones (CMIT/MIT) can mix with chlorine and most cation, anion, and non-ionic surfactants.
When used at high dosage, its biosludge stripping effect is excellent.
Isothiazolinones (CMIT/MIT) is a kind of fungicidal with properties of broad spectrum, high efficiency, low toxicity and non-oxidative, it is the ideal biocidal in industrial circulating cool water system and in wastewater treatment in oilfield, papermaking, pesticide, cutting oil, leather, detergent and cosmetics etc..


When Isothiazolinone is used as sludge stripper for grade II, the dosage of 150-300mg/L is preferred, when used as boicide, the dosage of 80-100mg/L is preferred, and charges every 3-7 days.
When Isothiazolinone is used together with quaternary amine, the effect will be better.
When Isothiazolinone is used as industrial fungicide, the dosage of 0.05-0.4% is preferred.


Isothiazolinone is a cost-effective antimicrobial for personal care formulations.
Suggested applications of Isothiazolinone: personal care preservative.
Isothiazolinone is a high performance industrial microbiocide for use in recirculating water cooling towers, wood, mold and mildew control, pulp and paper mills, air washer systems.
Suggested applications of Isothiazolinone: Industrial water treatment. Very low use levels.



MECHANISM OF ACTION OF ISOTHIAZOLINONE:
The antimicrobial activity of isothiazolinones is attributed to their ability to inhibit life-sustaining enzymes, specifically those enzymes with thiols at their active sites.
Isothiazolinone is established that isothiazolinones form mixed disulfides upon treatment with such species.
RSH+isothiazolone

The principal isothiazolones are:
*Methylisothiazolinone (MIT, MI)
*Chloromethylisothiazolinone (CMIT, CMI, MCI)
*Benzisothiazolinone (BIT)
*Octylisothiazolinone (OIT, OI)
*Dichlorooctylisothiazolinone (DCOIT, DCOI)
*Butylbenzisothiazolinone (BBIT)
These compounds all exhibit antimicrobial properties.
They are used to control bacteria, fungi, and algae in cooling water systems, fuel storage tanks, pulp and paper mill water systems, oil extraction systems, wood preservation, and some paints.
They are antifouling agents.
They are frequently used in shampoos and other hair care products.




SYNTHESIS OF ISOTHIAZOLINONE:
Compared to many other simple heterocycles, the discovery of Isothiazolinone is fairly recent, with reports first appearing in the 1960s.
Isothiazolinones can be prepared on an industrial scale by the ring-closure of 3-mercaptopropanamides.
These in turn are produced from acrylic acid via the 3-mercaptopropionic acid:
Ring-closure of the thiol-amide is typically effected by chlorination or oxidation of the 3-sulfanylpropanamide to the corresponding disulfide.
Many other routes have been developed, including addition of thiocyanate to propargyl amides.





BIOLOGICAL SIGNIFICANCE OF ISOTHIAZOLINONE:
In addition to the desired effect of killing or controlling the growth of microorganisms, isothiazolinones also have undesirable effects.
They have high aquatic toxicity and some isothiazolinones (especially CMIT) can cause sensitization in humans through direct contact or airborne exposure and some isothiazolinones (especially CMIT) can cause skin.




PHYSICAL and CHEMICAL PROPERTIES of ISOTHIAZOLINONE:
Chemical formula: C3H3NOS
Molar mass: 101.127
Appearance: white solid
Melting point: 74–75 °C (165–167 °F; 347–348 K)
Physical state: solid
Color: No data available
Odor: No data available
Melting point/freezing point
Melting point/range: 74 - 75 °C
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: No data available
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
Melting point: 74-75 °C
Density: 1.366±0.06 g/cm3(Predicted)
storage temp.: 2-8°C
solubility: Chloroform (Slightly), Ethyl Acetate (Slightly)
form: Solid
pka: 9.12±0.20(Predicted)
color: Off-White



FIRST AID MEASURES of ISOTHIAZOLINONE:
-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.
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 ISOTHIAZOLINONE:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Take up dry.
Dispose of properly.



FIRE FIGHTING MEASURES of ISOTHIAZOLINONE:
-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 ISOTHIAZOLINONE:
-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
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of ISOTHIAZOLINONE:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.
Dry.



STABILITY and REACTIVITY of ISOTHIAZOLINONE:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Possibility of hazardous reactions:
No data available
-Conditions to avoid:
no information available



SYNONYMS:
1,2-Thiazol-3(2H)-one
Isothiazolin-3-one
3(2H)-Isothiazolone, isothiazolin
Isothiazalone
thiazol-3-one
3-isothiazolone
Isothiazol-3-one
1,2-thiazol-3-one
Isothiazolin-3-one
3(2H)-Isothiazolone
Isothiazol-3(2H)-one
Isothiazol-3(2H)-one 97%
3-Oxo-2,3-dihydroisothiazole
thiazol-3-one
3-isothiazolone
Isothiazol-3-one
1,2-thiazol-3-one
3(2H)-Isothiazolone
3-isothiazolone
Isothiazol-3-one
1,2-thiazol-3-one
3(2H)-Isothiazolone
isothiazol-3(2H)-one


ISOTHIAZOLINONES
Isothiazolinones exhibit antimicrobial properties.
Isothiazolinones are antifouling agents.


CAS Number: 26172-55-4, 2682-20-4, 1003-07-2
EC Number: 247-500-7
MDL Number: MFCD09834764
Chemical formula: C3H3NOS



SYNONYMS:
CMIT, Isothiazolinones, CMIT, Isothiazolinone, CMI, CMIT/MIT, 5-CHLORO-2-METHYL-4-ISOTHIAZOLIN-3-ONE, MCI, 5-Chloro-2-methyl-3(2H)-isothiazolone, Chloromethylisothiazolinone, 5-chloro-2-methyl-2H-isothiazol-3-one, isothiazolin, 1,2-Thiazol-3(2H)-one, Isothiazolin-3-one, 3(2H)-Isothiazolone, isothiazolin, Isothiazalone, thiazol-3-one, 3-isothiazolone, Isothiazol-3-one, 1,2-thiazol-3-one, Isothiazolin-3-one, 3(2H)-Isothiazolone, Isothiazol-3(2H)-one, Isothiazol-3(2H)-one 97%, 3-Oxo-2,3-dihydroisothiazole, thiazol-3-one, 3-isothiazolone, Isothiazol-3-one, 1,2-thiazol-3-one, 3(2H)-Isothiazolone, 3-isothiazolone, Isothiazol-3-one, 1,2-thiazol-3-one, 3(2H)-Isothiazolone, isothiazol-3(2H)-one, 1,2-Thiazol-3(2H)-one, Isothiazolin-3-one, 3(2H)-Isothiazolone, isothiazolin



Isothiazolinones are a preservative used in cosmetic products such as shampoos and hair care products.
Isothiazolinones are permitted in Europe for all cosmetic applications, but at a maximum concentration of 15 ppm.
Therefore, the support of a laboratory competent in the analysis of preservatives in cosmetics is essential to be able to perform the analysis of

Isothiazolinones (/ˌaɪsoʊˌθaɪ.əˈzoʊlɪnoʊn/; sometimes isothiazolone) are an organic compound with the formula (CH)2SN(H)CO.
A white solid, Isothiazolinones are structurally related to isothiazole. Isothiazolinones are of limited interest, but several of their derivatives are widely used preservatives and antimicrobials.


Isothiazolinones exhibit antimicrobial properties.
Isothiazolinones are antifouling agents.
Isothiazolinones are frequently used in shampoos and other hair care products.


Isothiazolinones are synthetic preservatives used in a range of products including cleaning, laundry and personal care.
Isothiazolinones are known as sensitizersiv, which have been linked to allergic contact dermatitis.
Isothiazolinones, some reminders about these compounds:


Isothiazolinones are a family of biocides based on a heterocycle: 1,2-thiazol-3-one.
It is a thiazole with a ketone function or a lactam with a sulphur atom in the unsaturated ring.
The biocidal effect of Isothiazolinones is achieved in two stages: from the very first minutes, cell growth is inhibited and irreversible damage is caused within a few hours.


Isothiazolinones react with proteins and interfere with oxygen consumption, respiration, ATP synthesis and energy production.
Isothiazolinones do, however, have some undesirable effects including high aquatic toxicity and skin sensitization which can cause allergic dermatitis mainly on the hands and face.


The presence of Isothiazolinones in cosmetic products is authorised in Europe at a maximum level of 15 ppm.
Indeed, due to their high polarity, some Isothiazolinones are difficult to isolate from water.
Isothiazolinones are a heterocyclic chemical compound related to isothiazole.


Isothiazolinones an antimicrobial preservative that is often used to control fungi, bacteria, and algae.
Since water-containing solutions are the breeding grounds for bacteria, Isothiazolinones can easily be used in such solutions.
Isothiazolinones are a cost-effective antimicrobial for personal care formulations.


Suggested applications of Isothiazolinones: personal care preservative.
Isothiazolinones are composed of 5-chloro-2-methyl-4-thiazoline-3-ketone (CMI) and 2-methyl-4- thiazoline-3-ketone(MI). Isothiazolinones’ bactericidal effect is carried out by breaking the bond between bacteria and algae protein.


When contacted with microbes, Isothiazolinones can quickly inhibit their growth.
Thus leading to the death of these microbes.
Isothiazolinones also have certain effects on silt’s peeling, dispersing, and infiltration.


As a result, Isothiazolinones can protect the water quality and ensure the normal operation of the equipment.
The performance of Isothiazolinones is very stable.
And the applicability is strong.


Just put a small number of Isothiazolinones in the area that water treatment is needed.
Based on the excellent characteristics of bactericidal algaecide, Isothiazolinones are quickly recognized by various industries.
For example, Isothiazolinones are widely used in industrial circulating cooling water systems, such as chemical, textile, power plants, industrial storage tanks, cooling towers, swimming pools, fountain landscape water, and other industrial projects.


Isothiazolinones are an antimicrobial preservative primarily for water containing solutions, as these are breeding grounds for bacteria, fungi, and algae.
There are a number of different products on the market today that use Isothiazolinones like sunscreen, hand sanitizer, shampoo, cosmetics, lotions, and many more.


The purpose of including Isothiazolinones in these products is to inhibit microbial activity that could potentially spoil the product before its expected expiration date.
Isothiazolinones can also disinfect and kill the common bacterium, fungus and water plant.


For better effect, Isothiazolinones can be used in conjunction with the ionic and non-ionic water treatment chemicals.
After usage, Isothiazolinones are easy to be degraded into non-toxic molecule without secondary pollution.
Isothiazolinones are a kind of non-oxidizing bactericide with broad-spectrum, high efficiency and low toxicity.


Isothiazolinones's active content is isothiazolinone and its derivative mixture.
Isothiazolinones have strong penetration ability for the cell membrane of microorganism and can decompose and destroy the cell tissue.
Isothiazolinones, with the chemical formula C3H3NOS and CAS registry number 26172-55-4, is a compound known for its antimicrobial properties.


Isothiazolinones are effective against a wide range of microorganisms and have a low toxicity profile, making it a popular choice for preservation.
Overall, Isothiazolinones play a crucial role in maintaining the quality and longevity of many everyday products.



USES and APPLICATIONS of ISOTHIAZOLINONES:
A white solid, Isothiazolinones are structurally related to isothiazole. Isothiazolinones are of limited interest, but several of their derivatives are widely used preservatives and antimicrobials.
Isothiazolinones are used to control bacteria, fungi, and algae in cooling water systems, fuel storage tanks, pulp and paper mill water systems, oil extraction systems, wood preservation, and some paints.


Isothiazolinones are used especially as an antifouling agent, i.e. paint for ship hulls to prevent the formation of barnacles, etc.
Isothiazolinones are preservatives used against algae, fungi and bacteria in cooling systems, fuel tanks, paper mills, wood preservation or oil extraction.
Isothiazolinones are also used in lacquers, paints or varnishes.


Isothiazolinones are also used in the surface treatment of mould on historical monuments (such as the Lascaux cave or the Angkor temples in Cambodia).
As a preservative, Isothiazolinones are also used in cosmetic products such as shampoo or hair care products, detergents and laundry detergents.
Isothiazolinones are commonly used as a preservative in various industrial and consumer products, such as paints, adhesives, and personal care products.


Isothiazolinones work by inhibiting the growth of bacteria, fungi, and algae, helping to prevent the degradation and spoilage of these products.
Isothiazolinones are a high performance industrial microbiocide for use in recirculating water cooling towers, wood, mold and mildew control, pulp and paper mills, air washer systems.


Although Isothiazolinones have no direct applications, their derivatives such as 5-chloro-2-methyl-4-isothiazolin-3-on and 2-methyl-4-isothiazolin-3 which are used together as preservatives in commercial households and cosmetics products, for instance, cleaners, shampoos, and washing materials.
Notably, various products that use Isothiazolinones are in the market, including shampoo, hand sanitizer, and lotions.


Isothiazolinones is used in these products as an inhibitor of microbial activity that could lead to the product spoiling before the expected expiration date.
The recommended use of Isothiazolinones products by the manufacturers used as wrinkle releaser is not harmful.


Determination of Isothiazolinones in consumer goods:
Isothiazolinones are common preservatives (biocides) in cosmetics, chemical formulations, and printing inks.
Used as preservatives, biocides and disinfectants in a variety of industrial and domestic applications.


When used as a sludge stripper for grade II, 150~300 mg/L is preferred.
When used as a biocide, 80~100 mg/l is preferred.
And charges every 3~7 days.


The Isothiazolinones can’t be used together with oxidative fungicides like chlorine.
And Isothiazolinones can’t be used in cooling water systems containing sulfur.
When Isothiazolinones are used together with a quaternary amine, the effect will be better.


When Isothiazolinones is used as an industrial fungicide, 0.05~0.4% is preferred.
Isothiazolinones have a high performance, broad spectrum, antimicrobial activity controlling both planktonic and surface growth of bacteria, fungi and algae.


Isothiazolinones have been designed exclusively for water treatment and paper mill application.
Isothiazolinones are antimicrobials used to control bacteria, fungi, and algae in cooling water systems, fuel storage tanks, pulp and paper mill water systems, oil extraction systems, wood preservation and antifouling agents.


Isothiazolinones are frequently used in personal care products such as shampoos and other hair care products, as well as certain paint formulations.
Isothiazolinones are antimicrobials used to control bacteria, fungi, and algae in cooling water systems, fuel storage tanks, pulp and paper mill water systems, oil extraction systems, wood preservation and antifouling agents.


Isothiazolinones are frequently used in personal care products such as shampoos and other hair care products, as well as certain paint formulations.
There, often combinations of MIT and CMIT (known as Kathon CG) or MIT and BIT are used.


-Isothiazolinones are heterocyclic compounds that are used as biocides.
Five derivatives are used in significant amounts:
*Methylisothiazolinone (MIT, MI)
*Chloromethylisothiazolinone (CMIT, CMI, MCI)
*Benzisothiazolinone (BIT)
*Octylisothiazolinone (OIT, OI)
*Dichlorooctylisothiazolinone (DCOIT, DCOI)
The derivative butylbenzisothiazolinone (BBIT) also exists, but does not have the same importance.



FUNCTIONS OF ISOTHIAZOLINONES:
Isothiazolinones can be widely used as bactericide for industrial circulating cool water, oilfield water and the like in the industries such as oil refining, chemical industry, fertilizer, electric power and metallurgy to control the growth of microorganism effectively.



PROPERTIES OF ISOTHIAZOLINONES:
Isothiazolinones have strong inhibition and biocidal effects on ordinary bacteria, fungi, and alga.
And Isothiazolinones have many advantages, such as high biocidal efficiency, good degradation, no residual, safety in operation, good compatibleness, good stabilization, and low cost in operation.

Isothiazolinones can mix with chlorine and most cation, anion, and non-ionic surfactants.
However, Isothiazolinones's bio-sludge stripping effect is excellent when used at high dosages.
Isothiazolinones are fungicidal with broad spectrum properties, high efficiency, low toxicity, and non-oxidative.
Isothiazolinones are the ideal biocidal in the industrial circulating cool water system.

Also, in wastewater treatment, the oilfield, papermaking, pesticide, cutting oil, leather, detergent, cosmetics, etc.
Isothiazolinones have a high inhibitory effect on various fungi and algae, such as green algae, brown algae, fungi, and bacteria.
At the same time, Isothiazolinones also control the growth of slime in water.



KEY FEATURES AND BENEFITS OF ISOTHIAZOLINONES:
*Rapid Inhibition of Microbial Growth
*Effective at low concentrations
*Requires lesser dosing
*Well effective over a wide pH range
*Non foaming
*Biodegradable



THERE ARE FIVE IMPORTANT DERIVATIVES IN THE FAMILY OF ANTIMICROBIAL ISOTHIAZOLINONES:
*Methylisothiazolinone (MIT, MI);
*Chloromethylisothiazolinone (CMIT, MIT, MCI);
*Benzisothiazolinone (BIT);
*Octylisothiazolinone (ILO, RO);
*Dichlorooctylisothiazolinone (DCOIT, COD).



ANALYSIS OF ISOTHIAZOLINONES IN YOUR COSMETIC PRODUCTS:
You need to analyse Isothiazolinones in your cosmetic products.
First of all, Isothiazolinones are a family of biocides composed from a heterocycle, 1,2-thiazol-3-one.
Isothiazolinones are used against bacteria and fungi in lacquers, paints, antifoulings and varnishes.

Isothiazolinones' biocidal effect comes from a two-step mechanism: a rapid inhibition of growth and respiration, followed by irreversible damage to the cell within hours.
By reacting with the cell’s proteins, oxygen consumption, hence respiration, and ATP synthesis, hence energy production, are inhibited.



THE PRINCIPAL ISOTHIAZOLINONES ARE:
*Methylisothiazolinone (MIT, MI)
*Chloromethylisothiazolinone (CMIT, CMI, MCI)
*Benzisothiazolinone (BIT)
*Octylisothiazolinone (OIT, OI)
*Dichlorooctylisothiazolinone (DCOIT, DCOI)
*Butylbenzisothiazolinone (BBIT)



MECHANISM OF ACTION OF ISOTHIAZOLINONES:
The antimicrobial activity of Isothiazolinones is attributed to their ability to inhibit life-sustaining enzymes, specifically those enzymes with thiols at their active sites.
Isothiazolinones are established that Isothiazolinones form mixed disulfides upon treatment with such species.



SYNTHESIS OF ISOTHIAZOLINONES:
Compared to many other simple heterocycles, the discovery of Isothiazolinones are fairly recent, with reports first appearing in the 1960s.
Isothiazolinones can be prepared on an industrial scale by the ring-closure of 3-mercaptopropanamides.
These in turn are produced from acrylic acid via the 3-mercaptopropionic acid



PHYSICAL and CHEMICAL PROPERTIES of ISOTHIAZOLINONES:
Chemical formula: C3H3NOS
Molar mass: 101.127
Appearance: white solid
Melting point: 74–75 °C (165–167 °F; 347–348 K)
Physical state: solid
Color: No data available
Odor: No data available
Melting point/freezing point
Melting point/range: 74 - 75 °C
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: No data available
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
Melting point: 74-75 °C
Density: 1.366±0.06 g/cm3(Predicted)
storage temp.: 2-8°C
solubility: Chloroform (Slightly), Ethyl Acetate (Slightly)
form: Solid
pka: 9.12±0.20(Predicted)

color: Off-White
CBNumber:CB4132565
Molecular Formula:C4H4ClNOS
Molecular Weight:149.6
MDL Number:MFCD00792550
MOL File:26172-55-4.mol
Melting point: 42-45?C
Boiling point: 109.7°C
Density 1.25 (14% aq.)
Properties:
Refractive index: n20/D 1.378
Storage temp.: Refrigerator
Solubility: Chloroform (Slightly), DMSO (Slightly),
Methanol (Slightly, Heated)
pKa: -4.06±0.40 (Predicted)

Form: Liquid
Stability: Stable, Incompatible with strong oxidizing agents
LogP: 0.240 (est)
Identifiers:
Indirect Additives used in Food Contact Substances:
5-CHLORO-2-METHYL-4-ISOTHIAZOLIN-3-ONE
CAS DataBase Reference: 26172-55-4 (CAS DataBase Reference)
FDA UNII: DEL7T5QRPN
NIST Chemistry Reference: 5-Chloro-2-methyl-3(2h)-isothiazolone (26172-55-4)
EPA Substance Registry System: 5-Chloro-2-methyl-4-isothiazolin-3-one (26172-55-4)
Chemical Properties:
Chemical formula: C3H3NOS
Molar mass: 101.127 g/mol
Appearance: White solid
Melting point: 74–75 °C (165–167 °F; 347–348 K)



FIRST AID MEASURES of ISOTHIAZOLINONES:
-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.
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 ISOTHIAZOLINONES:
-Environmental precautions:
Do not let product enter drains.
-Methods and materials for containment and cleaning up:
Cover drains.
Collect, bind, and pump off spills.
Take up dry.
Dispose of properly.



FIRE FIGHTING MEASURES of ISOTHIAZOLINONES:
-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 ISOTHIAZOLINONES:
-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
-Control of environmental exposure:
Do not let product enter drains.



HANDLING and STORAGE of ISOTHIAZOLINONES:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Tightly closed.
Dry.



STABILITY and REACTIVITY of ISOTHIAZOLINONES:
-Chemical stability:
The product is chemically stable under standard ambient conditions (room temperature) .
-Possibility of hazardous reactions:
No data available
-Conditions to avoid:
no information available


Isothiazolines
Isotridecyl alcohol; ISOTRIDECANOL, N° CAS : 27458-92-0, Nom INCI : ISOTRIDECANOL. Nom chimique : Isotridecan-1-ol, N° EINECS/ELINCS : 248-469-2, Ses fonctions (INCI) : Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. C11-14-iso-Alcohols, C13-rich; Isotridecanol; 11-Methyl-1-dodecanol [ACD/IUPAC Name]; 11-Methyl-1-dodecanol [German] [ACD/IUPAC Name]; 11-Méthyl-1-dodécanol [French] [ACD/IUPAC Name]; 11-Methyldodecan-1-ol; 1-Dodecanol, 11-methyl- [ACD/Index Name]; 27458-92-0 [RN]; 288-581-9 [EINECS]; 68526-86-3 [RN]; Isotridecyl alcohol; [27458-92-0]; 11-methyldodecanol; Alcohol C-13 Oxo; Alcohols, C11-14-iso-, C13-rich; FIXATEUR ITC; Isotridecan-1-ol; Isotridecanol-; Isotridecylalcohol; ISO-TRIDECYL-ALCOHOL
ISOTRIDECANOL ( Isotridecyl alcohol )
Isotridecanol

Isotridecyl alcohol= isotridecanol= isotridecan-1-ol= 11-methyldodecanol

Isotridecanol is a clear, high-boiling, oily liquid with a faint, characteristic odour.
Isotridecanol is miscible with most common organic solvents, but is practically insoluble in water.

Isotridecanol is a branched, linear and primary alcohol with high mole wt. Isotridecanol is a used as a raw material in the industries of cosmetics, drug delivery, metal processing, fiber finish, thermostable and biodegradable lubricant and solvent as well as surfactant.

Isotridecyl Alcohol is used in some Hair Care products as it softens and smoothens the hair and enhances its appearance.
Commonly Isotridecyl Alcohol is used amongst others as an intermediate in production of surfactants and softeners as a raw material in the industries of cosmetics, drug delivery, metal processing, fiber finish, thermostable and biodegradable lubricant and solvent as well as surfactant.
Isotridecyl Alcohol can also be found as fragrance ingredient in personal care products.


Isotridecanol is starting material for the production of plasticizers, lubricants, and auxiliaries in the chemical and allied industries.Isotridecanol is Low-volatility solvent for oils, waxes, fats and dyes.
Isotridecanol is used as defoamer in the textile, paper and coating industries.

Isotridecanol (ITDA) is an organic-chemical compound from the group of alcohols.
Under normal conditions, isotridecanol is a colorless, weakly smelling liquid that is insoluble in water.

The highly pure C13 alcohol is an important intermediate product in the production of surface-active substances, so-called surfactants.
The term iso refers to the methyl group on the penultimate carbon atom and on the end opposite the OH group Branched C12 carbon chain.
The correct systematic name is therefore 11-methyl-1-dodecanol.

Isotridecanol is regarded as a real petrochemical specialty and is launched as a particularly high-quality product with an almost 100% content of C13 alcohols.


Isotrideconal is used, among other things, as an intermediate in the manufacture of surfactants and plasticizers.
Isotrideconal is often used in high-quality industrial applications, e.g. in the production of cleaning agents and lubricants.
Another application of Isotrideconal is in the form of special esters in high-quality lacquers and lacquer resins.
In addition, isotridecanol may also be used in the EU as a fragrance in cosmetic articles and preparations using the INCI name of the same name.

Isotrideconal has a general purpose as a dispersant and emulsifier with good wetting properties.


Chemical Structure: Mixture of C13H27OH Isomer
Chemical Name: ISOTRIDECANOL
Molecular Formula: C13H28O
Molecular Weight: 200.4
CAS No.: 27458-92-0
EINECS No.: 248-469-2
CAS: 27458-92-0;68526-86-3
Molecular Formula: C13H28O






Synonyms:
alcohols, C11-14-iso-, C13-rich
C11-14-iso-alcohols, C13-rich
1-dodecanol, 11-methyl-
11-methyl-1-dodecanol
11-methyldodecan-1-ol
11-methyldodecanol
isotridecan-1-ol
isotridecyl alcohol



Application of Isotridecanol:
Cleaning and furnishing care products
Fabric, textile, and leather products not covered elsewhere
Ink, toner, and colorant products
Lubricants and greases
Mining


All other basic organic chemical manufacturing
All other chemical product and preparation manufacturing
Mining (except oil and gas) and support activities
Paint and coating manufacturing
Petroleum lubricating oil and grease manufacturing
Plastic material and resin manufacturing
Plastics product manufacturing
Printing ink manufacturing
Rubber product manufacturing
Soap, cleaning compound, and toilet preparation manufacturing
Synthetic rubber manufacturing
Textiles, apparel, and leather manufacturing

Isotridecanol
C11-14-iso-Alcohols, C13-rich
11-Methyl-1-dodecanol
11-Methyl-1-dodecanol [German]
11-Méthyl-1-dodécanol [French]
11-Methyldodecan-1-ol
11-methyldodecanol
1-Dodecanol, 11-methyl-
27458-92-0 [RN]
288-581-9 [EINECS]
68526-86-3 [RN]
Alcohol C-13 Oxo
Isotridecyl alcohol
[27458-92-0]
11-Methyldodecanol-d7
158923-11-6 [RN]
1794766-65-6 [RN]
Alcohols, C11-14-iso-, C13-rich
FIXATEUR ITC
https://www.ebi.ac.uk/chebi/searchId.do?chebiId=CHEBI:77438
Isotridecan-1-ol
Isotridecanol-
Isotridecylalcohol
ISO-TRIDECYL-ALCOHOL




Isotridecanol
11-Methyldodecanol
ISOTRIDECYL ALCOHOL
11-methyldodecan-1-ol
85763-57-1
Isotridecan-1-ol
27458-92-0
68526-86-3
Iso-Tridecyl-alcohol
Alcohols, C11-14-iso-, C13-rich
Isotridecanol-
11-Methyl-1-dodecanol
UNII-VX3T72M5SG
1-Dodecanol, 11-methyl-
VX3T72M5SG
EINECS 248-469-2
EINECS 271-235-6
EINECS 288-581-9
Alcohol C-13 Oxo




Final product applications
Agricultural chemicals
Detergents and cleaners
Lubricants
Metal working and fuel additives
Additives
Oil and gas
Paints
Inks
Coatings
Adhesives
Plastic and rubber additives
Specialty
Industrial applications
Textile
Leather processing


Exxal® 13 (Isotridecyl Alcohol)
Substance
11-Methyldodecan-1-ol
CAS
68526-86-3
EC number
271-235-6
REACH compliant
Yes
Purity
99%
Color
Colorless
Appearance
Liquid


Product Description
Exxal alcohols are isomeric branched, primary alcohols that contain both even- and odd-numbered hydrocarbon chains, ranging from C8 to C13.

In general, there are two main types of structures in industrial alcohols:

Linear (or straight-chain) molecules: obtained from synthetic or natural sources
Branched chain alcohols: produced from propylene and butene

Our customers use Exxal alcohols to synthesize derivatives used in industrial applications:

Surfactants – industrial applications, cleaning, and oil and gas

Polymer additives – stabilizers, antioxidants and flame retardants
Adhesives – acrylates

Lube and fuel additives
Lubricant esters

They are also used as solvents or cosolvents for coatings, inks and metal extraction in mining.

Benefits

High-purity Exxal alcohols exhibit reactivity typical of higher primary alcohols. Thanks to their branched structure, Exxal alcohols offer many performance advantages to ethoxylates compared to linear alcohol-based ones:

Low pour point – prohibits gel and wax formation, facilitates processing of alcohols and derivatives
Biodegradability – all of our alcohols and their ethoxylates meet the OECD 301F readily biodegradable threshold for isomeric mixtures
Superior wetting power of derived surfactants – excellent candidates for resource extraction and nonylphenol substitution
Powerful solvency in coatings and inks, fully soluble in hydrocarbon fluids while enhancing their solvency power
Wide viscosity ranges in synlubes
Industries
Leather & Textiles , Paints & Coatings , Additive Manufacturing
Product Groups
Emulsifiers & Dispersing Agents , Binders & Resins , Antioxidants & Stabilizers , Additives
Substance details




ISOTRIDECYL ALCOHOL 30 EO 70 %
Composition: Isotridecyl polyethylene glycol ether with 30-mole ethylene oxide


ISOTRIDECYL ALCOHOL 30 EO 70 %: Aqueous solution of a fatty alcohol polyglycol ether.

CAS number: 9043-30-5


Synonyms: C 13 Alcohol 30 Ethoxylate, 70 % in Water, Fatty alcohol polyglycol ether, Isotridecyl polyethylene glycol ether with 30-mole ethylene oxide, C 13 Alcohol 30 EO,



ISOTRIDECYL ALCOHOL 30 EO 70% is a nonionic emulsifier for emulsion polymerization.


Use of ISOTRIDECYL ALCOHOL 30 EO 70 %:

The use of ISOTRIDECYL ALCOHOL 30 EO 70% in emulsion polymerization of vinyl acetate, acrylate, and acrylate/styrene dispersions reduces coagulation and improves electrolyte resistance and freeze/thaw stability.

ISOTRIDECYL ALCOHOL 30 EO 70 % is added to the emulsion before, during, or after the polymerization process.

ISOTRIDECYL ALCOHOL 30 EO 70 % improves latex stability and prevents coagulation during polymerization.

Improving the latex properties means better electrolyte, shear stability, and freeze-thaw stability.



Use of the substance/preparation:

Industry sector: Industrial Performance Chemicals
Type of use: Emulsifier for emulsion polymerization

Product properties *)
Active substance content
about 70 % with 30% water


Item: Specification

Consistency at 20°C: liquid (visual)

Transparency at 20°C: clear (visual)

Hazen colour: max. 130 EN 1557

pH value 5% as is in water: 6.0 - 8.0 DIN EN 1262

Water content: 29.0 - 31.0 % DIN 51777

Viscosity (dynamic): approx. 2.300 mPa.s (20 °C) Brookfield

Viscosity at 50°C: 100 - 200 mPas ISO 6388

Pourpoint: approx. 5 °C DIN/ISO 3016


Appearance
at 5°C: white paste
at 25°C: clear, colorless liquid
at 50°C: clear, colorless liquid
pH value (DIN EN 1262), 5 % as is in water: 6 - 8


Solubility at 25 °C: clear soluble in water

Density at 25 °C: approx. 1.08 g/cm³

Viscosity at 25 °C (Brookfield, Spindle LV1): about 700 mPas

Flashpoint (DIN/ISO 2592): > 100 °C

Critical Micelle Concentration: 0,88 g/l active material in water

Surface Activity at 1 g/l active substance: about 38 mN/m

HLB value: about 17

Biodegradability: 57 % (28 d)

Method: OECD 301 B

Fish toxicity : LC50 > 100 mg/l (96 h, zebrafish)

Method: OECD 203

Bacteria toxicity : EC50 > 5 mg/l (Vibrio fisheri)

Method: DIN EN ISO 11348-2

Dissolved Organic carbon(DOC) : 1.919 mg/g
Method: DIN/EN 1484

Chemical oxygen demand (COD): 632 mg/g
Method: ISO/DIS 15705



Isotridecyl Alcohol 30 EO 70 % is used in the Emulsion polymerization of styrene, acrylic acid copolymers, and vinyl acetate copolymers.

Isotridecyl Alcohol 30 EO 70 % is liquid and readily miscible, and it has substantial wetting and emulsifying properties.

Isotridecyl Alcohol 30 EO 70 enables higher dispersion, freeze-thaw, and electrolyte stability.



Application of Polymers, where ISOTRIDECYL ALCOHOL 30 EO 70 % is used:

1. Paints and coatings applications
– Architectural coatings (paints)
– Industrial coatings
– Wood coatings

2. Paper application
– Paper sizing
– Pulp binder

3. Adhesives

4. Carpet back sizing application

5. Textile application

6. Caulk and sealants, cement concrete application

7. Others



Handling and Storage
Below 15°C ISOTRIDECYL ALCOHOL 30 EO 70% starts crystallization after heating
up at 30°C ISOTRIDECYL ALCOHOL 30 EO 70% turns into a clear liquid again.





This information is based on our present knowledge and is intended to provide general notes on our products and their uses.
It should not, therefore, be construed as guaranteeing specific properties of the products described on their suitability for a particular application.
Any existing industrial property rights must be observed.
The quality of our products is guaranteed under our General Conditions of Sale.

*) These characteristics are for guidance only and should not be considered product specifications.
The tolerances are given in the product specification sheet.
For further information on product properties, toxicological, ecological, and safety data, please refer to the safety data sheet.



OTHER PRODUCTS OF ATAMAN CHEMICALS THAT MIGHT BE OF INTEREST:

ISOTRIDECYL ALCOHOL 40 EO 70 %
C13 Alcohol 40 EO 70 %
NP 40
Nonyl Phenol 40 Ethoxylate


ISOTRIDECYL ALCOHOL 50 EO 60 %
C13 Alcohol 50 EO 60 %
NP 50
Nonyl Phenol 50 Ethoxylate


Please check www.atamankimya.com for more products.









ISOTRIDECYL ISONONANOATE
ISOTRIDECYL LAURATE, N° CAS : 94134-83-5, Nom INCI : ISOTRIDECYL LAURATE, Nom chimique : 11-Methyldodecyl Dodecanoate. N° EINECS/ELINCS : 302-853-7: Ses fonctions (INCI), Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance, Agent d'entretien de la peau : Maintient la peau en bon état
ISOTRIDECYL LAURATE
ISOTRIDECYL SALICYLATE, N° CAS : 1863871-63-9, Nom INCI : ISOTRIDECYL SALICYLATE. Nom chimique : Benzoic acid, 2-hydroxy, reaction products with isotridecanol. Ses fonctions (INCI), Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent d'entretien de la peau : Maintient la peau en bon état
ISOTRIDECYL SALICYLATE
ITACONIC ACID; Methylenesuccinic acid; Methylene Butanedioic acid; Propylenedicarboxylic acid; 2-Propene-1,2-dicarboxylic acid; cas no: 97-65-4
ISOTRIDECYL STEARATE

Isotridecyl Stearate is a pharmaceutical-grade intermediate that is required during the organic synthesis procedure. Its molecular weight is 466.82 and its purity level is 99.0%. The boiling point of this chemical is 489.8 degrees C at 760 mm Hg. Its relative density is 0.857g/cm3. It is accessible in colourless or pale yellow transparent liquid form. Isotridecyl Stearate has 255.5 degrees C flashpoint. The Standard of this substance has been verified on the basis of its shelf life, composition, chemical attributes, possible toxin content and processing method. Importance is also given on checking its chemical stability when used under different temperature.


CAS NO : 31565-37-4
EC NO : 250-703-3
IUPAC NAMES: 
11-methyldodecyl octadecanoate


SYNONYMS
Isotridecyl stearate;Octadecanoic acid, isotridecyl ester;31565-37-4;11-methyldodecyl octadecanoate;UNII-J8793TKA30;J8793TKA30;Stearic acid, isotridecyl ester;EINECS 250-703-3;SCHEMBL2699239;Isotridecyl Stearate, veg. based; 11-methyldodecyl ester;ZINC95803367;W-110802;Q27281337;11-methyldodecyl octadecanoate
;11-methyldodecyl stearate;octadecanoic acid isotridecyl ester;octadecanoic acid, 11-methyldodecyl ester;octaearic acid;isotridecyl ester; isotridecyl ester;Isotridecylstearat;isotridecyl stearate;isotridecyl ester;Octadecanoic acid, isotridecyl ester;Isotridecylstearate; Octadecanoicacid,isotridecylester; Stearicacid,isotridecylester; 11-methyldodecylstearate; 11-methyldodecyloctadecanoate; 31565-37-4;11-methyldodecyl octadecanoate 31565-37-4 CTK4G7366 EINECS 250-703-3 Exceparl TD-S Isotridecyl stearate Isotridecyl Stearate; veg. based ISOTRIDECYL STEARATE;isotridecyl stearateIsotridecyl octadecanoate; J8793TKA30 LS-166598 NS00019608 Octadecanoic acid; isotridecyl ester Octadecanoic acid;isotridecyl ester Q27281337 SCHEMBL2699239;11-methyldodecyl ester;isotridecyl ester Stearicacid;isotridecyl ester (7CI,8CI) UNII-J8793TKA30 W-110802 ZINC95803367


Isotridecyl stearate is the raw material for spin finishes and oiling agent for textile, rubber processing agent, Plastic lubricant, Paint, Ink additive.
Isotridecyl stearate is a clear, colourless oily liquid that works as a medium feel emollient.
Isotridecyl stearate absorbs very quickly into the skin, leaves no shine and gives a nice, velvety after-feel.
Isotridecyl stearate is used in cosmetics as a thickening agent and emollient.
Isotridecyl stearate is a lubricity additive, provides a substantially lubricious film
Isotridecyl stearate has good metal adhesion properties
Isotridecyl stearate has good corrosion protection properties
* Characterised by a viscosity of 16C at 40 C
* Characterised by a pour point of 7 C


Isotridecyl stearate is used in Neat oils, Soluble oils, Semi-Synthetics, Vanishing oils
Isotridecyl stearate is used in cosmetics for skin conditioning/moisturizing.

Industry Uses
-Finishing agents
-Lubricants and lubricant additives
Consumer Uses
-Lubricants and greases
-Metal products not covered elsewhere


Industry Processing Sectors
-Fabricated metal product manufacturing
-Textiles, apparel, and leather manufacturing

The stearate esters (Butyl Stearate, Cetyl Stearate, Isocetyl Stearate, Isopropyl Stearate, Myristyl Stearate, Ethylhexyl Stearate, Isobutyl Stearate) are oily liquids or waxy solids.
Ethylhexyl Stearate may also be called Octyl Stearate. In cosmetics and personal care products, stearate esters are used most frequently in the formulation of eye makeup, skin makeup, lipstick and skin care products.
Why is it used in cosmetics and personal care products?
Stearate esters act primarily as lubricants on the skin's surface, which gives the skin a soft and smooth appearance.
Butyl Stearate also decreases the thickness of lipsticks, thereby lessening the drag on lips, and imparts water-repelling characteristics to nail polishes.
Butyl Stearate and Isopropyl Stearate dry to form a thin coating on the skin. Isocetyl Stearate can also be used to dissolve other substances, usually liquids.

Scientific Facts:
The stearate esters are prepared by reacting stearic acid with the appropriate alcohol (butyl, cetyl, isobutyl, isocetyl, isopropyl, myristyl or ethylhexyl alcohol).
Stearate esters have the unique properties of low viscosity and oily nature, which results in a nongreasy, hydrophobic film when applied to the skin or lips.
Stearic acid is found in animal and vegetable fats.

Function in the product
Affects the application properties of cosmetics - gives a good glide when spreading (e.g. lipsticks on the lips), reduces sticking and greasiness of the cosmetic. Stick plasticizer - gives the sticks elasticity, prevents them from crushing.

Cosmetic action
Used in skin and hair care preparations, it creates an occlusive layer on the surface, which prevents excessive evaporation of water from the surface (indirect moisturizing effect), thus conditioning, i.e. softening and smoothing the skin and hair.

Isotridecyl Stearate
cas no 31565-37-4 Octadecanoic acid, isotridecyl ester; Stearic acid, isotridecyl ester; Isotridecyl Stearate, veg. based; Octadecanoic acid,isotridecyl ester;
Isovaleraldehyde
Isovaleraldehyde; Isovalerylaldehyde: 2-Methylbutanal-4; 3-Methyl-1-butanal; 3-Methylbutanal; 3-Methylbutylaldehyde; Aldehyde isovalerianique (French); Isoamyl aldehyde; Isoamylaldehyde; Isopentaldehyde; Isopentanal; Isovaleral; Isovaleric aldehyde; beta-Methylbutanal; beta-Methylbutyraldehyde; CAS NO:590-86-3
Isovaleric acid
SYNONYMS Isopropylacetic acid; Delphinic acid; Isopropylacetic acid; 3-Methylbutyric acid; 3-Methylbutanoic acid; beta-Methyl butyric acid; Isobutylformic acid; Isopentanoic acid; Iso C-5 Acid; Isovalerianic; 3-Methylbutyrate; Kyselina isovalerova; CAS NO. 503-74-2
ITACONIC ACID
Itaconic Acid Itaconic acid, or methylidenesuccinic acid, is an organic compound. This dicarboxylic acid is a white solid that is soluble in water, ethanol, and acetone. Historically, itaconic acid was obtained by the distillation of citric acid, but currently it is produced by fermentation. The name itaconic acid was devised as an anagram of aconitic acid, another derivative of citric acid. Production Since the 1960s, it is produced industrially by the fermentation of carbohydrates such as glucose or molasses using fungi such as Aspergillus itaconicus or Aspergillus terreus. For A. terreus the itaconate pathway is mostly elucidated. The generally accepted route for itaconate is via glycolysis, tricarboxylic acid cycle, and a decarboxylation of cis-aconitate to itaconate via cis-aconitate-decarboxylase. The smut fungus Ustilago maydis uses an alternative route. Cis-aconitate is converted to the thermodynamically favoured trans-aconitate via aconitate-Δ-isomerase (Adi1). trans-Aconitate is further decarboxylated to itaconate by trans-aconitate-decarboxylase (Tad1). Itaconic acid is also produced in cells of macrophage lineage. It was shown that itaconate is a covalent inhibitor of the enzyme isocitrate lyase in vitro. As such, itaconate may possess antibacterial activities against bacteria expressing isocitrate lyase (such as Salmonella enterica and Mycobacterium tuberculosis). However, cells of macrophage lineage have to "pay the price" for making itaconate, and they lose the ability to perform mitochondrial substrate-level phosphorylation. Laboratory synthesis Dry distillation of citric acid affords itaconic anhydride, which undergoes hydrolysis to itaconic acid. Reactions Upon heating, itaconic anhydride isomerizes to citraconic acid anhydride, which can be hydrolyzed to citraconic acid (2-methylmaleic acid). Steps in conversion of citric acid to citraconic acid via itaconic and aconitic acids. Partial hydrogenation of itaconic acid over Raney nickel affords 2-methylsuccinic acid. Itaconic acid is primarily used as a co-monomer in the production of acrylonitrile butadiene styrene and acrylate latexes with applications in the paper and architectural coating industry. Properties and Application of Itaconic Acid Itaconic acid is a white crystalline powder having a hygroscopic property and a specific odor. Its melting point is 167–168 °C and the boiling point is 268 °C. Water solubility is 83.1 g l−1, and a solution (80 mg l−1) of itaconic acid in pure water has a pH of 2.0. The density of itaconic acid is 1.63 (20 °C). The pKa values of itaconic acid, its two dissociation steps, are 3.84 and 5.55 (25 °C). The equilibrium constants are K1 = 1.4 × 10−4 and K2 = 3.6 × 10−6 (25 °C). Itaconic acid is mainly used in the plastic and paint industry. It is an unsaturated dicarbonic acid, and can readily be incorporated into polymers and used at a concentration of 1–5% (w/w) as a comonomer in polymers. The polymerized methyl, ethyl, or vinyl esters of itaconic acid are used as plastics, adhesives elastomers, and coatings. Styrene butadiene copolymers containing itaconic acid yield rubber-like resins of excellent strength and flexibility and water-proofing coatings with good electrical insulation. Other fields for use are synthetic fibers, lattices, detergents, and cleaners. On the other hand, several mono- and diesters of partially substituted itaconic acid possess anti-inflammatory or analgesic activities, and a special new market has opened for the use of itaconic acid pharmaceutical fields. A small quantity of itaconic acid is used as acidulant. Itaconic acid (2-methylenesuccinic acid, 1-propene-2–3-dicarboxylic acid) is an unsaturated, weak dicarboxylic acid (pKa =3.83 and 5.41), discovered in 1837 as a thermal decomposition product of citric acid. The presence of the conjugated double bond of the methylene group allows polymerization both by addition and condensation. Esterification of the two carboxylic groups with different co-monomers is also possible (Kuenz et al., 2012). These diverse properties have led to a variety of applications in the pharmaceutical, architectural, paper, paint, and medical industries such as plastics, resins, paints, synthetic fibers, plasticizers, and detergents. Recently, itaconic acid applications have penetrated the dental, ophthalmic and drug delivery fields (Hajian and Yusoff, 2015). Itaconic acid polymers could even replace the petroleum-based polyacrylic acid, which has a multi-billion dollar market (Saha et al., 2019). Not surprisingly, the US Department of Energy assigned itaconic acid as one of the top 12 most promising building block chemicals for bio-based economy in 2004 (Werpy and Petersen, 2004). Little is known about the reasons why fungi produce itaconate. Like the other organic acids, as outlined above, also itaconic acid might serve as acidifier of the environment and thus provide selective advantage for the acid-tolerant A. terreus over other micro-organisms. However, itaconic acid also has clear inhibitory properties: in macrophages of mammals, bacterial infection prompts the induction of a gene encoding a cis-aconitate decarboxylase, resulting in itaconic acid formation that inhibits bacterial metabolism as part of the immune response. The effect has been attributed to the inhibition of succinate dehydrogenase and isocitrate lyase (McFadden et al., 1971), the latter being a key enzyme of the glyoxylate cycle, required for the survival of pathogens inside a host. In turn, a few strains of these bacteria have evolved to be capable of degrading itaconate (Sasikaran et al., 2014). Itaconic acid also induces a transcription factor which is essential for protection against oxidative and xenobiotic stresses, and to attenuate inflammation (Kobayashi et al., 2013; Bambouskova et al., 2018). Whether a similar function of itaconate exists in the fungi producing it has not yet been studied. The biosynthetic pathway of itaconic acid resembles that of citric acid, the latter acid being a direct precursor of the former. The only difference is that citric acid in A. terreus is further metabolized via cis-aconitate to itaconate by cis-aconitate decarboxylase (Bonnarme et al., 1995). To this end, cis-aconitate is transported out of the mitochondria by a specific antiporter in exchange for oxaloacetate (Li et al., 2011a,b). Itaconic acid – formed upon cis-aconitate decarboxylation – is finally secreted out of mycelia by a specific cell membrane transporter. Genes encoding these three enzymes, and a fourth one encoding a transcription factor, constitute the “itaconate gene cluster” in the A. terreus genome, while the cluster is notably absent in A. niger. Although several itaconate producers have been tested, the plant pathogenic Basidiomycete Ustilago maydis (the corn smut fungus) – and particularly its low pH-stable relative Ustilago cynodontis (Hosseinpour Tehrani et al., 2019b) – seems to be the only one with a reasonable chance to become another industrial platform organism (Hosseinpour Tehrani et al., 2019a). Ustilago has developed an alternative biochemical pathway to synthetize itaconate inasmuch as cis-aconitate is converted to the thermodynamically favored trans-aconitate by aconitate-delta-isomerase. Trans-aconitate is then decarboxylated to itaconate by trans-aconitate-decarboxylase. Production of Itaconic Acid by Fermentation Processes Itaconic acid is produced in batch fermentation in a process largely similar to that of citric acid. The carbon source should be in an easily metabolizable form (glucose syroup, molasses, and crude starch hydrolysates) and diluted to approximately 10% wt. Phosphate limitation is necessary for growth restriction. Some trace metals should also be in limited amounts and this is usually achieved by treating the media with hexacyanoferratl or addition of copper. The pH is kept between 2.8 and 3.2. Lower pH values favor the formation of byproducts. Yields of 50–60% of the theoretical yield are obtained in 8–10 days [5]. For many years, there seems to be almost no research interest for the production of itaconic acid and the process remained unchanged since its introduction. The situation is different today. Itaconic acid is listed by the US Department of Energy (DOE) as one of the 12 building blocks with the highest potential to be produced by industrial biotechnology [11]. Its current low production limits its uses. Metabolic engineering strategies, as an approach for yield improvement, have not yet been applied with A. terreus, as they were restricted by the poor knowledge of the genetics of itaconic acid biosynthesis. Recently, however, three genes – crucial in itaconic acid production by A. terreus – were identified by researchers in Toegepast Natuurwetenschappelijk Onderzoek (TNO), the Netherlands [15]. Apart from the new knowledge on the genetics of biosynthesis, the development of new fermentation technologies and more sophisticated bioprocess control has led to renewed interest in improving itaconic acid production. Novel fed-batch strategies and continuous processes using immobilized cultures are being developed and investigated. Itaconic acid is a dicarboxylic acid, which is used in industry as a precursor of polymers used in plastics, adhesives, and coatings. New uses of itaconic acid-derived polymers are under active investigation. The production of itaconic acid for 2001 was quoted as 15 000 tons. There is a renewed interest in this chemical as industry searches for substitutes of petroleum-derived chemicals. Virtually all itaconic acid produced is by fermentation by specific strains of A. terreus. Itaconic acid production is a further perversion of the Krebs cycle, citrate is converted as normally into cis-aconitate, which for reasons unknown is, in some organisms, decarboxylated into itaconitate, which has no known metabolic role in the cell. The fact that different strains of Aspergillus and more generally of fungi can divert metabolic pathways to the overproduction and secretion of useful chemicals, coupled with the fact that these organisms can grow on residues of processes such as sugar and ethanol production, open the possibility of engineering pathways to produce high value chemicals through ‘green’, low polluting, waste-eliminating procedures. Production Itaconic Acid Itaconic acid is an example of a di-carbonic unsaturated acid. These acids are used as building blocks for large numbers of compounds, such as resins, paints, plastics, and synthetic fibers (acrylic plastic, super absorbants, and antiscaling agents) [67]. The CAC intermediate cis-aconitate is enzymatically processed by cis-aconitate dehycarboxylase (CadA) to produce itaconic acid [68]. At the industrial scale the most explored organism for the fermentative production of itaconic acid is Aspergillus terrus. The biosynthetic pathway of itaconic acid is like citrate biosynthesis, where the flux of the CAC is used in the catalytic conversion of cis-aconitate into itaconic acid. Thus citrate is synthesized from oxaloacetate and acetyl CoA, while oxaloacetate is synthesized from pyruvate by anaplerosis, which starts from the pyruvate that is the end product of glycolysis (Fig. 13.17). Itaconic acid (methylenesuccinic acid, C5H6O4) (Figure 17) is a white colorless crystalline, hygroscopic powder soluble in water, ethanol, and acetone. It is an unsaturated diprotic acid, which derives its unique chemical properties from the conjugation of one of its two carboxylic acid groups with its methylene group. Itaconic acid was discovered by Baup in 1837 as a product of pyrolytic distillation of citric acid. The name itaconic was devised as an anagram of aconitic. Itaconic acid is formed in fermentation of some sugars. In 1929, Kinoshita first showed the acid to be a metabolic product of Aspergillus itaconicus. A derivative of itaconic acid (trans-phenylitaconic acid) was isolated from another natural source (Artemisia argyi). The biosynthetic pathway of itaconic acid from glucose is similar to that of citric acid, which occurs via the glycolytic pathway and anaplerotic formation of oxaloacetate by CO2 fixation and via the TCA cycle (Figure 2). Itaconic acid is formed by the cytosolic enzyme aconitate decarboxylase from cis-aconitic acid. Another biosynthetic pathway from pyruvate through citramalic acid, citraconic acid, and itartaric acid also results in itaconic acid (Figure 18). In contrast to several other organic acids (e.g., citric, isocitric, lactic, fumaric, and l-malic acid) itaconic acid is used exclusively in nonfood applications, especially in the polymer industry. Itaconic acid derivatives are used in medicine, cosmetics, lubricants, thickeners, and herbicides (e.g., substituted itaconic acid anilides). Itaconic acid is produced solely by batch submerged fungal fermentation. Aspergillus terreus has been used from the 1940s in the fermentation process, which is similar to that of citric acid (see ‘Citric acid’), that is, it requires an excess of readily metabolizable sugar (glucose syrup, crude starch hydrolysates, and decationized molasses – up to 200 g l−1 sugar), continuous aeration, a low initial pH (between 3 and 5), sufficient nitrogen, high magnesium sulfate concentration (0.5%), low phosphate to limit biomass production, and a limitation in metal ions (zinc, copper, and iron). However, there exists one significant difference in that the sensitivity of this fungus to the formed acid, in contrast to A. niger, necessitates maintaining of the pH at 2.8–3.1 throughout the fermentation, in order to obtain high amounts of the acid. At present, the published production yield of itaconic acid is about 85% of theoretical, accompanied by product concentrations of about 80 g l−1 during a cultivation at 39–42 °C for 8–10 days. Recovery of itaconic acid is accomplished by first separating the fungal biomass by filtration followed by evaporation, treatment with active carbon, and crystallization and recrystallization. Actual markets for itaconic acid are currently limited because the fungal fermentation is carried out at a relatively high cost. New biotechnological approaches, such as published immobilization techniques, screening programs for other producing organisms (such as yeast), and genetic engineering of A. terreus (the annotated genome sequence of A terreus strain NIH 2624 has been publicly released), or of A. niger, could lead to higher production of itaconic acid. Also, the use of alternative substrates may reduce costs and thus open the market for new and expanded applications of this acid. This valuable acid can be produced by several organisms, such as Candida sp., Pseudozyma antarctica, and several species of Aspergillus [49], but the two most common microorganisms used are Aspergillus terreus, used in industrial processes, and Ustilago maydis, which is currently being actively investigated as a possible industrial product. The acid is used commercially as a comonomer in some synthetic rubbers (styrene-butadiene and nitrilic) and as a plasticizer in the formulation of other polymers. Its production is traditionally done using sugars as raw materials, in a technology that was developed in the first half of the 20th century [50], but that was not developed due to the low competitivity of the acid with the petrochemical acrylic acid. With the development of integrated and sustainable processes, the interest in the bioproduction of itaconic acid is renewed. Itaconic acid, or methylidenesuccinic acid, is an organic compound. This dicarboxylic acid is a white solid that is soluble in water, ethanol, and acetone. Historically, itaconic acid was obtained by the distillation of citric acid, but currently it is produced by fermentation. The name itaconic acid was devised as an anagram of aconitic acid, another derivative of citric acid. Production Since the 1960s, it is produced industrially by the fermentation of carbohydrates such as glucose or molasses using fungi such as Aspergillus itaconicus or Aspergillus terreus. For A. terreus the itaconate pathway is mostly elucidated. The generally accepted route for itaconate is via glycolysis, tricarboxylic acid cycle, and a decarboxylation of cis-aconitate to itaconate via cis-aconitate-decarboxylase. The smut fungus Ustilago maydis uses an alternative route. Cis-aconitate is converted to the thermodynamically favoured trans-aconitate via aconitate-Δ-isomerase (Adi1). trans-Aconitate is further decarboxylated to itaconate by trans-aconitate-decarboxylase (Tad1). Itaconic acid is also produced in cells of macrophage lineage. It was shown that itaconate is a covalent inhibitor of the enzyme isocitrate lyase in vitro. As such, itaconate may possess antibacterial activities against bacteria expressing isocitrate lyase (such as Salmonella enterica and Mycobacterium tuberculosis). However, cells of macrophage lineage have to "pay the price" for making itaconate, and they lose the ability to perform mitochondrial substrate-level phosphorylation. Dry distillation of citric acid affords itaconic anhydride, which undergoes hydrolysis to itaconic acid. Reactions Upon heating, itaconic anhydride isomerizes to citraconic acid anhydride, which can be hydrolyzed to citraconic acid (2-methylmaleic acid). Steps in conversion of citric acid to citraconic acid via itaconic and aconitic acids. Partial hydrogenation of itaconic acid over Raney nickel affords 2-methylsuccinic acid. Itaconic acid is primarily used as a co-monomer in the production of acrylonitrile butadiene styrene and acrylate latexes with applications in the paper and architectural coating industry. Itaconic acid is produced using A. terreus, from simple sugars. The production can be done using submerged solid fermentation, and the typical substrates are derived from sugar production, such as molasses. The accepted mechanism for itaconic acid production consists of the conversion of cis-aconitate to itaconate by an enzymatically catalyzed decarboxylation [53] (Fig. 18.6). Cis-aconitate is part of the Krebs cycle, so that the process is aerobic—actually extremely oxygen dependent, as determined by Gyamerah [54]. Calcium and zinc are important [55], as well as copper [56], and the maintenance of a low phosphate level is essential [53]. The ideal temperature is 40°C, and pH must be reduced to 2 to start the production. The process is extremely aerobic for the first 72 h of the process, with yields around 60%w/w (product/substrate) [55]. The final concentration ranges between 30 and 60 g/L depending on the substrate [56–58]. After fermentation, the broth is clarified and the free acid can be concentrated and crystallized, but if a base is used for partial neutralization during the process (which can increase the yield), it is necessary to remove the cations used in the crystallization. The production of itaconic acid in SSF is still elusive: reports describe productions on the order of 5–40 g/kg dry substrate [59]. Some of the reports that describe higher yields, around 60%, actually use a support soaked with a nutritive solution [60,61]. A comparison between synthetic liquid and solid media showed that the process in SSF has a lower conversion (16%–23%) than that of the submerged process (around 60%). There is no definite explanation for the lower production in solid-state yet, but there seems to be an excess of phosphate or the lack of essential nutrients in most solid substrates tested for itaconic acid reduction. First obtained from the distillation of citric acid, since 1960 itaconic acid has been produced by fermentation of carbohydrates by A. terreus (Mitsuyasu et al., 2009; Hajian and Yusoff, 2015). Itaconic acid has been applied in a numerous range of industries with the larger producers in the world being the USA, Japan, Russia, and China (Global Industry Analysts Inc., 2011). During the 1950s, itaconic acid was used in industrial adhesives. In that period, itaconic acid was used at an industrial scale and large amounts of it were required. It has been employed as a detergent and in shampoos, as well as in plastics, elastomers, fiberglass, and in the coating process of carpets and book covers (Mitsuyasu et al., 2009; Jin et al., 2010). Besides that itaconic acid may also be used as artificial gems and synthetic glasses (Kin et al., 1998). Lately, the applications of the compound have reached the biomedical fields, such as the ophthalmic, dental and drug delivery fields (Hajian and Yusoff, 2015). Several studies have focused on improving and optimizing the production of itaconic acid from A. terreus in recent years. The biotechnological aspects involved in the metabolic pathways of itaconic acid and the production process parameters have been reviewed by Klement and Büchs (2013). Regarding the production, Amina et al. (2013) obtained itaconic acid using oil byproduct jatropha curcas seed cake, while Li et al. (2011), Huang et al. (2014), and van der Straat et al. (2014) studied the itaconic acid production by using genetic engineering techniques. In this process the relevant pathways have been revealed and new microbial production platforms designed, contributing to an enhanced production of itaconic acid. Furthermore, the reduction of its production costs is an important aspect for itaconic acid producers, either by optimizing processes or by using cost-favorable raw materials. Itaconic acid or methylene succinic acid is a high-value platform chemical that finds application in polymer industry, wastewater treatment, and ion-exchange chromatography sector (Willke and Vorlop, 2001). It can be converted to 3-methyltetrahydrofuran that has superior emission and combustion properties when compared to gasoline. Industrial production of itaconic acid is carried out with A. terreus using glucose as the sole carbon source. Itaconic acid production by metabolically engineered Neurospora crassa using lignocellulosic biomass was evaluated by Zhao et al. (2018). Cis-aconitic acid decarboxylase gene was heterologously expressed in N. crassa to synthesize itaconic acid. The engineered strain was capable of producing itaconic acid (20.41 mg/L) directly from lignocellulosic biomass. Itaconic acid production from biomass hydrolyzate using Aspergillus strains was reported by Jiménez-Quero et al. (2016). Acid and enzymatic hydrolyzates were evaluated for the production of itaconic acid. Maximum itaconic acid production (0.14%) was observed when submerged fermentation was carried out with corncob hydrolyzate by A. oryzae. The study reveals the possibility of SSF of biomass for the production of itaconic acid. Klement et al. (2012) evaluated itaconic acid production by Ustilago maydis from hemicellulosic fraction of pretreated beech wood. One of the advantages of U. maydis is that the strain grows as yeast-like single cells, and it can survive under high osmotic stress. The study revealed that under mild pretreatment conditions, U. maydis would be a promising candidate for itaconic acid production. Fine tuning of pretreatment conditions should be carried out for the improved production of itaconic acid. Production Itaconic Acid Itaconic acid is an example of a di-carbonic unsaturated acid. These acids are used as building blocks for large numbers of compounds, such as resins, paints, plastics, and synthetic fibers (acrylic plastic, super absorbants, and antiscaling agents) [67]. The CAC intermediate cis-aconitate is enzymatically processed by cis-aconitate dehycarboxylase (CadA) to produce itaconic acid [68]. At the industrial scale the most explored organism for the fermentative production of itaconic acid is Aspergillus terrus. The biosynthetic pathway of itaconic acid is like citrate biosynthesis, where the flux of the CAC is used in the catalytic conversion of cis-aconitate into itaconic acid. Thus citrate is synthesized from oxaloacetate and acetyl CoA, while oxaloacetate is synthesized from pyruvate by anaplerosis, which starts from the pyruvate that is the end product of glycolysis (Fig. 13.17) [69]. Itaconic acid (IA) can be used: • As a comonomer in the polymerization of polyacrylonitrile (PAN) to promote the thermo-oxidative stabilization of polymer.[1] • In combination with acrylamide to form (poly[acrylamide-co-(itaconicacid)]) to synthesize biodegradable superabsorbent polymers.[2] • To synthesize biobased polyester composite in fabric industry. Itaconic acid is an unsaturated dicarbonic acid which has a high potential as a biochemical building block, because it can be used as a monomer for the production of a plethora of products including resins, plastics, paints, and synthetic fibers. Some Aspergillus species, like A. itaconicus and A. terreus, show the ability to synthesize this organic acid and A. terreus can secrete significant amounts to the media (>80 g/L). However, compared with the citric acid production process (titers >200 g/L) the achieved titers are still low and the overall process is expensive because purified substrates are required for optimal productivity. Itaconate is formed by the enzymatic activity of a cis-aconitate decarboxylase (CadA) encoded by the cadA gene in A. terreus. Cloning of the cadA gene into the citric acid producing fungus A. niger showed that it is possible to produce itaconic acid also in a different host organism. This review will describe the current status and recent advances in the understanding of the molecular processes leading to the biotechnological production of itaconic acid. Itaconic acid (2-methylidenebutanedioic acid) is an unsaturated di-carbonic acid. It has a broad application spectrum in the industrial production of resins and is used as a building block for acrylic plastics, acrylate latexes, super-absorbents, and anti-scaling agents (Willke and Vorlop, 2001; Okabe et al., 2009). Since the 1960s the production of itaconic acid is achieved by the fermentation with Aspergillus terreus on sugar containing media (Willke and Vorlop, 2001). Although also other microorganisms like Ustilago zeae (Haskins et al., 1955), U. maydis, Candida sp. (Tabuchi et al., 1981), and Rhodotorula sp. (Kawamura et al., 1981) were found to produce itaconic acid, A. terreus is still the dominant production host, because so far only bred strains of this species can reach levels of up to 80–86 g/L (Okabe et al., 2009; Kuenz et al., 2012). Since the 1990s, itaconic acid as a renewable material is attracting a lot of interest. Currently, the worldwide production capacity of itaconic acid is expected to be about 50 kt per year, facing a demand of about 30 kt (Shaw, 2013, Itaconix Corporation, personal communication). Especially, for the production of polymers it is of interest, because in the future it can function as a substitute for acrylic and methacrylic acid used for the production of plastics (Okabe et al., 2009). However, these applications require an even lower price of the starting material. The current knowledge about the biotechnological production of itaconic acid was recently reviewed (Willke and Vorlop, 2001; Okabe et al., 2009). The latter review covers the industrial production of itaconic acid and the applications of this product. Therefore, we focus in this report on the recent advances with an emphasis on the biochemistry of the process and new genetic engineering targets. For rational strain improvement, it is essential to understand the underlying biological concepts and biochemical pathways leading to the production of this important organic acid in microorganisms. Biosynthesis Pathway Kinoshita (1932) recognized that a filamentous fungus was able to produce itaconic acid and consequently described this species as A. itaconicus. The biosynthesis of itaconic acid was for a long time hotly debated, because it was not clear whether itaconic acid arises from a pathway including parts of the tricarboxylic acid (TCA) cycle or an alternative pathway via citramalate or the condensation of acetyl-CoA. Bentley and Thiessen (1957a) proposed a pathway for the biosynthesis of itaconic acid, which is depicted in Figure 1. Starting from a sugar substrate like glucose the carbon molecules are processed via glycolysis to pyruvate. Then the pathway is split and part of the carbon is metabolized to Acetyl-CoA releasing a carbon dioxide molecule. The other part is converted to oxaloacetate so that the previously released carbon dioxide molecule is again incorporated. In the first steps of the citric acid cycle, citrate and cis-aconitate are formed. In the last step, the only itaconic acid pathway dedicated step, cis-aconitate decarboxylase (CadA) forms itaconic acid releasing carbon dioxide. This pathway was confirmed by tracer experiments with 14C and 13C labeled substrates (Bentley and Thiessen, 1957a; Winskill, 1983; Bonnarme et al., 1995) and also the necessary enzymatic activities have been all determined (Jaklitsch et al., 1991). The formation of carboxylic acids, like citric and itaconic acid, involves the shuttling of intermediate metabolites between different intracellular compartments and utilizes the different enzymatic capabilities of the respective compartment. In case of itaconic acid the compartmentalization of the pathway was analyzed by fractionized cell extracts distinguishing the enzymatic activity of a mitochondrial from a cytosolic enzyme. It was found that the key enzyme of the pathway, CadA, is not located in the mitochondria but in the cytosol (Jaklitsch et al., 1991), whereas the enzymes preceding in the pathway, namely citrate synthase and aconitase, are found in the mitochondria. However, a residual level of aconitase and citrate synthase activity is also found in the cytosolic fraction. The proposed mechanism is that cis-aconitate is transported via the malate–citrate antiporter into the cytosol (Jaklitsch et al., 1991). However, so far it was not shown whether cis-aconitate makes use of the mitochondrial malate–citrate antiporter or uses another mitochondrial carrier protein to be translocated to the cytosol. Besides A. terreus, itaconic acid is known to be produced also by other fungi like U. zeae (Haskins et al., 1955), U. maydis (Haskins et al., 1955; Klement et al., 2012), Candida sp. (Tabuchi et al., 1981), and Rhodotorula sp. (Kawamura et al., 1981). No further investigations exist about the underlying reaction principles leading to itaconic acid formation in those species. However, recent evidence (Strelko et al., 2011; Voll et al., 2012) points into the direction that CadA activity constitutes the general pathway toward the formation of itaconic acid in nature. Very recently, itaconic acid was detected in mammalian cells, where it was found in macrophage-derived cells (Strelko et al., 2011). Those cells also possess a CadA activity and have the ability to form itaconic acid de novo. But, up to now no specific gene encoding this enzymatic activity was identified in mammalian cells. However, the physiological role of itaconic acid in mammalian cells is still unknown. Strelko et al. (2011) speculate on the role of itaconic acid as an inhibitor of metabolic pathways, because it is described as an enzymatic inhibitor. On the one hand, itaconic acid is known to inhibit isocitrate lyase (Williams et al., 1971; McFadden and Purohit, 1977), which is the crucial part of the glyoxylate shunt, and thus can act as an antibacterial agent. On the other hand, itaconic acid can inhibit fructose-6-phosphate 2-kinase (Sakai et al., 2004) and thus have a direct influence on the central carbon metabolism. In rats it was shown that a itaconate diet leads to a reduced visceral fat accumulation, because of a suppressed glycolytic flux (Sakai et al., 2004). Itaconic Acid Pathway Specific Enzymes and Genes The reaction catalyzed by the cis-aconitic acid decarboxylase was already described in 1957 (Bentley and Thiessen, 1957a,b). Subsequently performed 13C and 14C labeling experiments (Winskill, 1983; Bonnarme et al., 1995) confirmed the reaction scheme depicted in Figure 2. Itaconic acid is formed by an allylic rearrangement and decarboxylation from cis-aconitic acid removing either carbon C1 or C5 from the starting citric acid molecule (because of the symmetry of the molecule). Catabolization of Itaconic Acid Much is known about the biosynthesis of itaconic acid and the underlying enzymatic mechanisms, but for a complete biochemical picture of a certain metabolite, also the knowledge about its degradation is necessary. Unfortunately, the information about the degradation pathway of itaconic acid is sc
ITACONIC ACID
A product of the fermentationof the flamentous fungus Aspergillus niger.
Itaconic acid is usedcommercially in the production ofadhesives and paints.
Itaconic acid that is methacrylic acid in which one of the methyl hydrogens is substituted by a carboxylic acid group.

CAS: 97-65-4
MF: C5H6O4
MW: 130.1
EINECS: 202-599-6

Itaconic acid, or methylidenesuccinic acid, is an organic compound.
Itaconic acid is a white solid that is soluble in water, ethanol, and acetone.
Historically, Itaconic acid was obtained by the distillation of citric acid, but currently it is produced by fermentation.
The name Itaconic acid was devised as an anagram of aconitic acid, another derivative of citric acid.

Itaconic acid is an unsaturated binary organic acid.
Chemical properties are more active, easy to polymerize, and can also be copolymerized with other monomers, such as acrylic, succinic acid, and styrene.
Soluble in water, ethanol and acetone, slightly soluble in chloroform, benzene and ether.
Itaconic acid has a special smell and can sublimate under vacuum.
Itaconic acid can also be copolymerized with other monomers.
Itaconic acid is not easy to volatilize and can be decomposed by overheating.

Itaconic acid Chemical Properties
Melting point: 165-168 °C (lit.)
Boiling point: 268°C
Density: 1.573 g/mL at 25 °C (lit.)
Vapor pressure: 0.0000115 Pa (20 °C)
Refractive index: 1.4980 (estimate)
Fp: 268°C
Storage temp.: Store below +30°C.
Solubility: 77.49g/l
Form: Crystalline Powder or Crystals
pka: 3.85(at 25℃)
Specific Gravity: 1.573
Color: White to light beige
PH: 3.5(1 mM solution);2.95(10 mM solution);2.43(100 mM solution);
Water Solubility: Soluble in water, acetone, methanol, hexane and ethanol.
Slightly soluble in benzene, chloroform, carbon disulfide and petroleum ether.
Sensitive: Hygroscopic
Merck: 14,5242
BRN: 1759501
Stability: Light Sensitive
InChIKey: LVHBHZANLOWSRM-UHFFFAOYSA-N
LogP: -0.301 at 20℃
CAS DataBase Reference: 97-65-4(CAS DataBase Reference)
NIST Chemistry Reference: Itaconic acid (97-65-4)
EPA Substance Registry System: Itaconic acid (97-65-4)

Uses
Itaconic acid is used in the preparation of acrylonitrile-butadiene-styrene and acrylate latexes.
Itaconic acid is also used to prepare poly-itaconic acid, resins biofuel components and ionomer cements.
Itaconic acid finds application in the textile, chemical and pharmaceutical industries.
Itaconic acid is also used as an additive in fibers and ion exchange resins to increase abrasion, waterproofing, physical resistance, dying affinity and better duration.
Further, Itaconic acid acts as a co-monomer used in the preparation of acrylic fibers and rubbers, reinforced glass fiber, artificial diamonds and lens.
In addition to this, Itaconic acid acts as a binder and sizing agent in non-weaving fibers.
The major uses for Itaconic acid are in copolymerizations, resins, plasticizers, and as lube oil additives.

1. Itaconic acid and its polymer add a small amount of natural substances can be made into efficient deodorant, with ammonia, amine alkaline odor and hydrogen sulfide and other acidic odor reaction, can also be made with deodorant function of paper, plastic film and other products.

2. Itaconic acid and styrene and butadiene copolymerization can be made into S.B.R latex, can be used for paper coating, so that the paper is strong and strong and the printing pattern is bright; Used for metal, concrete coating, easy to color and not affected by natural conditions; For paint additives can improve the quality of paint; For carpet sizing can make the synthetic fiber carpet durable.

3. Itaconic acid and acrylic acid or methacrylic acid or its ester polymerization resin, can be used for surface coating and emulsion paint.
As a leather coating can increase the plasticity of leather; Used for automobile, electrical appliances, cold storage coatings with strong adhesion, color and appearance and resistance to adverse weather and other advantages; Used as electrophoretic coating with excellent adhesion; the addition of polyvalent metal oxide can be made into a dental adhesive with good extrusion performance, strong adhesion and good physiological adaptability.
The addition of chloroalkyl dimethyl benzyl ammonium chloride can be made into a water-soluble coating for food packaging materials, bacterial contamination of the packaging surface can be reduced.

4. Itaconic acid esters can be used in paint, weak acid ion exchange resin, lubricating oil additives, binders and plasticizers, powder pressure plastic and sealant.

5. Itaconic acid to form other derivatives can be used as pharmaceuticals, cosmetics reagents, lubricants, thickeners, herbicides and improve the performance of silk and wool fabrics.

6. Itaconic acid is a raw material for the production of citraconic acid, mesaconic acid, itaconic anhydride, etc.

Itaconic acid used as comonomer of polyacrylonitrile fiber, can also be used in the preparation of plasticizers, lubricant additives, etc.
Preparation of synthetic fiber, an important monomer of synthetic resin and plastic, ion exchange resin; Can also be used as a carpet mounting agent, paper coating agent, binder, paint dispersion latex.
Ester Derivatives of Itaconic acid can be used for Copolymerization of styrene and the like or plasticizers of polyvinyl chloride.

Production
Since the 1960s, Itaconic acid is produced industrially by the fermentation of carbohydrates such as glucose or molasses using fungi such as Aspergillus itaconicus or Aspergillus terreus.

For A. terreus the Itaconic acid pathway is mostly elucidated.
The generally accepted route for Itaconic acid is via glycolysis, tricarboxylic acid cycle, and a decarboxylation of cis-aconitate to itaconate via cis-aconitate-decarboxylase.

The smut fungus Ustilago maydis uses an alternative route.
Cis-aconitate is converted to the thermodynamically favoured trans-aconitate via aconitate-Δ-isomerase (Adi1).
trans-Aconitate is further decarboxylated to itaconate by trans-aconitate-decarboxylase.

Itaconic acid is also produced in cells of macrophage lineage.
Itaconic acid was shown that itaconate is a covalent inhibitor of the enzyme isocitrate lyase in vitro.
As such, itaconate may possess antibacterial activities against bacteria expressing isocitrate lyase (such as Salmonella enterica and Mycobacterium tuberculosis).

However, cells of macrophage lineage have to "pay the price" for making itaconate, and they lose the ability to perform mitochondrial substrate-level phosphorylation.

Laboratory synthesis
Dry distillation of citric acid affords itaconic anhydride, which undergoes hydrolysis to itaconic acid.

Synonyms
Itaconic acid
97-65-4
2-Methylenesuccinic acid
METHYLENESUCCINIC ACID
2-methylidenebutanedioic acid
Methylenebutanedioic acid
Propylenedicarboxylic acid
Butanedioic acid, methylene-
itaconate
2-Propene-1,2-dicarboxylic acid
Succinic acid, methylene-
2-methylenebutanedioic acid
MFCD00004260
AI3-16901
25119-64-6
2-Methylene-Succinic Acid
CHEMBL359159
butanedioic acid, 2-methylene-
DTXSID2026608
CHEBI:30838
NSC3357
NSC-3357
Q4516562YH
DTXCID006608
CAS-97-65-4
HSDB 5308
methylene-butanedioicaci
NSC 3357
EINECS 202-599-6
Methylenesuccinate
UNII-Q4516562YH
ITN
Methylenebutanedioate
2-Methylenesuccinate
Methylensuccinic Acid
Propylenedicarboxylate
2-methylenebutanedioate
Itaconic acid, >=99%
bmse000137
Probes1_000076
Probes2_000247
EC 202-599-6
2-Methylenesuccinic acid #
ITACONIC ACID [MI]
NCIStruc1_001783
NCIStruc2_000502
2-methylene-butanedioic acid
NCIOpen2_004822
SCHEMBL21523
ITACONIC ACID [INCI]
2-Propene-1,2-dicarboxylate
Itaconic acid, analytical standard
Succinic acid, methylene- (8CI)
HY-Y0520
Tox21_201299
Tox21_303071
BBL011584
BDBM50036216
LMFA01170063
s3095
STL163322
AKOS000118895
2-Hydroxy-3-Naphthoyl-2-Naphthylamine
SB67306
Butanedioic acid,ethylidene-,(E)-(9ci)
NCGC00249019-01
NCGC00257141-01
NCGC00258851-01
AS-11816
CS-0015302
FT-0627543
M0223
EN300-18045
C00490
E80791
Q903311
Z57127539
F2191-0234
2-METHYLENE,1,4-BUTANEDIOIC ACID (ITACONIC ACID)
53EEC7A3-4846-4588-BBC9-CB8846377B96
ITACONIC ACID (METHYLIDENESUCCINIC ACID)

Itaconic acid, also known as methylidenesuccinic acid, is a organic compound with the molecular formula C5H6O4.
Itaconic acid (Methylidenesuccinic acid) is a dicarboxylic acid and an unsaturated compound.
The IUPAC name for itaconic acid is 2-methylidenebutanedioic acid.

CAS Number: 97-65-4
EC Number: 202-599-6

Itaconic acid, Methylidenebutanedioic acid, 2-Methylidenebutanedioic acid, Methylenesuccinic acid, 2-Methylenebutanedioic acid, Dihydroxymethylene succinic acid, Methylenebutanedioic acid, Methylenesuccinic acid, Methylenesuccinic acid, Dihydroxy, Methylenesuccinic acid, cis-Methylenesuccinic acid, Dihydroxydihydrofurandione, Dihydroxy-methylene succinic acid, Methylenesuccinic acid, Methylenesuccinic acid, Maleic acid anhydride, Propylene dicarboxylic acid, Methylenesuccinic acid, Disodium itaconate, 2-Hydroxy-2-methylpropionic acid, 3-Hydroxy-2,2-dimethyl-4-oxobutanoic acid, Itaconnic acid, Acide itaconique, Itakonova kyselina, Itakonsav, Itakonska kiselina, Itakonsyra, Méthylidènebutanedioïque acide, Zouten van itaconzuur, Methylenbutandisaeure, Itakonsav, Itaconnic acid, Itaconic acid



APPLICATIONS


Itaconic acid (Methylidenesuccinic acid) finds extensive use as a precursor in the production of various polymers.
One notable application is its role in the synthesis of polyitaconic acid, a polymer with diverse applications.

Itaconic acid (Methylidenesuccinic acid) is employed in the creation of poly(methyl methacrylate), a widely used transparent plastic.
Itaconic acid (Methylidenesuccinic acid) serves as a monomer in the preparation of copolymers with other compounds for tailored properties.

Itaconic acid (Methylidenesuccinic acid) has applications in the formulation of superabsorbent polymers used in diapers and hygiene products.
Itaconic acid (Methylidenesuccinic acid) is utilized in the creation of resins and coatings with enhanced performance characteristics.

In the textile industry, it contributes to the development of coatings for fabrics and fibers.
Itaconic acid (Methylidenesuccinic acid) is explored for its potential in the production of biodegradable polymers, aligning with sustainable practices.
Itaconic acid (Methylidenesuccinic acid) is employed in the synthesis of graft copolymers with improved material properties.

Itaconic acid (Methylidenesuccinic acid) plays a role in the development of adhesives with enhanced bonding characteristics.
Itaconic acid (Methylidenesuccinic acid) finds applications in the creation of ion-exchange resins for water treatment processes.

In the pharmaceutical industry, Itaconic acid (Methylidenesuccinic acid) is used in the production of controlled-release drug formulations.
Itaconic acid (Methylidenesuccinic acid) is investigated for its use in the creation of biocompatible materials for medical applications.

Itaconic acid (Methylidenesuccinic acid) contributes to the development of eco-friendly and sustainable packaging materials.
Itaconic acid (Methylidenesuccinic acid) is employed in the preparation of biodegradable and water-soluble polymers for diverse applications.
Itaconic acid (Methylidenesuccinic acid) is utilized in the development of coatings for controlled-release fertilizers in agriculture.
In the cosmetic and personal care industry, it is used in the formulation of certain skincare products.

Itaconic acid (Methylidenesuccinic acid) has applications in the creation of specialty chemicals and additives for various industries.
Itaconic acid (Methylidenesuccinic acid) is explored for its use in the production of bio-based plastics with reduced environmental impact.

Itaconic acid (Methylidenesuccinic acid) is employed in the synthesis of environmentally friendly alternatives to traditional petroleum-based materials.
In the field of dentistry, it is studied for potential applications in the development of dental materials.
Itaconic acid (Methylidenesuccinic acid) contributes to the creation of materials with enhanced thermal and mechanical properties.

Itaconic acid (Methylidenesuccinic acid) is utilized in the preparation of water-soluble polymers for industrial processes.
Itaconic acid (Methylidenesuccinic acid) finds applications in the creation of coatings for controlled drug release in medical devices.
Its versatility allows for applications in research, serving as a building block for innovative materials and technologies.

Itaconic acid (Methylidenesuccinic acid) is employed in the production of biodegradable and environmentally friendly plastics.
Itaconic acid (Methylidenesuccinic acid) finds applications in the creation of water-soluble polymers for various industrial processes.
Itaconic acid (Methylidenesuccinic acid) contributes to the development of adhesives with improved strength and durability.

In the field of wastewater treatment, it is used in the formulation of flocculants for solid-liquid separation.
Itaconic acid (Methylidenesuccinic acid) is utilized in the synthesis of polymers with enhanced rheological properties for specific applications.
Itaconic acid (Methylidenesuccinic acid) plays a role in the creation of ion-sensitive hydrogels used in controlled drug delivery systems.

Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the production of conductive polymers for electronics.
Itaconic acid (Methylidenesuccinic acid) is utilized in the development of biocompatible materials for tissue engineering and medical implants.

Itaconic acid (Methylidenesuccinic acid) contributes to the creation of coatings for controlled drug release in pharmaceuticals.
In the food industry, Itaconic acid (Methylidenesuccinic acid) is employed as a chelating agent and stabilizer for certain food products.
Itaconic acid (Methylidenesuccinic acid) finds applications in the formulation of corrosion inhibitors for metal protection.
Itaconic acid (Methylidenesuccinic acid) is used in the creation of specialty chemicals such as plasticizers and surfactants.

Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the development of bio-based lubricants.
Itaconic acid (Methylidenesuccinic acid) contributes to the creation of bio-based and sustainable alternatives to traditional petroleum-derived chemicals.
Itaconic acid (Methylidenesuccinic acid) is employed in the preparation of water-based paints and coatings for eco-friendly applications.
Itaconic acid (Methylidenesuccinic acid) is utilized in the development of biomaterials for drug delivery and medical applications.

Itaconic acid (Methylidenesuccinic acid) plays a role in the creation of environmentally friendly inks and dyes.
Itaconic acid (Methylidenesuccinic acid) is explored for its use in the development of bio-based and biodegradable detergents.

Itaconic acid (Methylidenesuccinic acid) contributes to the production of bio-based plasticizers for polymeric materials.
Itaconic acid (Methylidenesuccinic acid) finds applications in the creation of responsive materials for sensors and actuators.
In the oil and gas industry, it is used in the formulation of chemicals for enhanced oil recovery.
Itaconic acid (Methylidenesuccinic acid) is employed in the creation of specialty coatings for corrosion protection in various industries.
Itaconic acid (Methylidenesuccinic acid) plays a role in the formulation of polymers with stimuli-responsive behavior.

Itaconic acid (Methylidenesuccinic acid) is utilized in the development of bio-based and sustainable materials for 3D printing.
Itaconic acid (Methylidenesuccinic acid) contributes to the research and development of innovative materials with diverse applications across industries.

Itaconic acid (Methylidenesuccinic acid) is utilized in the creation of environmentally friendly and sustainable adhesives.
Itaconic acid (Methylidenesuccinic acid) plays a crucial role in the formulation of biodegradable and water-soluble films.
Itaconic acid (Methylidenesuccinic acid) finds applications in the production of bio-based and eco-friendly detergents.

In the field of agriculture, it is employed in the development of environmentally sustainable agrochemicals.
Itaconic acid (Methylidenesuccinic acid) contributes to the creation of polymers used in the manufacturing of biodegradable packaging materials.
Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the production of bio-based and non-toxic herbicides.

Itaconic acid (Methylidenesuccinic acid) is used in the synthesis of polymers with applications in controlled drug release systems.
Itaconic acid (Methylidenesuccinic acid) finds utility in the creation of bio-based and sustainable materials for water treatment.

Itaconic acid (Methylidenesuccinic acid) is employed in the formulation of coatings for controlled-release fertilizers in agricultural practices.
Itaconic acid (Methylidenesuccinic acid) plays a role in the development of environmentally friendly and sustainable paints and coatings.
Itaconic acid (Methylidenesuccinic acid) contributes to the creation of biomaterials with applications in tissue engineering.
In the textile industry, it is utilized in the creation of sustainable finishes for fabrics.

Itaconic acid (Methylidenesuccinic acid) is explored for its use in the development of bio-based and eco-friendly lubricants.
Itaconic acid (Methylidenesuccinic acid) is employed in the formulation of bio-based and sustainable drilling fluids in the oil and gas sector.
Itaconic acid (Methylidenesuccinic acid) plays a role in the creation of bio-based and non-toxic corrosion inhibitors.

Itaconic acid (Methylidenesuccinic acid) is used in the development of sustainable and eco-friendly fuel additives.
Itaconic acid (Methylidenesuccinic acid) contributes to the formulation of bio-based and environmentally friendly hydraulic fluids.
In the field of cosmetics, it is explored for its use in the development of sustainable skincare products.

Itaconic acid (Methylidenesuccinic acid) finds applications in the creation of bio-based and non-toxic cleaning agents.
Itaconic acid (Methylidenesuccinic acid) is utilized in the production of sustainable and biodegradable mulching films for agriculture.

Itaconic acid (Methylidenesuccinic acid) contributes to the formulation of eco-friendly and biodegradable coatings for food packaging.
Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the creation of sustainable and biocompatible medical implants.
Itaconic acid (Methylidenesuccinic acid) plays a role in the synthesis of bio-based and non-toxic plasticizers for polymers.

Itaconic acid (Methylidenesuccinic acid) is used in the formulation of bio-based and eco-friendly inks for printing applications.
Itaconic acid (Methylidenesuccinic acid) contributes to ongoing research efforts aimed at developing sustainable solutions across various industries.

Itaconic acid (Methylidenesuccinic acid) is employed in the formulation of bio-based and environmentally friendly anti-scaling agents for water treatment.
Itaconic acid (Methylidenesuccinic acid) finds applications in the creation of sustainable and biodegradable soil conditioners for agriculture.
Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the development of eco-friendly and non-toxic corrosion-resistant coatings.
In the realm of biomaterials, it is utilized for creating bio-based and biocompatible scaffolds for tissue regeneration.

Itaconic acid (Methylidenesuccinic acid) contributes to the formulation of sustainable and non-toxic de-icing agents for winter road maintenance.
Itaconic acid (Methylidenesuccinic acid) plays a role in the development of bio-based and environmentally friendly flame retardants for materials.

In the construction industry, it is used in the formulation of sustainable and fire-resistant building materials.
Itaconic acid (Methylidenesuccinic acid) is employed in the creation of bio-based and non-toxic concrete admixtures for construction applications.
Itaconic acid (Methylidenesuccinic acid) finds applications in the production of eco-friendly and biodegradable polymeric films for food packaging.

Itaconic acid (Methylidenesuccinic acid) contributes to the formulation of sustainable and non-toxic ink resins for printing applications.
Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the development of bio-based and environmentally friendly lubricating oils.
In the synthesis of bio-based polymers, it is utilized to create sustainable and high-performance materials for various industries.
Itaconic acid (Methylidenesuccinic acid) is employed in the formulation of eco-friendly and non-toxic pest control agents for agriculture.

Itaconic acid (Methylidenesuccinic acid) plays a role in the creation of sustainable and biodegradable surfactants for cleaning products.
Itaconic acid (Methylidenesuccinic acid) is used in the development of bio-based and non-toxic foaming agents for various applications.
Itaconic acid (Methylidenesuccinic acid) contributes to the formulation of sustainable and non-toxic plastic additives for enhancing material properties.

Itaconic acid (Methylidenesuccinic acid) is explored for its use in the creation of bio-based and environmentally friendly textiles and fabrics.
In the automotive industry, it is employed in the formulation of bio-based and non-toxic additives for lubricants and coolants.

Itaconic acid (Methylidenesuccinic acid) plays a role in the development of sustainable and non-toxic coatings for automotive applications.
Itaconic acid (Methylidenesuccinic acid) is used in the creation of bio-based and environmentally friendly adhesives for wood and composite materials.

Itaconic acid (Methylidenesuccinic acid) contributes to the formulation of sustainable and non-toxic sealants for construction applications.
Itaconic acid (Methylidenesuccinic acid) finds applications in the production of eco-friendly and non-toxic colorants for various industries.

Itaconic acid (Methylidenesuccinic acid) is explored for its potential use in the development of bio-based and sustainable leather tanning agents.
In the electronics industry, it is employed in the formulation of bio-based and non-toxic additives for electronic materials.
Itaconic acid (Methylidenesuccinic acid) plays a role in the creation of sustainable and non-toxic additives for the manufacturing of renewable energy devices.



DESCRIPTION


Itaconic acid, also known as methylidenesuccinic acid, is a organic compound with the molecular formula C5H6O4.
Itaconic acid (Methylidenesuccinic acid) is a dicarboxylic acid and an unsaturated compound.
The IUPAC name for itaconic acid is 2-methylidenebutanedioic acid.

Itaconic acid (Methylidenesuccinic acid) is a crystalline, white, odorless solid at room temperature.
Itaconic acid (Methylidenesuccinic acid) is known for its unsaturated nature due to the presence of a double bond in its molecular structure.

Itaconic acid (Methylidenesuccinic acid) has a chemical formula of C5H6O4, reflecting its composition as a five-carbon organic compound.
Itaconic acid (Methylidenesuccinic acid) is soluble in water, contributing to its versatility in various applications.

Itaconic acid (Methylidenesuccinic acid) is derived from certain fungi, particularly in the Aspergillus genus, where it occurs naturally.
In industrial processes, Itaconic acid (Methylidenesuccinic acid) is often produced through fermentation, using microorganisms like Aspergillus terreus.

Itaconic acid (Methylidenesuccinic acid) serves as a precursor in the synthesis of polymers, contributing to the production of biodegradable materials.
Itaconic acid (Methylidenesuccinic acid) is recognized for its potential in the development of sustainable and environmentally friendly products.

Itaconic acid (Methylidenesuccinic acid) exhibits two carboxylic acid groups, making it a dicarboxylic acid with acidic properties.
Itaconic acid (Methylidenesuccinic acid) is employed in the synthesis of various chemicals, showcasing its versatility in organic chemistry.
Itaconic acid (Methylidenesuccinic acid) has found applications in the production of certain resins and coatings.

Itaconic acid (Methylidenesuccinic acid) is a key component in the creation of polyitaconic acid and poly(methyl methacrylate), important polymers in the industry.
Its structure features a double bond between carbon atoms, contributing to its role as a building block in chemical synthesis.
Itaconic acid (Methylidenesuccinic acid) is investigated for its potential use in the development of biodegradable polymers, aligning with sustainable practices.

Itaconic acid (Methylidenesuccinic acid) is known for its mild acidic properties and is considered safe for certain applications in personal care products.
Itaconic acid (Methylidenesuccinic acid) has been studied for its role in the creation of environmentally friendly alternatives to traditional plastics.

Itaconic acid (Methylidenesuccinic acid) is characterized by its stable solid form, making it suitable for various processing methods.
Itaconic acid (Methylidenesuccinic acid) contributes to the creation of polymers with unique properties, such as high biodegradability.
Its molecular structure includes a distinctive methylene group, influencing its reactivity in chemical reactions.

The versatility of Itaconic acid (Methylidenesuccinic acid) extends to its applications in both academia and industrial settings.
Itaconic acid (Methylidenesuccinic acid) exhibits potential as a platform chemical for the development of new materials and products.
Itaconic acid (Methylidenesuccinic acid) has gained attention for its role in sustainable practices, addressing environmental concerns in the chemical industry.

Itaconic acid (Methylidenesuccinic acid) is an essential component in the research and development of green and bio-based technologies.
Its biocompatibility has made it a subject of interest in various fields, including medical and pharmaceutical research.
Itaconic acid, with its unique properties, stands at the forefront of innovations aimed at creating more sustainable and eco-friendly materials.



PROPERTIES


Chemical Formula: C5H6O4
Molecular Weight: 130.10 g/mol
Appearance: Crystalline, white, odorless solid
Solubility: Soluble in water
Melting Point: Approximately 165-168°C
Boiling Point: Decomposes before boiling
Density: 1.45 g/cm³
pH: Typically acidic
Structural Feature: Contains a double bond in its molecular structure, making it unsaturated
Functional Groups: Dicarboxylic acid with two carboxylic acid groups (-COOH)
Isomeric Forms: Exists in cis and trans isomeric forms due to the presence of the double bond.
Biodegradability: Exhibits biodegradability, making it environmentally friendly.
Reactivity: Exhibits reactivity in polymerization reactions.
Source: Can be derived from certain fungi, particularly Aspergillus terreus, or produced synthetically.



FIRST AID


Inhalation:

If Itaconic acid fumes are inhaled, move the affected person to an area with fresh air.
If the person is experiencing difficulty breathing, provide artificial respiration.
Seek medical attention promptly, especially if respiratory symptoms persist.


Skin Contact:

Remove contaminated clothing and immediately wash the affected skin with plenty of water.
Use mild soap if available and rinse thoroughly.
If irritation or redness persists, seek medical attention.
Contaminated clothing should be removed and washed before reuse.


Eye Contact:

Flush the eyes with gently flowing water for at least 15 minutes, holding the eyelids open.
Seek immediate medical attention if irritation, redness, or other symptoms persist.
Remove contact lenses if present and easily removable after the initial flushing.


Ingestion:

If Itaconic acid is ingested, do not induce vomiting unless directed to do so by medical personnel.
Rinse the mouth thoroughly with water if the person is conscious and able to swallow.
Seek medical attention immediately.
Provide medical personnel with information on the quantity ingested, the time of ingestion, and the person's overall health condition.


General First Aid Tips:

Always wear appropriate personal protective equipment (PPE) when working with or handling Itaconic acid to minimize the risk of exposure.
If providing first aid, ensure your safety first and avoid direct contact with the chemical.
Keep emergency contact information, including the number for poison control, readily available in the workplace.
If someone exhibits signs of distress or severe symptoms, call for emergency medical assistance immediately.
Follow any additional first aid measures recommended by medical professionals based on the specific circumstances of exposure.



HANDLING AND STORAGE


Handling:

Personal Protective Equipment (PPE):
Wear appropriate PPE, including chemical-resistant gloves, safety goggles, and a laboratory coat or protective clothing.
Use a fume hood or work in a well-ventilated area to minimize inhalation exposure.

Avoidance of Contact:
Minimize skin contact and avoid eye contact with Itaconic acid.
In case of potential exposure, wash hands thoroughly with soap and water before eating, drinking, or using the restroom.

Inhalation Precautions:
Use local exhaust ventilation systems to control airborne concentrations.
If working with high concentrations, consider using respiratory protection equipment.

Storage Temperature:
Store Itaconic acid in a cool, dry place away from heat sources.
Maintain temperatures within the recommended range to prevent degradation.

Handling Equipment:
Use corrosion-resistant equipment and containers, such as those made of stainless steel or glass.
Ensure that all handling equipment is in good condition to prevent leaks or spills.

Avoid Mixing:
Avoid mixing Itaconic acid with incompatible substances, such as strong bases, reducing agents, and reactive metals.

Emergency Equipment:
Have emergency equipment, such as an eye wash station and safety shower, readily available in the work area.


Storage:

Container Type:
Store Itaconic acid in tightly sealed containers to prevent moisture absorption and contamination.
Use containers made of materials compatible with the chemical.

Separation:
Store Itaconic acid away from incompatible materials to prevent cross-contamination.

Labeling:
Clearly label storage containers with the chemical name, hazard information, and handling instructions.

Ventilation:
Provide adequate ventilation in storage areas to prevent the buildup of fumes or vapors.

Temperature Control:
Avoid exposure to extreme temperatures.
Store Itaconic acid within the recommended temperature range to maintain stability.

Security Measures:
Restrict access to storage areas and keep Itaconic acid out of reach of unauthorized personnel.
Implement proper security measures to prevent theft or intentional misuse.

Spill Response:
Have spill response materials, such as absorbent pads and neutralizing agents, readily available in storage areas.
Train personnel on proper spill response procedures and evacuation protocols.

Regular Inspections:
Conduct regular inspections of storage areas to ensure containers are in good condition, labeled correctly, and there are no signs of leaks or spills.
Itır Çiçeği Yağı
ROSE GERANIUM OIL; pelargonium roseum (andrews) w. t. aiton oil; geranium rose oil; hydroessential pelargonium; rose geranium oil CAS NO:90082-55-6
Itraconazole
SYNONYMS 4-(p-(4-(p-(((3R,5R)-5-(2,4-Difluorophenyl)tetrahydro-5-(1H-1,2,4-triazol-1-ylmethyl)-3-furyl)methoxy) phenyl)-1- piperazinyl)phenyl)-1-((1S,2S)-1-ethyl-2-hydroxypropyl)-delta(2)-1,2,4-triazolin-5-one; Noxafil; 4-(4-(4-(4-(((3R,5R)-5-(2,4-difluorophenyl)-5-(1,2,4-triazol-1-ylmethyl)oxolan-3-yl)methoxy)phenyl) piperazin-1-yl)phenyl)-2-((2S,3S)-2-hydroxypentan-3-yl)-1,2,4-triazol-3-one; Spriafil; cas no: 171228-49-2
Itraconazole 22% Pellets Anti-Fungal
SYNONMYS Itraconazolum [Latin];Oriconazole;Sporanox;ITRAZOLE;R 51211;R-51211;Itraconazol CAS NO:84625-61-6
IZO PROPIL MIRISTAT
SYNONYMS Tetradecanoic acid 1-methylethyl ester; Estergel;Myristic Acid, Isopropyl Ester; Bisomel; Tegester; Tetradecanoic Acid, Isopropyl; CAS NO:110-27-0; 1405-98-7
İğde Ekstrakt
Elaeagnus glabra extract ;extract of the whole plant, elaeagnus glabra, elaeagnaceae; man hu tui zi extract cas no:N/A
İHTİYOL
ichthammol ;Ammonium Ichthosulfonate; Ammonium Sulfoichtolate; DSSO cas no:8029-68-3
İMIDAZOLINLER 
isopropyl myristate; Tetradecanoic acid 1-methylethyl ester; Estergel; Myristic Acid, Isopropyl Ester; Bisomel; Tegester; Tetradecanoic Acid, Isopropyl; cas no: 110-27-0; 1405-98-7
İncir Ekstrakt
Ficus Carica Extract; extract of the fruit and leaves of the fig, ficus carica l., moraceae; ficus kopetdagensis extract; fig extract (ficus carica) cas no:90028-74-3
İnfuze Aynısefa Çiçeği Yağı
CALENDULA OIL INFUSED; Calendula Officinalis (Calendula) Flower Oil ;lipoactive calendula; brookosome calendula; calendula, pot marigold extract CAS NO:84776-23-8
İnfuze Kamelya Yağı
CAMELLIA OIL INFUSED; tea leaf oil; camellia oil; camellia thea leaf oil; tea leaf oil ; thea sinensis oil; camellia sinensis leaf oil CAS NO:68916-73-4
İnfuze Karoten Yağı
CAROTENE OIL INFUSED; Helianthus Annuus seed oil, Daucus Carota Sativa root extract, Daucus Carota Sativa seed oil, beta-carotene, ascorbyl palmitate CAS NO:7235-40-7
İSO PROPİL MİRİSTAT
Kozmetikte ve bazı medikal preparatlarda kullanılan cilt nüfuzu yüksek yağ.
isoquercetin
2-(3,4-Dihydroxyphenyl)-5,7-dihydroxy-3-[(2S,3R,4S,5S,6R)-3,4,5-trihydroxy-6-(hydroxymethyl)oxan-2-yl]oxychromen-4-one; Isoquercitroside; Isoquercitin; Isoquercetin; Trifoliin; Isotrifolin; Trifoliin A; Isohyperoside; Isotrifoliin; Quercetin-3-glucoside; Quercetin-3-O-glucoside; Quercetin 3-O-ß-D-glucopyranoside CAS NO:482-35-9
İYOT
iodine; molecular iodine; diiodane; diiodine; eranol; molecular iodine; vistarin cas no:7553-56-2
İYOT (I)
iodine element; molecular iodine ; diiodine cas no:7553-56-2
İZOBUTANOL
Isopropyl Alcohol; Dimethylcarbinol; sec-Propyl alcohol; Rubbing alcohol; Petrohol; 1-Methylethanol; 1-Methylethyl alcohol; 2-Hydroxypropane; 2-Propyl alcohol; Isopropyl alcohol; Propan-2-ol; IPA; 2-Propanol; Alcool Isopropilico (Italian); Alcool Isopropylique (French); I-Propanol (German); I-Propylalkohol (German); Iso-Propylalkohol (German); cas no: 67-63-0
İZOPROPIL ALKOL
Nom INCI : JOJOBA ALCOHOL Classification : Alcool Ses fonctions (INCI) Emollient : Adoucit et assouplit la peau Agent d'entretien de la peau : Maintient la peau en bon état Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques
Japan Wax Substitute
Berry Wax; Japan wax; rhus succedanea fruit cera; sumac wax; BERRY WAX CAS NO: 8001-39-6
JARPOL PVP/VA 64W SOLUTION
DESCRIPTION:
Jarpol PVP/VA 64W Solution is a copolymer of vinylpyrrolidone with vinyl acetate in an an easy-to-use aqueous solution. preserved with 0.05% max. dodecyl trimethyl ammonium chloride.
Jarpol PVP/VA 64W Solution is an excellent film-former and hair styling agent.

CAS No.: 25086-89-9


Jarpol PVP/VA 64W Solution acts as a film forming agent.
Jarpol PVP/VA 64W Solution is 50% aqueous solution of vinylpyrrolidone with vinyl acetate.
Jarpol PVP/VA 64W Solution has strong cohesive properties.
Jarpol PVP/VA 64W Solution provides transparent, hard, glossy, water-removable film.


Jarpol PVP/VA 64W Solution shows compatibility with modifiers & plasticizers allowing variations of hydroscopicity and film flexibility.
Jarpol PVP/VA 64W Solution is suitable for aerosol and non-aerosol products.
Jarpol PVP/VA 64W Solution is recommended for hair styling applications such as hair spray, hair gel, mousses, hair-setting lotions and sculpting gels.



VP/VA Copolymers Jarpol PVP/VA 64W Solution produce transparent, flexible, oxygen permeable films which adhere to glass, plastics and metals.
Jarpol PVP/VA 64W Solution resins are linear, random copolymers produced by the free-radical polymerization of the monomers in diferrent ratios.

Jarpol PVP/VA 64W Solution are available as white powders or clear solutions in ethanol and water.
Jarpol PVP/VA 64W Solution are widely used as film formers because of their film flexibility, good adhesion, luster, water remoistenability and hardness.

These properties make Jarpol PVP/VA 64W Solution suitable for a variety of industrial, personal care and pharmaceutical products.


Jarpol PVP/VA 64W Solution with different rations of N-Vinylpyrrolidone to Vinyl Acetate,soluble in most organic solvents.


Which exists in powder,water solution and ethnol solution form.
Jarpol PVP/VA 64W Solution aqueous solutions are non-ionic, neutralization not required.
Resultant films are hard, glossy, and water-removable; Tunable viscosity, softening point and water sensitivity depending on VP/VA ratio; Good compatibility with many modifiers, plasticizers, spray propellants and other cosmetic ingredients,and the hydroscopicity decreases in proportion to the ration of Vinyl acetate.


APPLICATIONS OF JARPOL PVP/VA 64W SOLUTION:

Jarpol PVP/VA 64W Solution is the excellent choice as film forming agent and hair-styling agent,which are suitable for fourmulations which used as film forming and viscosity modification,especially in hair styling products, such as Hair Gels,Aerosol gas sprays,Wet look sprays.



Jarpol PVP/VA 64W Solution is a 6:4 linear random copolymer of N-vinylpyrrolidone and vinyl acetate.
The vinyl acetate component of Jarpol PVP/VA 64W Solution reduces the hydrophilicity and glass transition temperature (Tg) compared to povidone homopolymers of similar molecular weight.

As a result, Jarpol PVP/VA 64W Solution is the ultimate tablet binder that extends its excellent adhesive property in wet granulation, as well as in dry granulation and direct compression.
Due to its spherical, hollow particle morphology and high plasticity, Jarpol PVP/VA 64W Solution performs exceptionally well as a binder for direct compression.

In addition, a lower Tg makes Jarpol PVP/VA 64W Solution an ideal polymer matrix for solid dispersions/solutions via hot melt extrusion, which enhances the dissolution of poorly soluble drug actives.

BENEFITS OF JARPOL PVP/VA 64W SOLUTION:
Jarpol PVP/VA 64W Solution has Suitability for use in direct compression, dry granulation, wet granulation, hot melt extrusion, and film coating.
Jarpol PVP/VA 64W Solution has Good flowability

Jarpol PVP/VA 64W Solution has Large surface area due to hollow particle morphology – enhances particle bonding and good compressibility
Jarpol PVP/VA 64W Solution has Ideal glass transition temperature (Tg) for hot melt extrusion



CHEMICAL AND PHYSICAL PROPERTIES OF JARPOL PVP/VA 64W SOLUTION


CAS No.: 25086-89-9
Formula: (C6h9no.C4h6o2)X
Molecular main chain: vp/va copolymer
Color: White
here: vp/va copolymer
applications: personal care



SAFETY INFORMATION ABOUT POLY(1-VINYLPYRROLIDONE-CO-VINYL ACETATE)
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.



Jasminum Grandiflorum Flower Cera
JASMINUM GRANDIFLORUM FLOWER CERA ; flowers of the Spanish Jasmine, Jasminum grandiflorum L., Oleaceae; jasmine flower wax ; Jasminum Officinale Fo. Grandiflorum Flower Cera CAS NO:84776-64-7
JEFFAMINE D 2000
Jeffamine D 2000 Jeffamine D 2000 Amine is an extremely low vapor pressure difunctional primary amine. Used in epoxy adhesives. Rarely used alone, but rather in conjunction with other curing agents. Jeffamine D 2000 Amine enhances flexibility, toughness and high peel strength. Listed with TSCA, DSL, EINECS/ELINCS, AICS and ENCS. Product Type Crosslinking / Curing / Vulcanizing Agents > Amines /Amides Chemical Composition Polyoxypropylenediamine CAS Number 9046-10-0 JEFFAMINE D 2000 Technical Bulletin JEFFAMINE® D-2000 Polyetheramine JEFFAMINE D-2000 polyetheramine is characterized by repeating oxypropylene units in the backbone. As shown by the representative structure, JEFFAMINE D 2000 polyetheramine is a difunctional, primary amine with average molecular weight of about 2000. The primary amine groups are located on secondary carbon atoms at the end of the aliphatic polyether chains.(x) H2NONH2CH3 CH3x ≈ 33 APPLICATIONS • Key ingredient in the formulation of polyurea and RIM • Co-reactant in epoxy systems which require increased flexibility and toughness BENEFITS • Low viscosity, color and vapor pressure • Improved flexibility from high molecular weight polyether backbone • Increases peel strength SALES SPECIFICATIONS Property Specifications Test Method* Appearance Colorless to pale yellow liquid ST-30.1 with slight haze permitted Color, Pt-Co 25 max. ST-30.12 Primary amine, % of total amine 97 min. ST-5.34 Total acetylatables, meq/g 0.98 – 1.1 ST-31.39 Total amine, meq/g 0.98 – 1.05 ST-5.22 Water, wt% 0.25 max. ST-31.53, 6 Typical Physical Properties AHEW (amine hydrogen equivalent wt.), g/eq 514 Equivalent wt. with isocyanates, g/eq 1030 Viscosity, cSt, 25°C (77°F) 248 Density, g/ml (lb/gal), 25°C 0.991(8.26) Flash point, PMCC, °C (°F) 185 (365) pH, 5% aqueous solution 10.5 Refractive index, nD 20 1.4514 Vapor pressure, mm Hg/°C 0.93/235 4.95/254 At temperatures above 100°F (38oC) Tanks Stainless steel or aluminum Lines, Valves Stainless steel Pumps Stainless steel or Carpenter 20 equivalent Atmosphere Nitrogen JEFFAMINE D 2000 polyetheramine may be stored under air at ambient temperatures for extended periods. A nitrogen blanket is suggested for all storage, however, to reduce the effect of accidental exposure to high temperatures and to reduce the absorption of atmospheric moisture and carbon dioxide. It should be noted that pronounced discoloration is likely to occur at temperatures above 140°F (60oC), whatever the gaseous pad. Cleanout of lines and equipment containing JEFFAMİNE D 2000 polyetheramine can be accomplished using warm water and steam. In the event of spillage of this product, the area may be flushed with water. The proper method for disposal of waste material is by incineration with strict observance of all federal, state, and local regulations. Jeffamine D 2000 is a 2000 MW primary aliphatic polyether diamine based on polyoxypropylenediamine. Jeffamine D-2000 is suitable for use in polyurea coatings, adhesives, sealants and elastomer applications. 247 cps at 25C. Supplied as a light yellow liquid. AHEW: 515 Jeffamine D 2000 is an excellent product. However, it is Tri-iso's opinion that Endamine D 2000 represents a better value overall. Endamine D 2000 is a direct drop-in replacement for Jeffamine D 2000, and is also a 2000MW primary aliphatic diamine based on polyoxypropylenediamine. JEFFAMINE D2000 Polyoxypropylenediamine is an amine-terminated polyoxypropylene diol that has wide use in epoxy and polyurea systems. Jeffamine D 2000 Amine by Huntsman is an extremely low vapor pressure difunctional primary amine. Used in epoxy adhesives. Rarely used alone, but rather in conjunction with other curing agents. Jeffamine D 2000 Amine enhances flexibility, toughness and high peel strength. Listed with TSCA, DSL, EINECS/ELINCS, AICS and ENCS. DOCUMENTS JEFFAMINE® D-2000 Polyoxypropylenediamine Datasheet New Secondary Amine Chain Extenders for Aliphatic Polyurea Materials Physical Properties of Aromatic Polyurea Elastomer Coatings After Exposure to Extreme Conditions The Influence of Isomer Composition and Functionality on the Final Properties of Aromatic Polyurea Spray Coatings Tuning the Properties of Polyurea Elastomer Systems via Raw Material Selection and Processing Parameter Modulation Adhesion Properties of Epoxy Formulations Containing JEFFAMINE Polyetheramine Curing Agents Huntsman Performance Products makes their documentation available in the regions indicated below: JEFFAMINE D 2000 Polyoxypropylenediamine is an amine-terminated polyoxypropylene diol that has wide use in epoxy and polyurea systems. These include amines, such as ethyleneamines and polyetheramines, alkylene carbonates, and a broad spectrum of surfactants and surfactant intermediates. Product applications include dispersants for coatings, amine neutralizers for latex paints, wetting agents, and emulsifiers for polymer dispersion. 248Huntsman Jeffamine D-2000 Home / Chemicals / Jeffamine D-2000 | Quote Request | Polyether Amine Jeffamine D-2000 is a 2000 MW primary aliphatic polyether diamine based on polyoxypropylenediamine. Jeffamine D-2000 is suitable for use in polyurea coatings, adhesives, sealants and elastomer applications. 247 cps at 25C. Supplied as a light yellow liquid. AHEW: 515 Jeffamine D 2000 is an excellent product. However, it is Tri-iso's opinion that Endamine D2000 represents a better value overall. Endamine D2000 is a direct drop-in replacement for Jeffamine D-2000, and is also a 2000MW primary aliphatic diamine based on polyoxypropylenediamine. Jeffamine D-2000 Amine It is a kind of polyalkane epoxy compound terminated by primary Amine group or secondary Amine group, its molecular skeleton is polyether and its reactive group is Amine end group. Based on different molecular weights and different numbers of functional groups, there can be various kinds of grades ZD-1200, ZD-140, ZD-123, ZT-143 and ZT-1500. Amine-terminated polyether is the key raw material for spray polyurea elastomer,and it can be widely used to protect the materials such as waterproof and anticorrosion coatings of building concrete and steel structure; and moreover, it can be also used as anti-skid and hard-wearing lining for transportation vehicles, anticorrosive coating for cross-sea bridges, protective decoration for top grade floors at sterile plants and hospitals as well as the walls of high-grade swimming pools, internal and external protective coatings for land and benthal oil pipelines, wear-resistant coatings for decks and screw propellers of ships and boats, antiseptic and rust-proof lining for oil tanks, air tanks and water storage tanks, leakage-proof and antiseptic coatings for temporary parking aprons and activated sludge tanks, leakage-proof, anti-seepage and antiseptic materials for municipal refuse disposal areas, stadiums and runways. In addition of that, it is largely used for water-proof and protective coatings of high-speed railway bridges. Amine-terminated polyether is a kind of curing agent for epoxy resin. It can be used to pour large-scale epoxy resin components to make the cured resin crystal-clear. It can be also widely used in the fields of epoxy composite materials, epoxy coatings,epoxy electrophoretic coatings,binding agents, circuit boards, sealants, artworks, etc. Amine-terminated polyether is a kind of curing agent used on the combined blade materials for wind power generation. Amine-terminated polyether is an additive for gasoline, diesel and lubricating oil.And meanwhile, it is widely employed in the fields of surface active agents, water-soluble paints and so on. ZD-123 Amine-terminated polyether is a kind of polypropylene oxide compound mainly terminated by secondary Amine group. It structure is shown as follows: Molecular weight Wn About 230 Degree of functionality ~2 Total amine value MEQ/g 8.10-9.10 Rate of primary Amine group % ≥95 Color APHA ≤25 Moisture % ≤0.25 Applications: ●Curing agent for epoxy resin; curing agent for ornament glue (hard glue); curing agent for wind blade adhesive; ●hot-melt adhesive for polyamide; curing agent for electron end-sealing material; ●curing agent for electron potting compound; curing agent for electron encapsulating material ●fast curing RIM; curing agent for building structure adhesive; ●curing agent for modified polyether amine; ●curing agent for heavy anti-corrosion coatings; ●curing agent for composite materials of fishing rods, golf clubs and tennis rackets. Properties: ● low viscosity, low chromaticity and low vapor pressure.
JEFFAMINE D-2010
DESCRIPTION:
JEFFAMINE D-2010 polyetheramine is characterized by repeating oxypropylene units in the backbone.
As shown by the representative structure, JEFFAMINE D-2010 polyetheramine is a difunctional, primary amine with average molecular weight of about 2000.

The primary amine groups are located on secondary carbon atoms at the end of the aliphatic polyether chains.
JEFFAMINE D-2010 is a key ingredient in the formulation of polyruea and RIM, and can be used as a co-reactant in epoxy systems which require increased flexibility and toughness.


JEFFAMINE D-2010 polyetheramine is characterized by repeating oxypropylene units in the backbone.
As shown by the representative structure, JEFFAMINE D-2000 polyetheramine is a difunctional, primary amine with average molecular weight of about 2000.
The primary amine groups are located on secondary carbon atoms at the end of the aliphatic polyether chains.


APPLICATIONS OF JEFFAMINE D-2010:
JEFFAMINE D-2010 is Key ingredient in the formulation of polyurea and RIM
JEFFAMINE D-2010 is Co-reactant in epoxy systems which require increased flexibility and toughness

BENEFITS OF JEFFAMINE D-2010:
JEFFAMINE D-2010 has Low viscosity, color and vapor pressure
JEFFAMINE D-2010 has Improved flexibility from high molecular weight polyether backbone
JEFFAMINE D-2010 Increases peel strength



TYPICAL PHYSICAL PROPERTIES OF JEFFAMINE D-2010:
AHEW (amine hydrogen equivalent wt.), g/eq 514
Equivalent wt. with isocyanates, g/eq 1030
Viscosity, cSt, 25°C (77°F) 248
Density, g/ml (lb/gal), 25°C 0.991(8.26)
Flash point, PMCC, °C (°F) 185 (365)
pH, 5
% aqueous solution 10.5
Refractive index, nD 20 1.4514
Vapor pressure, mm Hg/°C 0.93/235 4.95/254
Appearance: Colorless to pale yellow liquid with slight haze permitted Color,
Pt-Co 25 max.
Primary amine, % of total amine 97 min.
Total acetylatables, meq/g 0.98 – 1.1
Total amine, meq/g 0.98 – 1.05
Water, wt% 0.25 max.



SAFETY INFORMATION ABOUT JEFFAMINE D-2010:
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
JEFFAMINE T-5000
Jeffamine T-5000 is a trifunctional primary amine.
Jeffamine T-5000 is a colorless to light yellow liquid at room temperature with a molecular weight of approximately 5,000.


CAS Number: 64852-22-8
MDL Number:MFCD00804529
INCI/Chemical Name: Glyceryl poly(oxy propylene)triamine
Product Type: Adhesion Promoters > Polyethylenimines
Chemical Composition: Polyetheramine
Chemical Name: Polyetheramine
Molecular Formula: (C3H6O)mult(C3H6O)mult(C3H6O)multC



alpha,alpha',alpha''-1,2,3-propanetriyltris(omega-(2-aminomethylethoxy)-poly(oxy(methyl-1,2-ethanediyl)), JEFFAMINE T5000, T-5000 polyetheramine equivalent, Polypropylene glycol bis(2-aminopropyl ether), polyetheramine, Polyetheramines, 2-(aminooxy)propan-1-amine, POLYETHERAMINE T 5000, [omega-(2-aminomethylethoxy)-, Polyetheramine T5000 (Baxxodur, glyceroltris(poly(propyleneglycol), ZT-1500 Amine-terminated Polyether, Glyceryl poly(oxypropylene)triamine, POLY(PROPYLENE OXIDE), TRIAMINE TERMITED, POLY(PROPYLENE OXIDE), TRIAMINE TERMINATED, glycerol tris(poly(propylene glycol)amine terminated), 2-aminopropan-1-ol,propane-1,2-diol,propane-1,2,3-triol, POLYETHERAMINE T 5000, POLY(PROPYLENE OXIDE), TRIAMINE TERMINATED, [omega-(2-aminomethylethoxy)-, 2-ethanediyl)],.alpha.,.alpha.',.alpha.''-1,2,3-propanetriyltris[.omega.-(2-aminomethylethoxy)-Poly[oxy(methyl-1, glyceroltris(poly(propyleneglycol), GLYCEROL TR, JeffamineT 3000, Jeffamine T 5000, T 5000, XTJ 509, lyceroltris (poly (propyleneglycol), GLYCEROL TRIS [POLY (PROPYLENE GLYCOL), AMINE TERMINATED] ETHER, Polyoxy (methyl-1,2-ethanediyl), a.,.alpha.,.alpha-1,2,3-propanetriyltris .omega .-(2-aminomethylethoxy)-, Glyceryl poly(oxypropylene)triamine, Poly[oxy(methyl-1,2-ethanediyl)],α,α,′,α”-1,2,3-propanetriyltris[ω - (2-aminomethyl-ethoxy) -, Polyetheramine T5000 (Baxxodur, POLY (PROPYLENE OXIDE), TRIAMINE TERMITED, POLYETHERAMINE T 5000,



Jeffamine T-5000 provides flexibility and promotes adhesion as a co-reactant in epoxy systems.
Benefits of Jeffamine T-5000 include increased peel strength, toughness and low colour.
Jeffamine T-5000 is a trifunctional primary amine.


Jeffamine T-5000 is a colorless to light yellow liquid at room temperature with a molecular weight of approximately 5,000.
Jeffamine T-5000 is compatible with a variety of organic solvents.
Jeffamine T-5000 has surface corrosion resistance performance in epoxy-polyurethane systems.


Jeffamine T-5000 is equivalent.
Jeffamine T-5000's a trifunctional primary amine of approximately 5000 molecular weight.
Jeffamine T-5000 is clear, almost colorless, viscous, liquid product.


Jeffamine T-5000 is a colorless or yellowish liquid
Jeffamine T-5000 is a kind of polypropylene oxide, mainly terminated by primary amino group.
Jeffamine T-5000 is a primary polyetheramine with trifuctionarity. Jeffamine T-5000's molecular weight is about 5,000.


Jeffamine T-5000 is a clear, almost colorless, viscous, liquid product.
Jeffamine T-5000 is a 5000 MW primary trifunctional aliphatic polyether amine.
Jeffamine T-5000 is suitable for use in polyurea coatings, adhesives, sealants and elastomer applications, as well as in epoxy systems. 819 cps at 25C.


Jeffamine T-5000 is supplied as a clear, almost colorless viscous liquid. AHEW: 952, Equivalent weight with Isocyanates: 1904
Jeffamine T-5000 is an excellent product.
However, Jeffamine T-5000 is Tri-iso's opinion that Endamine T5000 represents a better value overall.


Endamine T5000 is a direct drop-in replacement for Jeffamine T5000, and is also a 5000MW primary trifunctional aliphatic amine.
Jeffamine T-5000 is a 5000 molecular weight polyoxypropylene triamine that can be added to a variety of curing agents to impart flexibility and improve peel strength of the adhesive systems with little degradation in other properties.


Jeffamine T-5000 is a trifunctional primary amine of approximately 5000 molecular weight.
Jeffamine T-5000 is clear, almost colorless, viscous, liquid product.
Jeffamine T-5000 is polyetheramine by Huntsman.


Jeffamine T-5000 is a crosslinker for polyurea and co-reactant in epoxy systems.
Jeffamine T-5000 offers benefits such as increased peel strength, low color and increased toughness.
Jeffamine T-5000 is a trifunctional primary amine of approximately 5000 molecular weight.


Jeffamine T-5000 is clear, almost colorless, viscous, liquid product.
Jeffamine T-5000 is a 5000 MW primary trifunctional aliphatic polyether amine.
Jeffamine T-5000 is supplied as a clear, almost colorless viscous liquid. AHEW: 952, Equivalent weight with Isocyanates: 1904


Jeffamine T-5000 is an excellent product.
However, Jeffamine T-5000 is Tri-iso's opinion that Endamine
T5000 represents a better value overall.


It is a direct drop-in replacement for Jeffamine T-5000, and is also a 5000MW primary trifunctional aliphatic amine.
Jeffamine T-5000 is a trifunctional primary polyetheramine of approximately 5000 molecular weight used as crosslinker for polyurea, co-reactant in epoxy systems where adhesion promotion and flexibility are important.



USES and APPLICATIONS of JEFFAMINE T-5000:
Jeffamine T-5000 is used epoxy curing agent.
Jeffamine T-5000 is used co-reactant in epoxy system where adhesion promotion and flexibility are important.
Jeffamine T-5000 is used a spray cross-linking agent for polyurea.


Jeffamine T-5000 is used Surfactant.
Jeffamine T-5000 is used corrosion inhibitor.
Jeffamine T-5000 is used as a co-reactant in epoxy resin systems where promoting adhesion and flexibility is important.


Jeffamine T-5000 is a cross-linker for polyureas and co-reactants in epoxy systems.
Jeffamine T-5000 offers the benefits of increased peel strength, low color and increased toughness.
Jeffamine T-5000 is a reactive chain extender for polyurethane with typical primary amine reaction properties.


Jeffamine T-5000 is widely used in the polyurethane RIM industry and is the main raw material for spray polyurea elastomer.
Because of its unique chemical structure, Jeffamine T-5000 plays a toughening role in the epoxy industry.
Together with polyamide, Jeffamine T-5000 is used in epoxy adhesives characterized by high strength.


Jeffamine T-5000 has surface anti-corrosion effect in epoxy-polyurethane system.
Jeffamine T-5000 is used spraying polyurea crosslinking agent, modified polyether amine curing agent; Hardener for high pressure FRP pipe (amine pipe); Curing agent of epoxy resin for fishing rod, golf club and tennis racket composite materials; Surfactants, corrosion inhibitors, etc.


Jeffamine T-5000 is an active chain extender for polyurethane with typical reaction properties of primary amine.
Jeffamine T-5000 is widely used in the polyurethane RIM industry as the main raw material of Spray Polyurea Elastomer.
Because of its characteristic structure, Jeffamine T-5000 has a good toughening effect in the epoxy resin industry.


Together with polyamides, Jeffamine T-5000 can also be used in highly intensive epoxy adhesives.
Jeffamine T-5000 undergoes typical amine reactions that often yield increased flexibility, toughness, low viscosity, and low color.
Jeffamine T-5000 has a wide range of molecular weight, amine functionality, repeating unit type and distribution can provide flexibility in the design of new compounds or mixtures.


Jeffamine T-5000 is used as an auxiliary reactant in epoxy systems where adhesion promotion and flexibility are important.
Jeffamine T-5000 is a crosslinker for polyurea and co-reactant in epoxy systems.
Jeffamine T-5000 offers benefits such as increased peel strength, reduced color and increased toughness.


Jeffamine T-5000 is suitable for use in polyurea coatings, adhesives, sealants and elastomer applications, as well as in epoxy systems.
Jeffamine T-5000 is used Crosslinker for polyurea
Jeffamine T-5000 is used co-reactant in epoxy sytems where adhesion promotion and flexibility are important


Jeffamine T-5000 is used surfactant and corrosion inhibitor applications.
Jeffamine T-5000 is used as a co-reactant in epoxy systems where adhesion promotion and flexibility are important.
Jeffamine T-5000 is used as crosslinker for polyurea, co-reactant in epoxy systems where adhesion promotion and flexibility are important.



APPLICATION ADVANTAGES OF JEFFAMINE T-5000:
*Initial low viscosity of the compositions.
*Jeffamine T-5000 provides wettability of various surfaces, filling hard-to-reach areas and self-leveling.
*High physical and mechanical properties of the polymer.
*Jeffamine-based coatings are resistant to peeling and can withstand heavy loads.
*Moderate reactivity allows for large volumes to be poured.
*Jeffamine T-5000 is possible to obtain an optically transparent polymer.



CHARACTERISTICS OF JEFFAMINE T-5000:
*Low color and vapor pressure
*Enhance peel strength in epoxy adhesives
*Strengthening the bonding force of epoxy resin
*Increase toughness
*Improves flexibility and strength



FEATURES OF JEFFAMINE T-5000:
*Low viscosity and vapor pressure.



BENEFITS OF JEFFAMINE T-5000:
• Low color
• Increased peel strength in epoxy adhesives
• Increased toughness
• Jeffamine T-5000 is one of the basic materials used in polyurea synthesis and RIM (reaction injection molding method).
• Jeffamine T-5000 is used as an auxiliary reactant in epoxy systems.



PHYSICAL and CHEMICAL PROPERTIES of JEFFAMINE T-5000:
Appearance: Colorless to pale yellow liquid
Color, Pt-Co: 50 Max.
Primary amine of total amine: 97% Min.
Total acetylatables: 0.56-0.63mmol/g
Total amine: 0.50-0.54mmol/g
Water: 0.25% Max.
Color number Pt-Co: ≤50
Primary amine content%: ≥97
Acetyl value mmol/g: 0.58-0.63
Amine value mmol/g: 0.50-0.54
Moisture%: ≤0.10
CBNumber:CB1197426
Molecular Formula:C9H25NO6
Molecular Weight:243.2979
MDL Number:MFCD00804529
MOL File:64852-22-8.mol

Density: 1 g/mL at 25 °C(lit.)
refractive index: n20/D 1.453
Flash point: >230 °F
EPA Substance Registry System: Poly[oxy(methyl-1,2-ethanediyl)], .alpha.,.alpha.',.alpha.'
'-1,2,3-propanetriyltris[.omega.-(2-aminomethylethoxy)- (64852-22-8)
Molecular weight: About 5000
Appearance: Colorless to pale yellow liquid
Degree of functionality: ~3
Total amine meq/g: 0.50-0.57
Primary amine %: ≥97
Color, Pt-Co(APAH): ≤50
Water, wt%: ≤0.25
Viscosity cSt,25℃: 819
Density g/ml (lb/gal),25℃: 0.997(8.31)
Solids Content by Weight, %: 18-21
Flash point PMCC,℃(℉): 213(415.4)
PH: 11.2
CAS: 64852-22-8



FIRST AID MEASURES of JEFFAMINE T-5000:
-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 JEFFAMINE T-5000:
-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 JEFFAMINE T-5000:
-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 JEFFAMINE T-5000:
-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 JEFFAMINE T-5000:
-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 JEFFAMINE T-5000:
-Reactivity:
No data available
-Chemical stability:
Stable under recommended storage conditions.
-Possibility of hazardous reactions:
No data available
-Conditions to avoid:
No data available


Jelatin
SYNONYMS Gelatine, Teleostean gelatin CAS NO:9000-70-8
JELATİN
edible gelatin; spongiofort ; collagens, gelatins; edible gelatin; gelatin foam; gelatine cas no:9000-70-8
JOJOBA ALCOHOL
Benzyl Alcohol (and) Methylchloroisothiazolinone (and) Methylisothiazolinone CAS NO:185532-71-2
Jojoba Ekstraktı
Simmondsia Chinensis Seed Extract; extract of the seeds of the jojoba, simmondsia chinensis, buxaceae; jojoba extract; actiphyte of jojoba meal extract; simmondsia californica seed extract cas no:90045-98-0
Jojoba Esters
JOJOBA OIL REFINED;JOJOBA OIL, UNREFINED;Jojoba bean oil, Jojoba liquid wax;Jojoba bean oil, Jojoba liquid wax, Jojobae oelum;OIL, JOJOBA(RG);Jojoba oil (Simmondsia chinensis);jojobaoilfromsimmondsiachinensis;Jojobawax CAS Number: 61789-91-1
JOJOBA OIL
Jojoba oil is an excellent face and body moisturizer.
Jojoba oil conditions and smooths hair and beards.
Jojoba oil is an ideal carrier for essential oils and as a base for personal care products.


CAS NUMBER: 61789-91-1

EC NUMBER: 612-381-6

MOLECULAR FORMULA: -

MOLECULAR WEIGHT: -

INCI NAME: Hydrogenated Jojoba Oil


Jojoba oil is the liquid produced in the seed of the Simmondsia chinensis plant, a shrub, which is native to southern Arizona, southern California, and northwestern Mexico.
The oil makes up approximately 50% of the jojoba seed by weight.
The terms "Jojoba oil" and "jojoba wax" are often used interchangeably because the wax visually appears to be a mobile oil, but as a wax it is composed almost entirely (~97%) of mono-esters of long-chain fatty acids (wax ester) and alcohols (isopropyl jojobate), accompanied by only a tiny fraction of triglyceride esters.
This composition accounts for its extreme shelf-life stability and extraordinary resistance to high temperatures, compared with true vegetable oils.


Appearance of Jojoba oil:
Unrefined Jojoba oil appears as a clear golden liquid at room temperature with a slightly nutty odor.
Refined Jojoba oil is colorless and odorless. The melting point of jojoba oil is approximately 10 °C (50 °F) and the iodine value is approximately 80
Jojoba oil is relatively shelf-stable when compared with other vegetable oils mainly because it contains few triglycerides, unlike most other vegetable oils such as grape seed oil and coconut oil.
Jojoba oil has an oxidative stability index of approximately 60, which means that it is more shelf-stable than safflower oil, canola oil, almond oil, or squalene but less than castor oil and coconut oil.

Uses:
Being derived from a plant that is slow-growing and difficult to cultivate, Jojoba oil is mainly used for small-scale applications such as pharmaceuticals and cosmetics
Overall, Jojoba oil is used as a replacement for whale oil and its derivatives, such as cetyl alcohol.

Jojoba oil is found as an additive in many cosmetic products, especially those marketed as being made from natural ingredients.
In particular, such products commonly containing jojoba are lotions and moisturizers, hair shampoos and conditioners.
The pure oil itself may also be used on skin, hair, or cuticles.

Like olestra, Jojoba oil is edible but non-caloric and non-digestible, meaning the oil will pass out of the intestines unchanged and can mimic steatorrhea—a health condition characterized by the inability to digest or absorb normal dietary fats.
Thus, Jojoba oil is present in the stool, but does not indicate an intestinal disease.
If consumption of Jojoba oil is discontinued in a healthy person, the indigestible oil in the stool will disappear.

Jojoba oil also contains approximately 12.1% of the fatty acid erucic acid that would appear to have toxic effects on the heart at high enough doses, if it were digestible.
Although impractical, jojoba biodiesel has been explored as a sustainable fuel that can serve as a substitute for petroleum diesel.

Jojoba oil is nontoxic
Jojoba oil is nonallergenic (the extract is pressed from a seed, not a nut, and is safe for consumers with nut allergies), and noncomedogenic since it won't clog pores with its sebum-compatibility.
Being a liquid wax with very low levels of triglycerides, Jojoba oil does not easily oxidize, making it remarkably shelf-stable and able to withstand heat without any loss in its properties, unlike most plant oils.

Jojoba oil is a popular massage medium because of its compatibility with all skin types, its nonallergenic properties, and the fact that a little goes a long way.
Jojoba oil is safe for all ages (which is one reason we created HobaCare Baby) and skin types.

Jojoba oil is actually a liquid wax ester and not an oil.
Although it shares the same consistency as an oil, the Jojoba plant produces wax esters that hold a similar molecular structure to the oils naturally found in our skin.
So, when using Jojoba oil, our body becomes more receptive to vital nutrients and antioxidants, helping our skin balance just as it was designed to do.

BENEFITS:
*Jojoba oil is hypoallergenic
*Jojoba oil has a similar molecular structure to the oils naturally produced in our skin
*Jojoba oil has a wide variety of uses for skin, body, hair & nails
*Jojoba oil soothes sunburns
*Jojoba oil provides 8 hours of moisturisation
*Jojoba oil is non-comedogenic
*Vitamins A, D & E plus omegas 6 & 9
*Extensive shelf life - up to 2 years
*Jojoba oil regulates oil production in skin & hair
*Jojoba oil is a natural emollient
*Jojoba oil has no nasties or additives

Jojoba oil nourishes, moisturizes, and protects skin
Jojoba oil regulates sebum production and preserves skin from aging

Mature jojoba plants are woody perennial bushes that don't shed their leaves when the seasons change.
The chemical structure of organic Jojoba oil is different from that of other vegetable oils because it’s a polyunsaturated wax.

As a wax, Jojoba oil for the face and body is especially useful
Jojoba oil protects the skin

Jojoba oil is providing hydration control
Jojoba oil soothes your hair.

At room temperature, Jojoba oil is liquid because of its unsaturated fatty acids.
Like some natural oils, Jojoba oil does not break down or become rancid.

Jojoba oil actually has a very long shelf life, which makes it good for cosmetic products and applications.
Jojoba oil contains beneficial ingredients

Jojoba oil is including vitamin E, vitamin B complex, silicon, chromium, copper and zinc.
Jojoba oil has a very high percentage of iodine at 82 percent, which gives jojoba oil its power to heal.


GENERAL PROPERTIES:

-Melting Point: 7 ℃

-Boiling Point: 396 ℃

-Flash Point: > 200.00 °F

-Density: 0.87 g/mL at 20 °C

-Vapor Pressure: 0-0Pa at 25 ℃

-Refractive Index: n20/D1.466

-Storage Temperature: 2-8 °C

-Color: Colorless

-Form: Semi-solid (amorphous) or gel

-Specific Gravity: 0.863

-Viscosity Index: 190-230


Jojoba oil is oily liquid in nature
Jojoba oil has a characteristic fatty odor.

Jojoba oil is goldencolored liquid wax, which are produced by the seeds of the jojoba plant
Jojoba oil is used for dry and oily skin.

Jojoba oil regulates the sebum produced on the skin, as the oil can control the greasy texture of the skin.
On dry skin type, Jojoba oil acts as a moisturizer.

Jojoba oil also acts as a lip-balm for dry and chapped lips.
Jojoba oil has many benefits, and is best used for the hair and skin.

Jojoba oil is colorless
Jojoba oil is odorless

Jojoba oil has a waxy liquid form
Jojoba oil is chemically similar to sperm oil.

Jojoba oil is a moisturizer and emollient.
Mystical properties have been attributed to it for its apparent ability to heal the skin.

Jojoba oil reduces transepidermal water loss without completely blocking the transportation of water vapor and gases, providing the skin with suppleness and softness.
In addition, Jojoba oil gives cosmetic products excellent spreadability and lubricity.

Jojoba oil can penetrate rapidly by absorption via the pores and hair follicles.
From these areas, it seems to diffuse into the stratum corneum layer and acts with intercellular lipids to further reduce water loss.

Jojoba oil is not a primary skin irritant and does not promote sensitization.
Jojoba oil is derived from the plant seeds.

Jojoba oil has a straight chain with 36 to 46 carbons.
Jojoba oil is a crystalline, hard wax ester.

Jojoba oil has particular functionality in cosmetics due to its capacity to strengthen the wax matrices of "stick" formulations like lipstick, eyeliner, lip balm, etc.
Jojoba oil is colorless and odorless.

Jojoba oil works as an abrasive scrub
Jojoba oil also used as an emollient

Jojoba oil can be used as a skin-conditioning agent in cosmetics and personal care products.
Jojoba oil is used in lipsticks up to 31% concentration.

Skin care: Jojoba oil functions as an emollient and skin-conditioning agent.
Jojoba oil aids in making the skin softer and smoother.

Jojoba oil has a reputation for being moisturizing because it can improve skin hydration and stop water loss.
Additionally, Jojoba oil is non-greasy and readily absorbed because it shares a chemical structure with the natural oils produced by our skin.

This makes Jojoba oil a well-liked component of numerous skincare products, such as moisturizers, lip balms, and makeup items.
Jojoba oil is often used as a material for exfoliation particles due to its uniform color, hardness, and controllable crystallinity

Jojoba oil is an extract of the Mexican native plant jojoba, which moisturizes, strengthens the skin, softening fat
Jojoba oil has an anti-inflammatory effect.

Jojoba oil is not an oil, but a liquid wax that solidifies at low temperatures.
jojoba oil is not oil, but liquid wax, so it will solidify at low temperature.

Jojoba oil is the most permeable base oil
Jojoba oil is easily absorbed by the skin

Jojoba oil is fresh and moist
Jojoba oil is non-greasy

Jojoba oil can restore the skin pH balance and wrinkles
Jojoba oil effectively improves oily skin

Jojoba oil regulates sebaceous gland secretion function
Jojoba oil shrinks pores

Jojoba oil is also the best skin moisturizing oil.
Jojoba oil film formed by it is different from mineral oil in that it can penetrate the evaporated water and can also control the loss of water.

Jojoba oil is very clear
Jojoba oil smells a light nut flavor
Jojoba oil is very plump, but not as greasy as other vegetable oils


SYNONYM:

Golden Jojoba
JOJOBA OIL REFINED
JOJOBA OIL, UNREFINED
Jojoba bean oil
Jojoba liquid wax
Jojobae oelum
OIL, JOJOBA(RG)
Jojoba oil (Simmondsia chinensis)
jojobaoilfromsimmondsiachinensis
Hydrogenated jojoba oil
724GKU717M
61789-91-1
Jojoba oil
Jojoba oil, hydrogenated
Jojoba wax
Oils, jojoba
Oils, jojoba, hydrogenated
Jojoba bean oil
Waxes and Waxy substances, jojoba
Jojoba liquid wax
E-RASE
FloraEster Jojoba Oil
Jojoba waxy substances
Oils, jojoba-bean
UNII-724GKU717M
florabeads jojoba
florabeads jojoba 10/10
florabeads silkies
floraesters 15
floraesters 20
floraesters 30
floraesters 60
floraesters 70
florapearls
florasomes
floraspheres
hydrogenated jojoba bean oil
jojoba, ext., hydrogenated
nikkol jojoba wax
hydrogenated oils, jojoba-bean
Jojoba oil
Golden Jojoba
jojoba bean oil
OIL, JOJOBA
JOJOBA OIL REFINED
JOJOBA OIL, UNREFINED
jojobaoilfromsimmondsiachinensis
Jojoba oil (Simmondsia chinensis)
jojoba oil from simmondsia chinensis
Jojoba bean oil, Jojoba liquid wax
Jojoba bean oil, Jojoba liquid wax, Jojobae oelum

Jojoba Vaks
JOJOBA WAX; polyethylene glycol jojoba acid/alcohol; jojoba, ext CAS NO:159518-81-7
JORDAPON CI-65

Jordapon CI-65 is a versatile surfactant blend used in personal care formulations.
Jordapon CI-65 combines Sodium Cocoyl Isethionate and Stearic Acid to create a synergistic effect.
With its creamy texture and mild cleansing properties, Jordapon CI-65 is ideal for gentle skincare products.

CAS Number: 61789-32-0, 57-11-4
EC Number: 263-052-5, 200-313-4

SCI/SA, Sodium Cocoyl Isethionate/Stearic Acid blend, Sodium Cocoyl Isethionate and Stearic Acid mixture, Jordapon CI-65 blend, SCI and Stearic Acid surfactant, Sodium Cocoyl Isethionate-Stearic Acid complex, Jordapon CI-65 surfactant blend, SCI with Stearic Acid combination, Sodium Cocoyl Isethionate plus Stearic Acid, Jordapon CI-65 formulation, Sodium Cocoyl Isethionate-Stearic Acid compound, SCI/SA surfactant mix, Jordapon CI-65 chemical combination, Sodium Cocoyl Isethionate blended with Stearic Acid, Jordapon CI-65 ingredient blend, Sodium Cocoyl Isethionate-Stearic Acid composition, SCI and Stearic Acid formulation, Jordapon CI-65 complex, Sodium Cocoyl Isethionate with Stearic Acid mixture, Jordapon CI-65 surfactant combination



APPLICATIONS


Jordapon CI-65 is commonly used in syndet bars, providing gentle cleansing for the skin without stripping away natural oils.
Jordapon CI-65 is utilized in combo bars, offering a blend of cleansing and moisturizing properties in solid soap formulations.
Jordapon CI-65 is incorporated into facial cleansing products, including creams, gels, and foams, for effective removal of impurities while maintaining skin hydration.

Jordapon CI-65 blend finds application in body washes, creating luxurious lather for a refreshing shower experience.
Jordapon CI-65 is added to aerosol shave creams, providing a smooth and comfortable shaving experience by softening facial hair and lubricating the skin.
Jordapon CI-65 is used in facial masks and cleanser pads to enhance the cleansing and exfoliating effects.

Jordapon CI-65 is found in acne treatment products, helping to cleanse pores and reduce excess oil without causing irritation.
The blend is incorporated into intimate hygiene products such as feminine washes, providing gentle cleansing while maintaining pH balance.
Jordapon CI-65 is added to baby care products, including gentle cleansers and diaper creams, for its mildness and skin conditioning properties.

Jordapon CI-65 is used in pet grooming products such as shampoos and conditioners, providing effective cleansing and conditioning for pets' fur and skin.
Jordapon CI-65 is utilized in exfoliating scrubs and body polishes, helping to remove dead skin cells and reveal smoother skin.

Jordapon CI-65 is added to foot care products such as foot scrubs and creams, helping to soften rough skin and soothe tired feet.
Jordapon CI-65 finds application in bath bombs and bath fizzies, creating foamy and aromatic baths for relaxation.
Jordapon CI-65 is incorporated into massage oils and body oils, facilitating smooth application and absorption into the skin.

Jordapon CI-65 is utilized in pre-shave products such as facial scrubs and cleansers, preparing the skin for a closer and smoother shave.
Jordapon CI-65 is added to post-shave products such as balms and lotions, soothing irritation and moisturizing the skin.
Jordapon CI-65 is found in sunless tanning products, helping to distribute the tanning agent evenly for a natural-looking tan.

Jordapon CI-65 is utilized in hair care products such as shampoos and conditioners, providing gentle cleansing and conditioning for all hair types.
Jordapon CI-65 is added to styling products such as mousses and foams, providing hold and volume without weighing down the hair.
Jordapon CI-65 is incorporated into sunscreen formulations, enhancing spreadability and water resistance.

Jordapon CI-65 is utilized in natural and organic personal care products, aligning with consumers' preferences for clean beauty.
Jordapon CI-65 is added to facial mists and sprays, providing hydration and refreshing the skin throughout the day.
Jordapon CI-65 is found in wound care products such as cleansing wipes and antiseptic solutions, facilitating gentle yet effective wound care.

Jordapon CI-65 is utilized in exfoliating lip scrubs and hydrating lip balms, helping to maintain smooth and moisturized lips.
Jordapon CI-65 is a versatile ingredient with applications in various personal care products, offering gentle cleansing, conditioning, and moisturizing properties for the skin and hair.

In facial toners and astringents, Jordapon CI-65 helps to remove excess oil and impurities while toning and tightening the skin.
Jordapon CI-65 is incorporated into facial serums and treatments, assisting in the delivery of active ingredients and improving skin texture.
Jordapon CI-65 is found in anti-aging skincare products such as creams and lotions, helping to reduce the appearance of fine lines and wrinkles.

Jordapon CI-65 is used in hand sanitizers and antibacterial hand washes for effective cleansing and disinfection.
Jordapon CI-65 is added to exfoliating body washes and scrubs, promoting smoother and more radiant skin.
Jordapon CI-65 is utilized in cream and gel-based deodorants, providing gentle cleansing while neutralizing odor.

Jordapon CI-65 is incorporated into intimate lubricants and washes, helping to maintain comfort and hygiene in sensitive areas.
Jordapon CI-65 is found in cuticle creams and nail treatments, moisturizing and nourishing the nails and cuticles.
Jordapon CI-65 is utilized in foot care products such as foot masks and soaks, softening rough skin and relieving dryness.

Jordapon CI-65 is added to bath oils and bath salts, enhancing the relaxation and therapeutic benefits of a warm bath.
Jordapon CI-65 is incorporated into hand creams and lotions, providing long-lasting hydration and protection.
Jordapon CI-65 is found in anti-dandruff shampoos and scalp treatments, helping to soothe irritation and control flakiness.

Jordapon CI-65 is used in body butter and moisturizing creams, providing intense hydration for dry and rough skin.
Jordapon CI-65 is incorporated into lip care products such as lip balms and treatments, helping to repair and nourish chapped lips.
Jordapon CI-65 is utilized in hair masks and deep conditioning treatments, restoring moisture and shine to dry and damaged hair.

Jordapon CI-65 is added to sun care products such as after-sun lotions, providing soothing and moisturizing benefits to sun-exposed skin.
Jordapon CI-65 is found in natural soap formulations, offering gentle cleansing without harsh chemicals or sulfates.
Jordapon CI-65 is utilized in facial exfoliating pads and wipes, providing convenient and effective cleansing on the go.

Jordapon CI-65 is added to bath milk and bath soak formulations, creating a luxurious and indulgent bathing experience.
Jordapon CI-65 is incorporated into hair styling products such as pomades and waxes, providing texture and hold.
Jordapon CI-65 is found in body powder formulations, offering moisture absorption and skin-soothing properties.

Jordapon CI-65 is utilized in anti-cellulite creams and treatments, promoting smoother and firmer-looking skin.
Jordapon CI-65 is added to hand soaps and foaming hand washes, providing effective cleansing with a luxurious lather.
Jordapon CI-65 is found in natural toothpaste formulations, helping to clean and refresh the mouth without harsh chemicals.
Jordapon CI-65 is incorporated into facial essence and essence toners, providing hydration and preparing the skin for subsequent skincare steps.



DESCRIPTION


Jordapon CI-65 is a versatile surfactant blend used in personal care formulations.
Jordapon CI-65 combines Sodium Cocoyl Isethionate and Stearic Acid to create a synergistic effect.
With its creamy texture and mild cleansing properties, Jordapon CI-65 is ideal for gentle skincare products.

Jordapon CI-65 offers excellent foaming capabilities, producing rich lather in cleansing formulations.
Jordapon CI-65 is derived from natural, renewable sources, making it environmentally friendly.
Its low-dusting nature and easy handling characteristics make it suitable for manufacturing processes.

Jordapon CI-65 imparts a soft and smooth after-feel, leaving the skin feeling refreshed and moisturized.
Jordapon CI-65 exhibits mildness, making it suitable for sensitive skin types, including babies and those with dermatological conditions.
Jordapon CI-65 is free from harsh chemicals and sulfates, making it a preferred choice for natural and clean beauty formulations.

Jordapon CI-65 offers biodegradability, ensuring minimal environmental impact upon disposal.
Jordapon CI-65 is compatible with a wide range of cosmetic ingredients, allowing for versatile formulations.
Its stable composition and compatibility with other additives contribute to the overall efficacy of cosmetic products.

In facial cleansers and body washes, Jordapon CI-65 provides thorough yet gentle cleansing without stripping the skin of its natural oils.
Jordapon CI-65 enhances the sensory experience of personal care products, offering a luxurious feel during use.
Jordapon CI-65 contributes to the creamy texture and smooth consistency of creams, lotions, and gels.
In syndet bars and combo bars, the blend creates a dense, long-lasting lather for effective cleansing.

Jordapon CI-65 is commonly used in aerosol shave creams to provide a smooth and comfortable shaving experience.
Jordapon CI-65 is suitable for a variety of hair care products, including shampoos and conditioners, for its cleansing and conditioning properties.
Its versatility extends to bath products such as bath bombs and bubble baths, adding frothy bubbles to the bathwater.

Jordapon CI-65 is often used in natural and organic formulations, aligning with consumers' preferences for clean beauty.
Jordapon CI-65 contributes to the overall stability and shelf life of cosmetic formulations.
Its non-comedogenic nature makes it suitable for facial cleansers and acne treatment products.

Jordapon CI-65's gentle cleansing action makes it suitable for daily use in personal care routines.
Jordapon CI-65 undergoes rigorous quality control measures to ensure consistency and performance in cosmetic applications.
Overall, Jordapon CI-65 is a reliable and versatile ingredient that enhances the efficacy and sensory appeal of personal care products.



PROPERTIES


Chemical Composition: Blend of Sodium Cocoyl Isethionate and Stearic Acid.
Physical Form: Solid (typically in powder or granular form).
Appearance: White to off-white solid.
Odor: Mild, characteristic odor.
Solubility: Soluble in water.
pH (1% aqueous solution): Typically around pH 5-7.
Melting Point: Varies depending on the specific composition and ratio of components.
Boiling Point: Decomposes before boiling.
Density: Varies depending on the specific composition and ratio of components.
Hygroscopicity: May absorb moisture from the air.
Stability: Stable under normal storage and handling conditions.



FIRST AID


Inhalation:

If inhaled, remove the affected person to an area with fresh air.
Allow the individual to rest in a comfortable position and monitor their breathing.
If breathing difficulties persist or if the person becomes unconscious, seek medical attention immediately.
Provide artificial respiration if the person is not breathing and is trained to do so.


Skin Contact:

Remove contaminated clothing and rinse the affected area thoroughly with water for at least 15 minutes.
Use mild soap if available to cleanse the skin gently.
If irritation or redness develops, seek medical attention.
Apply a moisturizing cream or lotion to soothe any discomfort.


Eye Contact:

Immediately flush the eyes with gently flowing water for at least 15 minutes, holding the eyelids open to ensure thorough rinsing.
Remove contact lenses, if present and easily removable, after the initial flushing, and continue rinsing.
Seek immediate medical attention if irritation, redness, or other symptoms persist after rinsing.


Ingestion:

If swallowed, rinse the mouth thoroughly with water.
Do not induce vomiting unless instructed to do so by medical personnel.
Seek medical attention immediately.
Provide supportive care as directed by medical professionals.



HANDLING AND STORAGE


Handling Precautions:

When handling Jordapon CI-65, wear appropriate personal protective equipment (PPE) such as safety goggles, gloves, and protective clothing to minimize the risk of skin and eye contact.
Avoid inhalation of dust or aerosols by working in a well-ventilated area or using local exhaust ventilation systems.
Do not eat, drink, or smoke while handling Jordapon CI-65 to prevent accidental ingestion.
Wash hands thoroughly with soap and water after handling Jordapon CI-65 and before eating, drinking, or using the restroom.
Keep Jordapon CI-65 containers tightly closed when not in use to prevent contamination and moisture absorption.
Use suitable tools and equipment, such as scoops or spatulas, to handle Jordapon CI-65 and minimize dust generation.
Clean up spills promptly using suitable absorbent materials and dispose of them in accordance with local regulations.
Store Jordapon CI-65 away from incompatible materials such as strong acids, oxidizing agents, and alkalis to prevent hazardous reactions.
Avoid contact with skin, eyes, and clothing. In case of contact, follow appropriate first aid measures.


Storage Conditions:

Store Jordapon CI-65 in a cool, dry, and well-ventilated area away from direct sunlight and heat sources.
Keep containers tightly closed and upright to prevent spills and leakage.
Store Jordapon CI-65 away from sources of ignition and open flames to reduce the risk of fire.
Maintain proper labeling on Jordapon CI-65 containers, including product name, composition, and hazard warnings.
Store Jordapon CI-65 separately from food, beverages, and animal feed to prevent contamination.
Inspect Jordapon CI-65 containers regularly for signs of damage, leakage, or deterioration, and replace them if necessary.
Store Jordapon CI-65 containers on shelves or pallets to prevent direct contact with the floor and facilitate inspection and handling.
Keep Jordapon CI-65 containers in a secure area accessible only to authorized personnel to prevent unauthorized access or tampering.
Follow any specific storage instructions provided by the manufacturer or supplier, including temperature and humidity requirements.
Ensure that storage areas are equipped with appropriate firefighting equipment and spill containment measures in case of emergencies.


Transportation Precautions:

When transporting Jordapon CI-65, use suitable containers that are compatible with the chemical and securely sealed to prevent leaks or spills.
Ensure that Jordapon CI-65 containers are properly labeled with product information and hazard warnings.
Follow applicable regulations and guidelines for the transportation of hazardous chemicals, including packaging, labeling, and documentation requirements.
Take precautions to prevent damage to Jordapon CI-65 containers during loading, unloading, and transportation.
In case of spills or leaks during transportation, follow established procedures for containment, cleanup, and disposal.
Provide training to personnel involved in the transportation of Jordapon CI-65 to ensure safe handling practices and emergency response procedures.
JORDAPON SCI

Jordapon SCI is a mild and gentle surfactant commonly used in personal care products.
Jordapon SCI is derived from coconut oil and is known for its excellent cleansing properties.
Jordapon SCI is available in powder or granular form, making it easy to incorporate into various formulations.

CAS Number: 61789-32-0
EC Number: 263-052-5

SCI, Sodium coco sulfate, Sodium cocoyl isethionate, Sodium N-cocoyl-N-methyltaurate, Sodium isethionate, Sodium cocoyl glycinate, Sodium cocoyl methyl taurate, Sodium cocoyl sarcosinate, Sodium cocoyl glutamate, Sodium cocoyl alaninate, Sodium N-lauroyl-N-methyltaurate, Sodium N-cocoyl-N-methylglycinate, Sodium lauroyl sarcosinate, Sodium cocoyl hydrolyzed wheat protein, Sodium cocoyl collagen amino acids, Sodium cocoyl silk amino acids, Sodium cocoyl oat amino acids, Sodium lauroyl oat amino acids, Sodium lauroyl hydrolyzed collagen, Sodium cocoyl hydrolyzed collagen, Sodium cocoyl hydrolyzed keratin, Sodium lauroyl hydrolyzed keratin, Sodium cocoyl hydrolyzed silk, Sodium lauroyl hydrolyzed silk, Sodium lauroyl hydrolyzed oat protein, Sodium cocoyl hydrolyzed oat protein, Sodium lauroyl hydrolyzed soy protein, Sodium cocoyl hydrolyzed soy protein, Sodium lauroyl hydrolyzed wheat protein, Sodium cocoyl hydrolyzed wheat protein, Sodium lauroyl hydrolyzed rice protein, Sodium cocoyl hydrolyzed rice protein, Sodium lauroyl hydrolyzed quinoa, Sodium cocoyl hydrolyzed quinoa, Sodium lauroyl hydrolyzed amaranth, Sodium cocoyl hydrolyzed amaranth, Sodium lauroyl hydrolyzed millet, Sodium cocoyl hydrolyzed millet, Sodium lauroyl hydrolyzed barley, Sodium cocoyl hydrolyzed barley, Sodium lauroyl hydrolyzed corn protein, Sodium cocoyl hydrolyzed corn protein, Sodium lauroyl hydrolyzed pea protein, Sodium cocoyl hydrolyzed pea protein, Sodium lauroyl hydrolyzed soybean protein, Sodium cocoyl hydrolyzed soybean protein, Sodium lauroyl hydrolyzed sunflower seed protein, Sodium cocoyl hydrolyzed sunflower seed protein, Sodium lauroyl hydrolyzed vegetable protein, Sodium cocoyl hydrolyzed vegetable protein, Sodium lauroyl hydrolyzed lupine protein, Sodium cocoyl hydrolyzed lupine protein, Sodium lauroyl hydrolyzed pumpkin seed protein, Sodium cocoyl hydrolyzed pumpkin seed protein, Sodium lauroyl hydrolyzed sesame seed protein, Sodium cocoyl hydrolyzed sesame seed protein, Sodium lauroyl hydrolyzed almond protein, Sodium cocoyl hydrolyzed almond protein



APPLICATIONS


Jordapon SCI is commonly used in shampoo formulations for its excellent cleansing properties.
Jordapon SCI is employed in body washes and shower gels to create a rich and creamy lather that effectively cleanses the skin.
Jordapon SCI is a key ingredient in facial cleansers and cleanser bars due to its gentle yet effective cleansing action.

Jordapon SCI is used in baby care products such as gentle cleansers and bubble baths for its mildness.
Jordapon SCI is utilized in hand soaps and liquid hand washes to provide thorough cleansing without drying out the skin.

Jordapon SCI is incorporated into sulfate-free and natural hair care products as a gentle alternative to traditional surfactants.
Jordapon SCI is found in shaving creams and foams to provide lubrication and help soften facial hair for a smooth shave.

Jordapon SCI is used in bath bombs and bath salts to create foaming and bubbling effects in the bathwater.
Jordapon SCI is added to facial scrubs and exfoliating cleansers to help remove dead skin cells and unclog pores.

Jordapon SCI is utilized in toothpaste formulations to create foam and assist in the removal of plaque and debris from the teeth.
Jordapon SCI is incorporated into liquid and bar soap formulations for its ability to produce stable and long-lasting lather.

Jordapon SCI is used in pet grooming products such as shampoos and conditioners for its gentle cleansing properties.
Jordapon SCI is employed in intimate hygiene products such as feminine washes and wipes to maintain freshness and cleanliness.

Jordapon SCI is found in facial masks and cleanser pads for its ability to deliver cleansing and exfoliating benefits.
Jordapon SCI is used in pre-shave and post-shave products to help prepare the skin for shaving and soothe irritation afterward.
Jordapon SCI is added to bath oils and bath melts to help disperse essential oils and moisturizing ingredients in the bathwater.
Jordapon SCI is utilized in sunscreen formulations as an emulsifier and surfactant to improve spreadability and water resistance.

Jordapon SCI is found in hair styling products such as mousses and foams to provide hold and volume without weighing down the hair.
Jordapon SCI is employed in facial cleanser wipes and makeup remover wipes for convenient and effective cleansing on the go.

Jordapon SCI is used in foot care products such as foot scrubs and foot soaks to help soften calluses and remove dead skin.
Jordapon SCI is found in acne treatment products such as cleansers and spot treatments for its gentle yet effective cleansing action.

Jordapon SCI is utilized in deodorant formulations as a mild surfactant to help disperse active ingredients and provide cleansing benefits.
Jordapon SCI is incorporated into bath bombs and shower steamers to create a foaming and aromatic experience in the shower or bath.
Jordapon SCI is used in scalp treatments and dandruff shampoos for its cleansing and soothing properties on the scalp.
Jordapon SCI is found in natural and organic personal care products as a preferred alternative to harsher surfactants due to its mildness and biodegradability.

Jordapon SCI is utilized in facial cleanser formulations to provide a gentle yet thorough cleansing experience for sensitive skin types.
Jordapon SCI is incorporated into makeup remover products such as cleansing balms and oils to effectively dissolve and remove makeup.
Jordapon SCI is added to bath foams and bubble baths to create luxurious and long-lasting bubbles for a relaxing bathing experience.

Jordapon SCI is found in body scrubs and exfoliating treatments to help slough off dead skin cells and reveal smoother skin.
Jordapon SCI is used in hair masks and deep conditioning treatments to help improve the manageability and softness of the hair.

Jordapon SCI is added to hair coloring products such as shampoos and conditioners to help maintain color vibrancy and prolong color retention.
Jordapon SCI is employed in hair volumizing products such as mousses and foams to provide lift and body to fine or limp hair.
Jordapon SCI is found in dry shampoo formulations to help absorb excess oil and refresh the hair between washes.

Jordapon SCI is utilized in intimate hygiene products such as feminine washes and wipes to maintain pH balance and freshness.
Jordapon SCI is incorporated into hand sanitizers and antibacterial hand washes for its cleansing and disinfecting properties.
Jordapon SCI is added to facial toners and astringents to help remove excess oil and impurities from the skin's surface.

Jordapon SCI is found in anti-aging skincare products such as serums and creams to help improve skin texture and reduce the appearance of fine lines.
Jordapon SCI is used in foot scrubs and foot soaks to help soften rough skin and soothe tired feet.

Jordapon SCI is employed in cuticle creams and nail treatments to help moisturize and nourish the nails and cuticles.
Jordapon SCI is added to bath salts and bath teas to help enhance the relaxation and therapeutic benefits of a warm bath.

Jordapon SCI is found in body lotions and moisturizers to help improve skin hydration and prevent moisture loss.
Jordapon SCI is utilized in lip scrubs and lip balms to help exfoliate and hydrate the lips for a smoother, softer appearance.

Jordapon SCI is incorporated into massage oils and body oils to help facilitate glide and absorption into the skin.
Jordapon SCI is added to sunless tanning products such as mousses and lotions to help distribute the tanning agent evenly across the skin.

Jordapon SCI is found in acne spot treatments and blemish control products for its cleansing and soothing properties.
Jordapon SCI is used in natural and organic personal care products such as bar soaps and solid shampoos for its mildness and biodegradability.

Jordapon SCI is employed in bath bombs and bath fizzies to help create effervescent and aromatic baths.
Jordapon SCI is added to pet grooming products such as shampoos and conditioners for its gentle cleansing and conditioning properties.

Jordapon SCI is found in facial mists and sprays to help hydrate and refresh the skin throughout the day.
Jordapon SCI is utilized in wound care products such as cleansing wipes and antiseptic solutions for its gentle yet effective cleansing action on the skin.



DESCRIPTION


Jordapon SCI is a mild and gentle surfactant commonly used in personal care products.
Jordapon SCI is derived from coconut oil and is known for its excellent cleansing properties.
Jordapon SCI is available in powder or granular form, making it easy to incorporate into various formulations.

Jordapon SCI produces rich, creamy lather that effectively removes dirt, oil, and impurities from the skin and hair.
Jordapon SCI is often used in shampoos, body washes, facial cleansers, and baby care products due to its mildness.

Jordapon SCI is suitable for all skin types, including sensitive and delicate skin, as it does not cause irritation or dryness.
Jordapon SCI helps to soften and condition the skin, leaving it feeling smooth and moisturized after use.
In hair care products, Jordapon SCI helps to cleanse the scalp and hair without stripping away natural oils or causing damage.

Jordapon SCI is often found in sulfate-free and gentle cleansing formulas designed to maintain the natural balance of the skin and hair.
Jordapon SCI is biodegradable and environmentally friendly, making it a preferred choice for eco-conJordapon SCIous consumers.

Jordapon SCI has excellent foaming properties, contributing to luxurious lather in personal care products.
Jordapon SCI is compatible with other surfactants and cosmetic ingredients, allowing for versatile formulations.

Jordapon SCI helps to stabilize emulsions and improve the overall texture and feel of cosmetic products.
Jordapon SCI is pH-balanced and does not disrupt the skin's natural acid mantle, making it suitable for daily use.

Jordapon SCI is non-comedogenic and does not clog pores, making it suitable for use in facial cleansers and acne treatments.
Jordapon SCI is considered safe for use in cosmetics and personal care products when used as directed.

Jordapon SCI is often used in combination with other surfactants to enhance performance and sensory attributes.
Jordapon SCI is free from harsh chemicals such as sulfates, parabens, and phthalates, making it a preferred choice for natural and clean beauty formulations.

Jordapon SCI is produced using sustainable and environmentally friendly manufacturing processes.
Jordapon SCI has a neutral odor and does not impart fragrance to cosmetic products, making it suitable for fragrance-sensitive individuals.

Jordapon SCI is readily biodegradable and does not accumulate in the environment, minimizing its ecological impact.
Jordapon SCI is gentle enough for use in baby care products such as gentle cleansers and diaper creams.

Jordapon SCI is often used in facial cleansers and exfoliating scrubs to provide gentle yet effective cleansing and exfoliation.
Jordapon SCI is water-soluble and rinses off easily without leaving a residue on the skin or hair.
Jordapon SCI is a versatile and effective surfactant that offers gentle cleansing and conditioning benefits for the skin and hair.



PROPERTIES


Chemical Formula: C₂₈H₅₅NO₇S
Molecular Weight: Approximately 573.81 g/mol
Physical Form: Solid (typically in powder or granular form)
Appearance: White to off-white solid
Odor: Mild, characteristic odor
Solubility: Soluble in water
pH (1% aqueous solution): Typically around pH 5-7
Melting Point: Varies depending on the specific grade, typically around 150-180°C
Boiling Point: Decomposes before boiling
Density: Varies depending on the specific grade
Hygroscopicity: Hygroscopic (absorbs moisture from the air)
Stability: Stable under normal storage and handling conditions
Compatibility: Compatible with a wide range of cosmetic ingredients and additives
Foaming Properties: Produces rich, creamy lather in water
Cleansing Ability: Effectively removes dirt, oil, and impurities from the skin and hair
Emulsifying Ability: Acts as an emulsifier, helping to stabilize oil-in-water emulsions
Mildness: Gentle on the skin and hair, suitable for sensitive skin types
Biodegradability: Readily biodegradable under aerobic conditions
Environmental Impact: Low environmental toxicity and minimal environmental impact when used as directed



FIRST AID


Inhalation:

If inhaled, move the affected person to an area with fresh air.
Allow the person to rest in a comfortable position and keep them warm.
If breathing difficulties persist, seek medical attention immediately.
Provide artificial respiration if the person is not breathing and trained to do so.


Skin Contact:

Remove contaminated clothing and rinse the affected area with plenty of water for at least 15 minutes.
If irritation or redness occurs, seek medical attention.
Wash contaminated skin thoroughly with soap and water.
Apply a mild moisturizer or emollient to soothe any discomfort.


Eye Contact:

Immediately flush the eyes with gently flowing water for at least 15 minutes, holding the eyelids open to ensure thorough rinsing.
Remove contact lenses, if present and easily removable, after the initial flushing, and continue rinsing.
Seek immediate medical attention if irritation, redness, or other symptoms persist after rinsing.


Ingestion:

If swallowed, rinse the mouth thoroughly with water.
Do not induce vomiting unless instructed by medical personnel.
Seek medical attention immediately.
Provide supportive care as directed by medical professionals.


First Aid for First Responders:

Wear appropriate personal protective equipment (PPE), including gloves, goggles, and protective clothing, when providing first aid.
Avoid direct contact with the chemical to prevent secondary exposure.
Follow standard first aid procedures and protocols for chemical exposures.
If unsure about the appropriate course of action, contact poison control or seek guidance from a healthcare professional.



HANDLING AND STORAGE


Handling Precautions:

When handling Jordapon SCI, wear appropriate personal protective equipment (PPE), including safety goggles, gloves, and protective clothing, to minimize the risk of skin and eye contact.
Avoid inhalation of dust or aerosols by working in a well-ventilated area or using local exhaust ventilation systems.

Do not eat, drink, or smoke while handling Jordapon SCI to prevent accidental ingestion.
Wash hands thoroughly with soap and water after handling Jordapon SCI and before eating, drinking, or using the restroom.
Keep Jordapon SCI containers tightly closed when not in use to prevent contamination and moisture absorption.

Avoid contact with incompatible materials, such as strong acids, oxidizing agents, and alkalis, to prevent hazardous reactions.
Use appropriate tools and equipment, such as scoops or spatulas, to handle Jordapon SCI and minimize dust generation.
Clean up spills promptly using suitable absorbent materials and dispose of them in accordance with local regulations.


Storage Conditions:

Store Jordapon SCI in a cool, dry, well-ventilated area away from sources of heat and ignition.
Keep containers tightly closed and upright to prevent spills and leakage.
Store Jordapon SCI away from direct sunlight and moisture to prevent degradation and caking.
Maintain proper labeling on Jordapon SCI containers, including product name, chemical composition, and hazard warnings.

Store Jordapon SCI separately from incompatible materials, such as acids, oxidizing agents, and alkalis, to prevent hazardous reactions.
Do not store Jordapon SCI near food, beverages, or animal feed to avoid contamination.
Store Jordapon SCI containers on shelves or pallets to prevent direct contact with the floor and facilitate inspection and handling.

Check Jordapon SCI containers regularly for signs of damage, leakage, or deterioration, and replace them if necessary.
Follow any specific storage instructions provided by the manufacturer or supplier, including temperature and humidity requirements.
Keep Jordapon SCI containers in a secure area accessible only to authorized personnel to prevent unauthorized access or tampering.


Transportation Precautions:

When transporting Jordapon SCI, use appropriate containers that are compatible with the chemical and securely sealed to prevent leaks or spills.
Ensure that Jordapon SCI containers are properly labeled with the product name, hazard warnings, and handling instructions.

Follow applicable regulations and guidelines for the transportation of hazardous chemicals, including packaging, labeling, and documentation requirements.
Take precautions to prevent damage to Jordapon SCI containers during loading, unloading, and transportation.

In case of spills or leaks during transportation, follow established procedures for containment, cleanup, and disposal.
Provide training to personnel involved in the transportation of Jordapon SCI to ensure safe handling practices and emergency response procedures.


Emergency Procedures:

In the event of a spill, leak, or accidental release of Jordapon SCI, follow established emergency procedures for chemical spills and hazardous material incidents.
Evacuate the area if necessary to prevent exposure to chemical vapors or dust.
Notify appropriate personnel, such as safety officers, supervisors, or emergency responders, of the incident.

Provide information about the chemical involved, including its identity, quantity, and location.
Use appropriate containment measures, absorbent materials, and personal protective equipment to safely clean up spills.
Dispose of contaminated materials and waste in accordance with local regulations and guidelines.

Report the incident to appropriate authorities, such as workplace safety officials or poison control centers, if necessary.
Provide follow-up care and monitoring for individuals involved in the incident to ensure their health and safety.
JORDAPON SCI
Jordapon SCI is an anionic surfactant and a good foamer.
Jordapon SCI offers benefits including soft after feel, mildness and biodegradability.
Jordapon SCI is based upon fatty acids from natural, renewable coconut oil.


CAS Number: 61789-32-0 / 58969-27-0
EC Number: 263-052-5
INCI NAME: Sodium Cocoyl Isethionate.
Chem/IUPAC Name:Fatty acids, coco, 2-sulfoethyl esters, sodium salts
MDL Number: MFCD01772282
Molecular formula: C6H11NaO5S


Jordapon SCI Powder is a very highly active, finely divided, free-flowing powder (sodium cocoyl isethionate) used in syndet bars, combo bars, liquid soaps, facial cleansers, body washes and shampoos.
Jordapon SCI has high foaming power, extreme mildness, and a soft and silky skin feel.


Jordapon SCI foams excellently in even hard water, convinces with its mild scent and is also called baby foam because of its gentleness.
Jordapon SCI is an anionic co-surfactant ideally suited for mild personal care cleansing products, such as shampoo, body wash, liquid soap and syndet bar.


Jordapon SCI is a Solid.
Jordapon SCI is a very high activity, solid Sodium Cocoyl Isethionate that is used in syndet bars, combo bars, liquid soaps, adnfacial cleansers.


Jordapon SCI is a very high activity, solid Sodium Cocoyl Isethionate that is used in syndet bars, combo bars, liquid soaps, facial cleansers, body cleansers and shampoos.
Jordapon SCI has high foaming performance, extreme mildness, as well as soft and silky skin after feel characteristics.


Jordapon SCI is an anionic surfactant and a good foamer.
Jordapon SCI offers benefits including soft after feel, mildness and biodegradability.
Jordapon SCI is based upon fatty acids from natural, renewable coconut oil.


Jordapon SCI is an anionic co-surfactant ideally suited for mild personal care cleansing products, such as shampoo, body wash, liquid soap and syndet bar.
Jordapon SCI is an easy to handle, coconut derived, anionic, mild primary surfactant which creates a product with a dense and luxurious foam.


Jordapon SCI can be used alone to make a cream or solid cleansing bar, or combined with other surfactants to make a creamy shampoo or body wash.
Jordapon SCI creates an elegant feel during use and a conditioned after feel in both hair and skincare formulations.
Jordapon SCI is a sodium salt of the fatty acid, isethionic acid.


Jordapon SCI is a very high activity, solid Sodium Cocoyl Isethionate that is used in syndet bars, combo bars, liquid soaps, facial cleansers, body cleansers, and shampoos.
Jordapon SCI has high foaming performance, extreme mildness, as well as soft and silky skin after feel characteristics.


Jordapon SCI is mild to skin and eyes.
Jordapon SCI is an excellent foamers in hard or soft water.
Jordapon SCI is impart a soft after-feel to skin.


Jordapon SCI has mild odor.
Jordapon SCI is based upon fatty acids from natural, renewable coconut oil.
Jordapon SCI is completely biodegradable.


Jordapon SCI is a very high-activity, solid sodium cocoyl isethionate.
Jordapon SCI is a white flakes.
Jordapon SCI is an anionic surfactant obtained from coconut oil


Jordapon SCI is a light surfactant, gentle on the eyes and skin and friendly to the environment since it is based on purified fatty acids derived from coconut oil, which is a natural, renewable and biodegradable resource .
If you are making a liquid product with Jordapon SCI, it will need to be dissolved in a suitable solvent first.


Jordapon SCI does not dissolve readily into water; I once combined some Jordapon SCI with water in a jar, sealed it, and left it for 6 months.
Jordapon SCI never dissolved.
I recommend combining Jordapon SCI with the liquid amphoteric surfactant that is likely also present in the recipe and heating the two together in a water bath until you have a uniform paste.


That paste will dissolve into water.
If you are working with a large amount of this Jordapon SCI + amphoteric surfactant blend you can speed things along by using an immersion blender to get the mixture silky smooth—the low water content means it won’t lather up, but you’ll get a smooth paste very quickly!


You can also speed up the process by running your Jordapon SCI through a coffee grinder before combining it with the liquid amphoteric surfactant—just be sure you are wearing your dust mask!
Hydrous formulations including Jordapon SCI should have a pH of 6–8 or the Jordapon SCI can hydrolyze.


That said, I have made more acidic formulations featuring Jordapon SCI and haven’t had troubles—though those batches would’ve been quite small and the products were finished quickly.
Jordapon SCI is a surfactant based on fatty acids from coconut oil and isoethionic acid, a type of sulfonic acid.


Commonly known as Baby Foam due to its exceptional mildness, Jordapon SCI is a surfactant that is comprised of a type of sulphonic acid called Isethionic Acid as well as the fatty acid – or sodium salt ester – obtained from Coconut Oil.
Jordapon SCI is a traditional substitute for sodium salts that are derived from animals, namely sheep and cattle.


Jordapon SCI is a solid, gentle anionic surfactant made from coconut oil.
Jordapon SCI is really versatile and lovely, and is considered natural.
Jordapon SCI is a powdered surfactant made from renewable coconut fatty acids that is fully biodegradable.


Jordapon SCI is one of the gentlest surfactants on the market leading it to also being known as Baby Foam, as this surfactant is mild enough to be used in baby products and personal cleansers like eye makeup remover.
Jordapon SCI is made from the renewable fatty acid, or sodium salt ester, that is obtained from Coconut Oil.


Jordapon SCI is a common replacement for animal-derived sodium salts such as Sodium Tallowate.
Jordapon SCI is a biodegradable, powdered surfactant that allows it to easily be added to formulations.
Jordapon SCI is one of the gentlest and mildest surfactants on the market, leading it to acquire the moniker of Baby Foam due to its use in various baby products.


Jordapon SCI is an anionic surfactants of vegetable and synthetic origins from fatty acids of coconut oil (derived from fatty acids of coconut oil) and isethionic acid.
Solid, Jordapon SCI is in the form of white granules or powder.


Once integrated into a formula, Jordapon SCI is soft for the eyes and biodegradable.
Jordapon SCI is soluble in water, and insoluble in oil.
Jordapon SCI is soft, very foaming cleaner.


Jordapon SCI leaves the skin and the hair soft.
Jordapon SCI is liquid and solid shampoos.
In the dry state, Jordapon SCI is very irritating for the respiratory tract.


Jordapon SCI is mild, high foaming, sulfate-free anionic surfactant combined with disodium cocoyl glutamate, a gentle cleanser produced from natural sources including coconut fatty acids and fermented sugar.
Jordapon SCI is mild anionic surfactant.


Jordapon SCI has high foaming performance, extreme softness, as well as silky smooth skin characteristics after touch.
Jordapon SCI is Gentle on skin and eyes.
Jordapon SCI is ideal for baby care and gentle cleaning products.


Jordapon SCI is made from natural coconut oil and is completely biodegradable.
Jordapon SCI is recommended for systems where a low percentage of fatty acids is needed, e.g. shampoos, bath and shower gels and liquid soaps.
Jordapon SCI is soluble in some water.


Jordapon SCI is a naturally-derived ingredient that comes from the fatty acids that are present in isethionic acid and coconut oil.
Jordapon SCI is also soluble in surfactants (some formulations may require some heat)
No ethoxylation takes place in the manufacture of Jordapon SCI.


Jordapon SCI is an ester of long-chain aliphatic carboxylic acids ( fatty acids ) obtained from coconut oil with isethionic acid or sodium isethionate and belongs to the class of isethionates, which are also referred to in the literature as acyl isethionates or, according to chemical nomenclature, as 2-sulfoethylcarboxylic acid esters or acyloxyethanesulfonates.


The most important representative of this class of mild anionic surfactants is Jordapon SCI, which is referred to in the English literature as Jordapon SCI.
Jordapon SCI is a mild, high foaming anionic surfactant with high purity made from coconut fatty acids.


Jordapon SCI has minimum 85% active matter.
Jordapon SCI has free fatty acid 14% maximum.
Jordapon SCI has excellent foam density and foam stability.


Jordapon SCI has very good lime soap dispersion and surface activity. Leaves no soap scum as it is very hard water tolerant.
Jordapon SCI is compatible with soaps and anionic, non-ionic, and amphoteric surfactant.
Jordapon SCI is excellent lathering; exceptionally mild, provides soft skin after-feel.



These fatty acids are reacted with sodium isethionate and the mixture is heated to remove any water left behind.
Further, the mixture is distilled to remove excess fatty acids.
In its raw form, Jordapon SCI appears as a fine white powder.


Jordapon SCI is a naturally-derived ingredient that comes from the fatty acids that are present in isethionic acid and coconut oil.
These fatty acids are reacted with sodium isethionate and the mixture is heated to remove any water left behind.
Further, the mixture is distilled to remove excess fatty acids.


Jordapon SCI is a gentle surfactant derived from coconut oil that is commonly used in skincare and haircare products.
This white, powdery substance, Jordapon SCI, has gained popularity due to its mild, non-irritating nature, making it suitable for a variety of personal care applications.


Jordapon SCI is a sodium salt of the coconut fatty acid ester of isethionic acid.
Jordapon SCI is an anionic surfactant, meaning it carries a negative charge that helps to create a lather and lift dirt, oil, and impurities from the skin and hair.


A cleansing agent, Jordapon SCI is claimed to be so gentle on the skin that it hardly impacts the skin barrier.
Jordapon SCI also gives a rich, creamy foam, it's based on vegetable fatty acids and is readily biodegradable.
Jordapon SCI's an especially important and popular ingredient in "syndet bars" (or soapless soaps).


Jordapon SCI provides skincare benefits and serves as a fantastic alternative to harsher, drying cleansers (like sulfates).
Jordapon SCI is a natural surfactant derived from Vegetable Oils.
Jordapon SCI has high foaming performance, extreme mildness, as well as soft and silky skin after feel characteristics.


Jordapon SCI in powder form is much easier to incorporate into your products compared to noodles or granular alternatives.
Jordapon SCI is a surfactant made up of Isethionic Acid, a form of sulphonic acid, and the fatty acid – or sodium salt ester – produced from Coconut Oil.


Jordapon SCI’s commonly referred to as Baby Foam because of its outstanding mildness.
Jordapon SCI is an anionic surfactant, i.e. an amphophilic compound.
These compounds dissociate and are biodegradable.


Their most frequent application is in cosmetic products.
Jordapon SCI is an ingredient derived from coconut oil.
Jordapon SCI is a fine white Powder and far superior to the SCI granules, flakes or needles currently available on the market.


Jordapon SCI is naturally derived and biodegradeable while being suitable for Vegans.
Jordapon SCI is a mild surfactant (cleansing agent) derived from isethionic acid and coconut fatty acids.
In its raw state, Jordapon SCI usually appears as white granular solids.


Jordapon SCI can be used in personal care products as a gentle surfactant, helping to mix water with oil and dirt so they can be washed away, without stripping the skin's natural barrier.
Like many coconut-derived cleansers, Jordapon SCI also contributes to lather, producing a luxurious creamy foam that does not dry out skin.


Jordapon SCI is a mild soap-free cleansing agent known for its ability to mitigate disruption of skin’s barrier.
Jordapon SCI is derived from coconut and is regarded as compatible with sensitive skin.
Jordapon SCI’s an anionic surfactant, meaning a cleansing agent with a negative instead of a positive charge.


Anionic surfactants are the most common type due to their ability to lift and suspend dirt, oil, and debris, allowing them to be washed away.
Suppliers of Jordapon SCI tout its gentle foaming action as a desirable quality for consumers, even though the foam itself has little cleansing ability.


In addition to skin care formulations, Jordapon SCI is a popular ingredient in hair products.
Jordapon SCI is a powder in its raw material form.
Jordapon SCI is a natural ingredient that is derived from coconuts, specifically coconut oil and isethionic acid.


Jordapon SCI exhibits high foaming ability, producing a stable, rich and velvety lather, without damaging the moisture barrier or taking stripping away hydration.



USES and APPLICATIONS of JORDAPON SCI:
Personal Care uses of Jordapon SCI; Beauty & Care, Baby Care, Bath & Shower, Hair Care, and Skin Care.
HI&I Care uses of Jordapon SCI;Home Care and Pet Care
Bath & Shower Applications of Jordapon SCI: Bar Soaps, Body Wash, and Liquid Soap.


Hair Care Applicationso of Jordapon SCI: Hair Conditioner, and Shampoos & Rinses.
Skin Care Applications of Jordapon SCI: Facial Cleanser, and Skin Cleanser.
Jordapon SCI is our favourite surfactant - it's just so giving!


Jordapon SCI provides loads of lather, and can be used to make liquid and solid bar cleansers and shampoos.
Jordapon SCI is used Bath & Shower, Body Care, Hand Cleansing, Skin Cleansing
Jordapon SCI can be used in Syndet (synthetic detergent) bars, Combobars (mixtures of synthetic and soap), Liquid soaps, Facial cleansers, and Body cleansers and shampoos.


Jordapon SCI is used in personal cleansing products like syndet bar, combo bars, foaming facial washes, body washes, shampoos, bath and showers gels and liquid soaps.
Jordapon SCI is used Anionic co-surfactant ideally suited for mild personal care cleansing products, such as shampoo, body wash, liquid soap and syndet bar.


Applications of Jordapon SCI: Bath & Shower, Body Care, Hair Cleansing, Hand Cleansing, Liquid Soap, Skin Care, Skin Cleansing
Jordapon SCI is used Baby Care and Cleansing, Face Cleansing, Liquid Soap, Shampoo, Shower/Bath Products
Jordapon SCI is a detergent that blends well with skin and hair.


Therefore, Jordapon SCI can be used as a coagulant in cleaning formulas such as facial cleansing gel/cream, facial cleansing powder, shampoo, liquid soap, shower cream.
Jordapon SCI is commonly used in formulas that are gentle (mildness).


Jordapon SCI is also used in the production of soap bars (Syndet bar).
Jordapon SCI is used Gentle, high foaming personal cleansing products, Bar toilet soaps, Pearlescent liquid soaps, Foams for facial wash, Body shampoos, Hair shampoos, and Sulfate-free shampoos.


Jordapon SCI is a natural anionic surfactant which allows the implementation of solid foaming agents, but also without sulfate .
Due to its anionic nature Jordapon SCI offers a beautiful dense and airy foam.
Jordapon SCI can be used with cleaning products


Jordapon SCI can be used as a primary or secondary surfactant, it is recommended for systems where low levels of fatty acids are needed; for example: shampoos, bath gels and liquid soaps, although their predominant commercial use is in formulations of synthetic bar soaps “Syndet bar” and “combo bars”, the latter being bars made up of a mixture of synthetic surfactant and soap.


Jordapon SCI is used Gentle, high foaming personal cleansing products, Bar toilet soaps , Pearlescent liquid soaps, Foams for facial wash, Body shampoos, Hair shampoos, and Sulfate-free shampoos
Jordapon SCI is used in syndet bars, combo bars, liquid soaps, facial cleansers, body cleansers, and shampoos.


Jordapon SCI has high foaming performance, extreme mildness, as well as soft and silky skin after-feel characteristics.
Jordapon SCI has a neutral pH and can be used in pharmaceutical preparations.
Jordapon SCI has been shown to have anti-cancer effects in clinical studies by inhibiting the growth of skin cancer cells.


Jordapon SCI also has skin conditioning properties and can be used as an emulsifier.
Jordapon SCI is typically found in concentrations between 64-68%.


Because of its excellent skin compatibility , its pronounced foam formation and foam stability, Jordapon SCI is also used in hard water, its good cleaning effect and its pleasant feeling on the skin in soap bars, the so-called syndet bars or in combination with soaps in the so-called combo bars, which are used in particular as baby soaps find.


Because of its low water solubility (approx. 0.01% = 100ppm at 25 °C), Jordapon SCI must be solubilized for use in liquid washing solutions, i.e. H. its concentration in the soap micelles can be increased.
This is done, for example, B. the addition of secondary surfactants or the exchange of sodium cations for ammonium cations [ammonium cocoyl isethionate is very water-soluble with >25% by weight at 25 ° C].


Jordapon SCI is used Hair shampoo, hand shampoo, pet shampoo, professional shampoo, baby shampoo, facial cleansers, solid shampoo.
To incorporate Jordapon SCI into a formulation, it is recommended that the chips be crushed prior to melting, as this helps to increase their melting rate.


Next, Jordapon SCI must be heated slowly on low heat in order to allow for easy mixing with other surfactants.
It is recommended that Jordapon SCI phase be mixed using a high shear stick blender.
This approach helps to prevent the excess foaming that could potentially occur if the stick blender is used to mix all ingredients together at once.


Finally, Jordapon SCI mixture can be added to the rest of the formulation.
Jordapon SCI is used to create solid cleansers and opaque liquid cleansers.
Jordapon SCI has numerous functions and applications in skincare and haircare products due to its mild, non-irritating properties.


Shampoos and conditioners uses of Jordapon SCI: As a surfactant, Jordapon SCI helps as a cleaning agent to hair and the scalp, removing dirt, oil, and impurities without causing irritation or damaging the hair.
Facial cleansers uses of Jordapon SCI: Jordapon SCI's gentle nature makes it ideal for use in facial cleansers, particularly for sensitive skin.


Bar soaps uses of Jordapon SCI: Jordapon SCI can be found in bar soaps, where it creates a creamy lather and cleanses the skin without causing dryness or irritation.
Hair styling products uses of Jordapon SCI: In hair styling products, Jordapon SCI can provide a smooth texture and aid in the even distribution of other ingredients.


Jordapon SCI is primarily a surfactant that is gentle on the surface and provides many benefits to skin and hair.
Jordapon SCI is thus commonly used in the cosmetic world.
Jordapon SCI can be used in clear / pearlescent gels.


Jordapon SCI is an anionic surfactant that gives a creamy, foaming texture to your recipes for solid cleansing products.
Jordapon SCI is derived from the fatty acids in 100% natural Coco oil.
The plant-derived Jordapon SCI adds softness to skin and hair and improves detangling.


Available in granulated form, Jordapon SCI is more convenient to use than powder because of its volatility.
To use, put the Jordapon SCI in a little water and heat the mixture in a bain-marie.
Stir until the mixture forms a paste.


You can then add it to your recipe for solid shampoo, soap or other products.
Jordapon SCI is a sulphate-free, mild anionic surfactant.
Jordapon SCI is derived from the fatty acids of coconut oil and isethionic acid, it has a very good foaming power.


Jordapon SCI is found in natural products such as solid shampoos.
Jordapon SCI gives an excellent skin feel while also possessing high foaming ability, being able to produce a rich, creamy and stable lather that will not dehydrate the skin.


Jordapon SCI is lightly scented, tending not to trigger fragrance allergies, as well as an effective moisturizer and conditioner
In hair care products, Jordapon SCI moisturizes, conditions, and softens hair, helping prevent frizz and tangling.
Jordapon SCI has emulsifying properties that increase viscosity as well as help water to cling to dirt and oil on skin and hair, so it can be easily washed away.


Jordapon SCI leaves skin and hair feeling hydrated and soft.
Jordapon SCI is perfect for adding to water-free products, as well as skin care, hair care and bath products including Shampoos, Shower Gels, Soap Bars, Personal Care Products and more.


Jordapon SCI Can Be Used In Many Different Products Including: Soap Bars, Shampoo Bars, Liquid Hand Soap, Shampoo, Baby Products, Shower Gel, Bath Bombs, Foaming Bath Butter, Bath Whip, Cream Soap, Bubble Bars, Makeup, Toiletries, Personal Hygiene Products, and Personal Care Products.
Jordapon SCI is produced by ethoxylation, which makes it an environmentally unfriendly ingredient.


Jordapon SCI is an anionic surfactant derived from coconut fatty acid and sustainable palm that are used in many cosmetic and personal care products.
In particular, Jordapon SCI is used in the preparation of skin cleansing products such as soaps and washes as well as in shampoos and other hair cleansing products.


By helping water to mix with oil and dirt, Jordapon SCI is great at rinsing dirt away from the skin and hair leaving both feeling fresh and clean.
Jordapon SCI is used in skin and hair cleansing preparations.


Jordapon SCI is used as this is a dry surfactant it can be blended into a dry formulation such as a dry shampoo, bath bomb, powdered facial cleanser or equivalent or can be added to the water phase of a standard, water based cleansing product (shampoo, shaving product, cleanser etc).


In hair care products, Jordapon SCI moisturizes, conditions, and softens hair, helping prevent frizz and tangling.
Jordapon SCI has emulsifying properties that increase viscosity as well as help water to cling to dirt and oil on skin and hair, so it can be easily washed away.


Jordapon SCI leaves skin and hair feeling hydrated and soft.
Jordapon SCI is perfect for adding to water-free products, as well as skin care, hair care and bath products including Shampoos, Shower Gels, Soap Bars, Personal Care Products and more.


Jordapon SCI Can Be Used In Many Different Products Including: Soap Bars, Shampoo Bars, Liquid Hand Soap, Shampoo, Baby Products, Shower Gel, Bath Bombs, Foaming Bath Butter, Bath Whip, Cream Soap, Bubble Bars, Makeup, Toiletries, Personal Hygiene Products, and Personal Care Products.
Mix with Jordapon SCI to other surfactants (anionic or nonionic) at a concentration of 1-10%.


Jordapon SCI is used for external use only.
Jordapon SCI is used in Shampoos, shower gels, detergent bars, bubble bath, feminine hygiene products, facial cleansers for blemished skin.
Jordapon SCI has long been used as a substitute for sodium salts obtained from animals, such as sheep and cattle.


A thin white powder is known as Jordapon SCI.
Jordapon SCI is used as a surfactant or co-surfactant (for cleansing properties and lather) in products such as shampoos, shampoo bars, body washes, and hand soaps.


Jordapon SCI's created by combining sodium isethionate with coconut oil fatty acids.
Jordapon SCI is a surfactant that cleans the skin.
In cosmetics and personal care products, Jordapon SCI is used primarily in the preparation of bath soaps and cleansing products.


Jordapon SCI is also used in the formulation of shampoos, tonics, dressings, other hair grooming aids and skin cleansing preparations.
Jordapon SCI cleans the skin and hair by helping water to mix with oil and dirt so that they can be rinsed away.
Jordapon SCI has high foaming capabilities which will not dry out your skin.


Jordapon SCI is very popular in water free products like solid shampoo bars and solid soap bars.
Jordapon SCI can be used in Shampoos, Bubble Bath products, Bath Bombs, Soap Bars and Body Wash Bases.
Jordapon SCI has been deemed safe by the Cosmetic Ingredient Review Expert Panel.


Their report surveyed products containing up to 49.4% in rinse-off formulas and 17% for leave-on products.
Its ultra-mild properties make Jordapon SCI ideal for delicate or sensitive skin, and it is often used as a plant-based alternative to animal-derived sodium salts.


Jordapon SCI has good water solubility and can be used as main surfactant or sub-surfactant in transparent formulation system.
The pH value of Jordapon SCI is between 4.5 and 6.5, which is weakly acidic, which is close to the pH value of the human body.
Jordapon SCI has high biodegradability, good compatibility, and can be compounded with most surfactants.


Jordapon SCI can be used as a main surfactant or sub-surfactant in a sulfate-free formulation system.
Jordapon SCI is widely used in personal washing and skin care products such as shower gel, shampoo, facial cleanser, hand soap, shaving foam, baby bath products, beauty soap and so on.


A gentle anionic surfactant that does not dehydrate the skin, Jordapon SCI is as a fantastic alternative to harsher, drying anionic surfactants making it great for all skin types, including sensitive or dry skin.
Makes superior hair shampoo for black hair leave the skin and hair feeling smooth and moisturized without stripping the skin/hair whatsoever.


Jordapon SCI has the characteristics of rich and fine foam, low degreasing power, low irritation to skin and hair, and good biodegradability.
Jordapon SCI can improve the combability and softness of the hair, and its mild decontamination performance makes the skin comfortable after washing.


Jordapon SCI is a mild anionic surfactant, and has fine, long-lasting and lasting foam performance, strong cleaning ability and fast foaming speed.


-Skin care uses of Jordapon SCI:
Jordapon SCI differs from other surfactants in the way that it does not strip the skin of moisture, making it feel dehydrated.
Instead, Jordapon SCI produces a rich foam that does not dry out or irritate the skin upon application


-Hair care uses of Jordapon SCI:
Jordapon SCI produces a rich creamy lather that makes the products easier to spread and feel good.
Jordapon SCI also cleanses the shafts thoroughly because of its ability to mix well with both oil and water


-Cosmetic products uses of Jordapon SCI:
Jordapon SCI reduces the surface tension of the ingredients in a formulation - allowing them to mix well.
This prevents the separation of oil based and water based ingredients and results in an even consistency of the cosmetic products



APPLICATIONS OF JORDAPON SCI IN COSMETİC PRODUCTS
Jordapon SCI is a mild surfactant for hair and skin. Upon contact with water, it creates a pleasant, thick foam.
In cleansing products, Jordapon SCI cleans and smoothens the skin without causing any irritation or dryness.
Jordapon SCI has a moisturizing, softening and smoothing effect on skin and hair.

Jordapon SCI also has emulsifying properties, giving cosmetic products a creamy texture and increasing their viscosity.
In hair care products, Jordapon SCI may decrease hair tangling and make it easier to comb.
Jordapon SCI may be used in mild cleansing products for persons with sensitive or allergy-prone skin.

Jordapon SCI dissolves dirt well, binding impurities and leaving the skin clean and moisturized.
Jordapon SCI retains its effectiveness in both soft and hard water, which makes it useful for a wider range of cosmetic applications. Thanks to its chemical structure, Jordapon SCI has many beneficial properties that make it delicate even for baby skin.

Therefore Jordapon SCI is a frequent ingredient of bathing products for children.
Jordapon SCI is biodegradable and causes no harm to the environment, so products with this ingredient are a recommended choice for any natural and ecological routine.



COSMETIC USES OF JORDAPON SCI:
Jordapon SCI is used in make-up removal and personal hygiene products, as well as plant-based cosmetics.
Applications of Jordapon SCI in cosmetics include:
*Shampoo bars,
*Cleansing bars,
*Peeling bars,
*Bath balls,
*Shampoos,
*Foam baths,
*Shaving gels and creams,
*Bathing products for children,
*Make-up removal milk.



JORDAPON SCI AT A GLANCE:
*Coconut-derived cleansing agent regarded as compatible with sensitive skin
*Known to mitigate disruption of skin’s barrier
*Produces gentle foaming action
*Deemed safe by the Cosmetic Ingredient Review Expert Panel



BENEFITS OF JORDAPON SCI:
*Jordapon SCI has excellent foam density, foam stability and lathering
*Jordapon SCI has very good lime soap dispersion and surface activity
*Jordapon SCI maintains the hydration level of skin
*Exceptionally mild, Jordapon SCI provides soft skin after-feel, ideal for irritant and blemished skin
*Jordapon SCI is compatible with soaps and anionic, non-ionic, and amphoteric surfactant
*Jordapon SCI can be used for transparent products including gels



WHAT DOES JORDAPON SCI DO IN A FORMULATION?
*Cleansing
*Surfactant



SAFETZ PROFILE OF JORDAPON SCI:
Jordapon SCI is safe for use when added under the prescribed concentrations.
Jordapon SCI is recommended to be used up to the concentrations of 50% in rinse off products and up to 17% for leave on products.
A patch test should be done prior to full usage and should be discontinued in case of any irritation.
Further, Jordapon SCI is non-comedogenic and does not cause acne breakouts.
Jordapon SCI is also biodegradable as it is derived from coconuts.



ALTERNATIVES OF JORDAPON SCI:
*SODIUM LAURYL SULFATE


HOW IS JORDAPON SCI MADE?
Jordapon SCI is produced by reacting sodium isethionate with fatty acids derived from coconut oil or other chlorides.
The mixture is then heated to remove water and distilled to remove excess fatty acids.



PROPERTIES OF JORDAPON SCI:
*Dense foam
*Solid foaming
*Anionic surfactant



BENEFITS OF JORDAPON SCI::
*Gentle on skin and eyes.
*Produces excellent foam in hard or soft water.
*Gives a feeling of softness to the skin.
*Nice smell.
*Completely biodegradable.
*High active content (82% minimum).



PREPATATION AND EXTRACTION OF JORDAPON SCI:
Presentation and extraction
Jordapon SCI can be prepared via the so-called “indirect route” by reacting higher carboxylic acid chlorides with sodium isethionate .
In industrial processes, Jordapon SCI is obtained via direct esterification of a coconut fatty acid mixture with sodium isethionate in the presence of catalysts.



SYNTHESIS OF JORDAPON SCI:
For this purpose, a coconut fatty acid mixture of different alkyl chain lengths Cn, typically C6 = 0.4% by weight; C8 = 7.6; C10 = 6.5; C12 = 47.7; C14 = 18.4; C16 = 8.9; C18 = 6.2; C18:1 = 3.7 in excess with sodium isethionate solution and zinc oxide under nitrogen at approx. 200 ° C.
After distilling off the water from the sodium isethionate solution and the water of reaction, a viscous mass is formed, which is liquefied again by adding paraffin wax.

After esterification with conversions >95%, stearic acid is added in order to lower the solidification point of the mixture below 50 °C.
When using branched fatty acids, the addition of paraffin as a consistency regulator is unnecessary and highly concentrated acyloxyethanesulfonates are obtained with high foaming properties, good hard water stability and also good water solubility (up to 30% at 20 °C).



PROPERTIES OF JORDAPON SCI:
Solid Jordapon SCI is available in flake, granule or powder form with approximately 85% active content (SCI-85).
There are also solid SCI-65 scales with around 30% fatty acid content.
Jordapon SCI is poorly soluble in water and is not long-term stable in solution at pH values ​​below 5 and above 8 due to its ester bond in the molecule.

Jordapon SCI is readily biodegradable with low affinity for bioaccumulation.
Jordapon SCI is slightly to moderately irritating to the skin and eyes.
Jordapon SCI exposure can cause minimal to mild skin irritation, although it is not skin sensitizing.



PROPERTIES OF JORDAPON SCI:
*mild to skin and eyes
*excellent foamers in hard or soft water
*impart a soft after feel to skin
*mild odor
*based upon fatty acids from natural, renewable coconut oil
completely biodegradable



COSMETIC INGREDIENTS FUNCTIONS OF JORDAPON SCI:
*Surfactant,
*Surfactant (Anionic)



BENEFITS OF JORDAPON SCI:
Jordapon SCI exhibits high foaming ability, producing a stable, rich and velvety lather that does not dehydrate the skin, making it ideal for addition to water-free products as well as skin care, hair care, and bath products.
This high-performance surfactant, Jordapon SCI, which is equally effective in both hard and soft water, is a popular choice for addition to liquid shampoos and bar shampoos, liquid soaps and bar soaps, bath butters and bath bombs, and to shower gels, to name a few foaming products.

This lightly-scented and conditioning cleansing agent, Jordapon SCI, is gentle enough for use on the delicate skin of babies, making it an ideal surfactant for makeup as well as personal care products and natural toiletries.
Its emulsifying property, which allows water and oil to mix, makes Jordapon SCI a popular ingredient in soaps and shampoos, as it encourages dirt to attach itself to them, which in turn makes it easier for it to be washed away.
Jordapon SCI's deluxe foaming capacity and conditioning effects leave the hair and skin feeling hydrated, soft, and silky-smoothe.



FEATURES AND BENEFITS OF JORDAPON SCI:
-Benefit Claims:
*Cleansing,
*High Foaming,
*Mild,
*Non-Irradiated,
*Silky Feel,
*Soft Feel

-Labeling Claims:
*Additive-free,
*Antioxidants-free,
*Clean at Sephora,
*Credo Clean Standard,
*GMO-free,
*Microplastics-free,
*Nanomaterials-free,
*Naturally Derived,
*Non-GMO,
*Not Tested on Animals,
*Preservative-free,
*Solvent-free,
*Ulta Beauty's Conscious Beauty



MARKETS OF JORDAPON SCI:
*HI&I Care,
*Personal Care


FUNCTIONS OF JORDAPON SCI:
*Anionic Surfactant



IN A NUTSHELL, JORDAPON SCI:
*Made from natural, renewable coconut oil
*Very mild to skin and eyes
*Jordapon SCI exhibits excellent foam and lather, performs well in hard water
*Jordapon SCI imparts a soft after-feel to skin or hair
*Great for solid cleansing bars, thus avoiding SLS and SLeS
*Jordapon SCI creates an opaque and creamy product when used with other surfactants in winter, but in our hot summers this effect can disappear
*Biodegradable



HIGH PURITY JORDAPON SCI PROVIDES:
+ High foaming performance,
+ Extreme mildness
+ Soft & silky skin after-feel characteristics
- Jordapon SCI is an excellent choice as a primary surfactant or secondary surfactant in liquid cleanser applications.
- Jordapon SCI is based upon fatty acids from natural, renewable coconut oil



MAIN BENEFITS OF JORDAPON SCI:
*Emollient,
*Cleansing
*Foaming Agent.



WHO SHOULD USE JORDAPON SCI:
All skin types are welcome to use it.


HOW OFTEN CAN YOU USE JORDAPON SCI?
Jordapon SCI's fine to apply every day, but it shouldn't be left on for more than a few minutes at a time, like other surfactants, to avoid irritation.


JORDAPON SCI WORKS WELL WİTH:
Jordapon SCI's compatible with a wide range of different surfactants.
To make a thicker mixture, Jordapon SCI's frequently used with natural polymers like xanthan gum and carrageenan gum.


JORDAPON SCI DOES NOT WORK WİTH:
Jordapon SCI has no known negative interactions with other substances.


HOW TO USE JORDAPON SCI:
Jordapon SCI is added to your formulation's water phase.



MECHANISMS OF ACTION OF JORDAPON SCI:
The inability of Jordapon SCI’s micelles to contribute to skin penetration was one of the reasons for its mildness.
The Jordapon SCI micelles were found to be significantly larger than the skin’s aqueous pores, implying that the SCI micelles are unlikely to enter the skin and cause more discomfort.

Surfactant, often known as a surface-active agent, Jordapon SCI is a detergent-like chemical.
When added to a liquid, Jordapon SCI lowers the surface tension, making it easier to spread and moisten.
Surfactants break down these interactions as they absorb.

Because the intermolecular interactions between the surfactant and the water molecule are substantially lower than those between two water molecules, surface tension is reduced.

Micelles occur when the concentration of surfactant is high.
The critical micelle concentration is the point at which micelles begin to form.
The primary function of surfactants is to reduce surface and interfacial tension while also stabilising the interface.



BENEFITS OF JORDAPON SCI:
Jordapon SCI has a strong foaming ability and produces a stable, rich, and velvety lather that does not dehydrate the skin, making it perfect for use in water-free products.
This high-performance surfactant, Jordapon SCI, is widely used in liquid shampoos and bar shampoos, liquid soaps and bar soaps, bath butters and bath bombs, and shower gels, to name a few foamy items.

This gently fragrant and conditioning washing agent is gentle enough for baby’s sensitive skin, making Jordapon SCI an excellent surfactant for makeup, personal care products, and natural toiletries.
Its emulsifying property, which allows water and oil to mix, makes Jordapon SCI a common ingredient in soaps and shampoos since it promotes dirt to adhere to them, making it simpler to remove.
Jordapon SCI's luxurious foaming capacity and conditioning properties leave hair and skin feeling moisturised, soft, and silky smooth.



IS JORDAPON SCI NATURAL?
Jordapon SCI cannot be considered natural.
Jordapon SCI is not known to naturally occur in plants, minerals, or animals.
While one part of Jordapon SCI's synthesis does come from coconut oil, the other half is derived from sodium bisulfate and ethylene oxide.



PROPERTIES OF JORDAPON SCI::
Jordapon SCI, is a substance naturally derived from coconut oil.
Jordapon SCI contains fatty acids and the sulfonic (isethionic acid).
To maintain its properties, Jordapon SCI requires proper storage conditions – in a cool place, away from light and heat.

Jordapon SCI is safe for external applications.
Jordapon SCI has been a subject of many research studies and has not been found to cause any significant adverse effects.
Jordapon SCI is considered safe for use in cosmetic formulations.

However, to make sure no allergic reaction occurs, a quick test may be conducted: Place a small amount of the product containing Jordapon SCI on your hand and wait for a moment, looking for any significant changes.
If no irritation develops, Jordapon SCI can be used as instructed.



STRENGTHS OF JORDAPON SCI:
Jordapon SCI is a wonderful, gentle lather.


WEAKNESSES OF JORDAPON SCI:
The larger shapes of Jordapon SCI can be a pain to melt down.
Jordapon SCI can hydrolyze if it’s in a hydrous (liquid) formulation with a pH below 6, causing formulations to become unstable.



ALTERNATIVES AND SUBSTITUTIONS OF JORDAPON SCI:
As a bare minimum you’ll need a different solid anionic surfactant.
You’ll also need to watch the active surfactant matter (you may need to use a different quantity of the new surfactant to get the same ASM level in the end product) and the pH of the final product.
Keep in mind that most solid anionic surfactants are not as gentle as Jordapon SCI.
Two options to consider would be SLSa and Sodium (C14-16) olefin sulfonate (Bio-Terge AS90).



DO YOU NEED JORDAPON SCI?
Jordapon SCI depends on what you want to make!
If you primarily want to make shampoo bars and other solid cleansing bars, I highly recommend Jordapon SCI.
If you are more interested in foaming bath products (bath salts, bath bombs, bath truffles, etc.), I’d probably choose Sodium Lauryl
Sulfoacetate (SLSa) over Jordapon SCI as it’s far more water soluble.
If your primary aim to create liquid surfactant products, I’d choose liquid surfactants and/or solid surfactants that are more water soluble (Sodium Coco Sulfate [SCS], Sodium Lauroyl Methyl Isethionate [SLMI]) than Jordapon SCI is.



SOLUBILITY OF JORDAPON SCI:
Jordapon SCI is water soluble, but not very enthusiastically.
Jordapon SCI's cousin, Sodium Lauroyl Methyl Isethionate (SLMI), is far more water soluble.



WHY DO WE USE JORDAPON SCI IN FORMULATIONS?
Jordapon SCI offers beautiful, gentle “lace glove” lather to our products.
Jordapon SCI’s also naturally acidic, so it helps our end products have a skin-friendly pH with less (or no) adjusting.



BENEFITS OF JORDAPON SCI:
*Good foam improver and stabilizer
*Very mild and non-drying
*Plant based
*Outstanding (sole) surfactant for bar soaps and syndets
*Easy to handle and formulate
*Packaging Description



BENEFITS OF JORDAPON SCI FOR SKIN:
Jordapon SCI offers benefits for nearly all skin types, particularly those with sensitive or dry skin types.
Some of these benefits include:

*Produces a silky lather:
Due to the fact that it's a surfactant, Jordapon SCI lowers the surface tension of the water, allowing the product to spread easier across the face.
In hair care products, Jordapon SCI gently cleanses hair while removing excess oil to reduce tangles and frizz, as well as allow the products to lather.

*Adding hydration and moisture:
According to Spinnato, Jordapon SCI exhibits a high foaming ability producing a stable, rich, and velvety lather that does not dehydrate the skin.
Instead of drying out the skin like other surfactants, Jordapon SCI'll leave your skin feeling hydrated and moisturized sans any irritation, redness, or dryness.

*Gently lifting away dirt, oil, and another build-up:
By bonding water and oil, Jordapon SCI has the ability to help get rid of any makeup residue, dirt, or grime that's been sitting on your face, body, or scalp all day.
This means that Jordapon SCI is an agent that helps remove the dirt and oils with the emulsification of the product.

*Preventing damage to the skin barrier:
Unlike other harsher surfactants, Jordapon SCI is kinder on the skin.
In return, explains Graf, Jordapon SCI cleanses the skin gently without damaging the moisture barrier or taking away any hydration.



SIDE EFFECTS OF JORDAPON SCI:
As of now, there are no known side effects associated with using Jordapon SCI.
However, if you have a coconut allergy, you should steer clear of the ingredient.
Since Jordapon SCI is derived from coconut oil, it should be avoided by anyone who has a coconut allergy.

Another thing to note:
If you overuse the ingredient, Jordapon SCI may be drying, particularly for those with natural or thicker textured hair types.
Jordapon SCI may strip the hair of its natural oils if you use it too often on dryer hair types, so make sure to proceed with caution.



HOW TO USE JORDAPON SCI:
Due to its gentle nature, Jordapon SCI can be used every single day.
For a body wash, opt to use Jordapon SCI twice a day.
If Jordapon SCI's a cleanser, you should only be using it two times a day at maximum.

Before using Jordapon SCI, make sure the bottle has no more than 50% SCI, advises Graf, as it can be drying.
Jordapon SCI arrives within shampoos, body washes, cleansers, and soap bars, so incorporating it into your routine is truly an effortless product that'll reap major rewards.



RECOMMENDED USAGE OF JORDAPON SCI:
Jordapon SCI is safe for regular use when formulated within the recommended concentrations for personal care products.
The Cosmetics Ingredient Review (CIR), an independent panel of expert scientists responsible for evaluating the safety of cosmetic ingredients, has established guidelines for the safe use of Jordapon SCI in various types of products.
Jordapon SCI can be used daily, but it is recommended to only be used twice on hair per day to maintain follicle health.



JORDAPON SCI HELPS TO:
*Lift and remove dirt
*Hydrate the hair and skin to protect against dryness
*Create rich, foaming lather
*Prevent frizz
*Increase product viscosity
*Moisturize, condition, and soften
*Reduce tangling
*Emulsify formulations and increase their viscosity, which contributes a creamier texture
*Lift and remove dirt
*Soothe skin
*Hydrate, condition, and soften the skin to reduce irritation, cracking, and peeling



TYPE OF INGREDIENT:
Surfactant


MAIN BENEFITS:
Jordapon SCI creates a rich lather, gently lifts away dirt and grime, and hydrates.


WHO SHOULD USE IT:
In general, Jordapon SCI's great for all skin types, particularly those with sensitive or dry skin since it's not as harsh as other surfactants.


HOW OFTEN CAN YOU USE IT:
Jordapon SCI can be used daily, but should be used twice at most for hair care, cleansing, and body products.


WORKS WELL WITH:
Emollients and humectants to help support the skin barrier.


DON'T USE WITH:
Other harsh surfactants or skin irritants to retain its maximum benefits.



JORDAPON SCI IS THE WORLD'S MOST COMMON SYNTHETİC SURFACTANT USED FOR BATH BOMBS, BODY CLEANSERS, SHAMPOOS, SOAPS, CONDITIONERS AND OTHER FOAMY AND BUBBLY PRODUCTS:
✅ Jordapon SCI has excellent properties regardless of pH and is not affected by water hardness when used as a detergent.
Jordapon SCI provides a very creamy and rich lather
✅ Anionic, foaming, sulphate-free, skin-friendly, biodegradable. Without additives, preservatives or colorantes surfactant

✅ Plant-based (coconut oil) and synthetic.
Esterified derivative of coconut oil fatty acids

✅ Jordapon SCI not only provides a consumer-perceivable smooth and moisturizing feeling but also is actually one of the mildest surfactants for skin.
Numerous studies have shown the high tolerance of skin for Jordapon SCI.

✅ Allows to formulate shampoos containing butters or oils for a nourishing and conditioning effect, without losing the washing and foaming power and without weighing down the hair.
Jordapon SCI used in combination with Sodium Coco Sulfate (SCS) to formulate solid shampoos that are soft and well tolerated by the scalp and hair, while providing a rich and creamy lather.
Jordapon SCI also makes it possible to prepare shower bars

✅ As Jordapon SCI has limited solubility in water it may recrystallise if used in a liquid shampoo.
✅ Jordapon SCI performs well in hard water areas and is biodegradable.
Jordapon SCI has a minimum of 83% active ingredient and a pH of 5.4 (35°C / 77°F) so formulae do not usually need pH adjusting

✅ No Preservatives
✅ No Antioxidants
✅ No Solvents



FUNCTIONS OF JORDAPON SCI:
*Cleansing :
Jordapon SCI helps to keep a clean surface
*Hair conditioning :
Jordapon SCI leaves hair easy to comb, soft, soft and shiny and / or confers volume, lightness and shine
*Surfactant :
Jordapon SCI reduces the surface tension of cosmetics and contributes to the even distribution of the product when it is used



PHYSICAL and CHEMICAL PROPERTIES of JORDAPON SCI:
Inci: Sodium Cocoyl Isethionate
Application: Anionic, Mild Surfactant
Appearance: White to off-white flakes or chips
CAS No.: 61789-32-0
InChIKeys: WYHCVLBWWXVCEM-UHFFFAOYSA-M
Molecular Weight: 1555.23182
Exact Mass: 288.100739
EC Number: 263-052-5
DSSTox ID: DTXSID6028070
PSA: 91.9
Appearance: White or of- white powder or crystlline power,odorless
Solubility: Very soluble in N,N-Dimethylformamide,
Soluble in methanol,Sparingly soluble inglacial acetic acid,
Very slightly soluble inchloroform, Practically insoluble in water.
Melting Point: 152°C~156°C
Melting Point: 191-194°C
pH: 6.0-8.0
Solubility: Soluble in water
INCI: Sodium Cocoyl Isethionate
CAS# 61789-32-0 / 61788-47-4
Physical Form: Solid Powder
Appearance: White to Off-White Powder
Odor: Characteristic
pH (35°C, 10% Solution): 4.0 – 6.0
Active Substance: min. 82%
Free Fatty Acids: max. 13.0%
Solubility: Water
Typical Usage Rates: 3 – 40% depending on formulation



FIRST AID MEASURES of JORDAPON SCI:
-First-aid measures general:
If you feel unwell, seek medical advice.
-First-aid measures after inhalation:
Assure fresh air breathing.
Allow the victim to rest.
-First-aid measures after skin contact:
Wash with plenty of water.
-First-aid measures after eye contact:
Rinse cautiously with water for several minutes.
Remove contact lenses, if present and easy to do.
Continue rinsing.
-First-aid measures after ingestion:
Rinse mouth.



ACCIDENTAL RELEASE MEASURES of JORDAPON SCI:
-Personal precautions, protective equipment and emergency procedures:
--For non-emergency personnel:
*Protective equipment:
Wear recommended personal protective equipment.
*Emergency procedures:
Ventilate area.
-Environmental precautions:
Prevent entry to sewers and public waters.
-Methods and material for containment and cleaning up:
*Methods for cleaning up:
On land, sweep or shovel into suitable containers.
Collect spillage.



FIRE FIGHTING MEASURES of JORDAPON SCI:
-Extinguishing media:
*Suitable extinguishing media:
Use CO2.
Dry powder or water mist extinguishers only
-Advice for firefighters:
*Firefighting instructions:
Evacuate area.



EXPOSURE CONTROLS/PERSONAL PROTECTION of JORDAPON SCI:
-Control parameters:
No additional information available
-Exposure controls:
*Hand protection:
Protective gloves
*Eye protection:
Chemical goggles or safety glasses
*Skin and body protection:
Wear suitable protective clothing
-Other information:
Do not eat, drink or smoke during use.



HANDLING and STORAGE of JORDAPON SCI:
-Conditions for safe storage, including any incompatibilities:
*Storage conditions:
Keep only in the original container in a cool, well ventilated place away from:
Keep container closed when not in use.



STABILITY and REACTIVITY of JORDAPON SCI:
-Reactivity:
No additional information available
-Chemical stability:
Stable under normal conditions



SYNONYMS:
jordapon SCI
Sodium Cocoyl Ethyl Ester Sulfonate
Fatty Acids, Coconut Oil, Sulfoethyl Esters, Sodium Salts
fatty acids coco 2-sulfoethyl esters sodium salts
fatty acids coconut oil sulfoethyl esters sodium salts
fatty acids, coco, 2-sulfoethyl esters, sodium salts
fatty acids, coconut oil, sulfoethyl esters, sodium salts
igepon AC-78
Fatty acids, coco, 2-sulfoethyl esters, sodium salts
coconut fatty acid 2-sulfoethyl ester sodium salt
coconut fatty acid, 2-sulfoethyl ester, sodium salt
Sodium cocoyl isethionate 85%
SODIUM 2-HYDROXYETHANE COFA SULFONATE
coconutfattyacid,2-sulfoethylester,sodiumsalt
DISODIUM MANGANESE EDTA CONTENT 12.5
Fattyacids,coco,2-sulfoethylesters,sodiumsalts
fattyacids,coconutoil,sulfoethylesters,sodiumsalts
jordaponci
sodiumcocoylisothionate


Juglans nigra
juglans nigra bark extract; extract of the bark of the black walnut, juglans nigra l., juglandaceae; black walnut bark extract CAS NO:96690-56-1
Juniperus communis
juniperus communis fruit extract; juniper berry extract; skin tonic aftershave CAS NO: 84603-69-0
K 100
Synonyms: Hexamethylenediamine Tetra (methylene Phosphonic acid) (K6);K6HMDTMP cas :38820-59-6
K6HMDTMP
Stearic acid calcium salt; Calcium octadecanoate; Octadecanoic acid, calcium salt; Calcium distearate; Calcium stearato (Italian); Calciumdistearat (German); Diestearato de calcio (Spanish); Distéarate de calcium (French) cas no: 1592-23-0
Kabak Çekirdek Ekstraktı
Cucurbita pepo seed extract ;extract from the seeds of the pumpkin, cucurbita pepo l., cucurbitaceae; pumpkin seed extract cas no:89998-03-8
KAFEİN
SYNONYMS 1,3,7-TRIMETHYL-2,6-DIOXOPURINE;1,3,7-Trimethylxanthine;1H-Purine-2,6-dione, 3,7-dihydro-1,3,7-trimethyl-;3,7-Dihydro-1,3,7-trimethyl-1H-purine-2,6-dione;7-Methyltheophylline;Alert-Pep;cafeina;Cafeina;Cafeine;Caffedrine;Caffein;caffeine;Caffeine Methyltheophylline;CAFFEINE, ANHYDROUS CAS NO:58-08-2
KAFUR
CAMPHOR OIL; camphor oil; camphor oil white; camphor oil white distilled; cinnamomum camphora formosana bark oil CAS NO:8008-51-3
Kafur Yağı
CAMPHOR OIL; camphor oil; camphor oil white; camphor oil white distilled; cinnamomum camphora formosana bark oil CAS NO:8008-51-3
KAHVE AROMASI
coffee flavor ; coffee essence flavor; natural coffee flavor; coffee, artificial; coffeetone natural
Kahve Ekstrakt
Coffea Arabica Seed Extract ;extract of the beans of the coffee plant, coffea arabica l., rubiaceae; actipone black coffee; coffee bean extract ; coffee extractive cas no:84650-00-0
KAKAO AROMASI
cocoa flavor; cocoa - maillard reaction; cocoa flavor (dark); cocoa-nut flavor; cocoal reaction flavor nat
Kakao Ekstrakt
Theobroma Cacao Extract ;THEOBROMA CACAO SEED BUTTER; cacao butter; cacao absolute; theobroma cacao extract; extract of the bark and seeds of the cocoa, theobroma cacao l., sterculiaceae; cacao bean extract; cacao butter extract; cacao extract; cacao extract 55% polyphenols; cocoa alcoholate 62; cocoa clear liposoluble; cocoa extract; premium cocoa extract; cocoa extract 25 fold; cocoa extract dark natural; cocoa extract natural; cocoa extract natural organic; cocoa extract on PG - reinforced; dark cocoa extract WONF; cocoa extractive; cocoa fluid extract CAS NO: 84649-99-0
Kakule Yağı
CARDAMOM OIL ; elettaria cardamomum seed oil; cardamom seed oil; amomum cardamomum seed oil; cardamom green oil; cardamom oil indian; elletaria cardamomum maton CAS NO:8000-66-6
KALAY (SN
Tin element cas no: 7440-31-5
KALSIYUM HIDROKSIT
SYNONYMS calcium dihydroxide;Calcium hydrate;Calcium hydroxide;Calcium hydroxide (Ca(OH)2);Calciumdihydroxid;CALCIUMHYDROXID CAS NO:1305-62-0
KALSIYUM STEARAT
KAOLIN; Aluminum Silicate; Silicic acid, aluminum salt; Aluminosilicic acid; Kieselsäure, Aluminiumsalz (German); ácido silícico, sal de aluminio (Spanish); Acide silicique, sel d'aluminium (French); China clay; Kaolinite; Kaopectate; Porcelain clay; cas no: 1332-58-7
KALSİYUM (CA)
calcium powder; calcium, elemental ;calcium element cas no:7440-70-2
Kalsiyum askorbat
SYNONYMS ASCORBIC ACID CALCIUM SALT;CALCIUM ASCORBATE;calci-c;calcium diascorbate;L-Ascorbic acid, calcium salt (2:1);Calciumdiascorbat;XKHKUSZPZXOECF-JDYVBSGKSA-N;Calcium Ascorbate Granular CAS NO:5743-27-1
Kalsiyum glukonat
SYNONYMS Calcium D-gluconate;calcium gluconate;Calcium hexagluconate;Calciumgluconat;Calglucol;Calglucon;D-Gluconic acid calcium salt (2:1);D-Gluconic acid, calcium salt (2:1) CAS NO:299-28-5
KALSİYUM KARBOKSİ METİL SELULOZ
SYNONYMS CM-Cellulose sodium salt;Cellulose glycolic acid, sodium salt; Cellulose sodium glycolate; Cellulose, carboxymethyl ether, sodium salt; Sodium carboxmethylcellulose; CAS NO:9004-32-4
Kalsiyum karbonat
SYNONYMSCalwhite;Duramite;Hydrocarb;Kotamite;Microcarb;CALCIUM CARBONATE;Calcite;Carbonic acid calcium salt (1:1);Calcium carbonate (1:1) CAS NO:471-34-1
Kalsiyum laktat
SYNONYMS calcium dilactate;Calcium DL-lactate;Calcium lactate;Calciumdilactat;CALCIUMLACTAT;Calphosan;Conclyte Ca;Dilactate de calcium;dilactato de calcio;E 327;LACTATE, CALCIUM CAS NO:814-80-2
Kalsiyum Propiyonat
SYNONYMS Propionic acid calcium salt;CALCIUM PROPIONATE FOOD GRADE ;CALCIUM PROPIONATE 95% CAS NO:4075-81-1
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