DI-C12-15 ALKYL FUMARATE, Nom INCI : DI-C12-15 ALKYL FUMARATE Ses fonctions (INCI) Emollient : Adoucit et assouplit la peau Solvant : Dissout d'autres substances

DICALCIUM PHOSPHATE, N° CAS : 7757-93-9, Nom INCI : DICALCIUM PHOSPHATE, Nom chimique : Calcium hydrogenorthophosphate, N° EINECS/ELINCS : 231-826-1, Ses fonctions (INCI) : Agent Abrasif : Enlève les matières présentes en surface du corps, aide à nettoyer les dents et améliore la brillance.Agent de foisonnement : Réduit la densité apparente des cosmétiques. Opacifiant : Réduit la transparence ou la translucidité des cosmétiques. Agent d'hygiène buccale : Fournit des effets cosmétiques à la cavité buccale (nettoyage, désodorisation et protection)

CALCII HYDROGENOPHOSPHAS DIHYDRICUS; CALCIUM HYDROGEN PHOSPHATE; CALCIUM HYDROGEN PHOSPHATE-2-HYDRATE; CALCIUM HYDROGENPHOSPHATE DIHYDRATE; CALCIUM MONOHYDROGEN PHOSPHATE DIHYDRATE; CALCIUM PHOSPHATE, DIBASIC; CALCIUM PHOSPHATE DIBASIC, DIHYDRATE; CALCIUM PHOSPHATE DIHYDRATE, DIBASIC; DICALCIUM PHOSPHATE DIHYDRATE; PHOSPHORIC ACID CALCIUM SALT, DIHYDRATE; Calciumhydrogenphosphate,dih; Calciumhydrogenphosphate,medicinal; Phosphoricacid,calciumsalt(1:1),dihydrate; DICALCIUM PHOSPHAT; CALCIUM HYDROGEN PHOSPHATE-2-HYDRATEEXTRA PURE, DAB, PH.; CALCIUM PHOSPHATE DIBASIC DIHYDRATE PH EUR; CALCIUM HYDROGENPHOSPHATE DIHYDRATE 98%; CalciumPhosphateDibasicDihydrateUsp; Dicalciumphosphate,precipitate; Calciumhydrogenphosphatedihyrdate,98%min CAS NO:7789-77-7

DICALCIUM PHOSPHATE DIHYDRATE, N° CAS : 7757-93-9 / 7789-77-7, Nom INCI : DICALCIUM PHOSPHATE DIHYDRATE, Nom chimique : Calcium hydrogenorthophosphate, N° EINECS/ELINCS : 231-826-1, Ses fonctions (INCI). Agent Abrasif : Enlève les matières présentes en surface du corps, aide à nettoyer les dents et améliore la brillance.Opacifiant : Réduit la transparence ou la translucidité des cosmétiques. Agent d'hygiène buccale : Fournit des effets cosmétiques à la cavité buccale (nettoyage, désodorisation et protection)

Dioctylcarbonat; Dioctyl carbonate; DICAPRYLYL CARBONATE; Dicaprylyl Carbonate 99%; Carbonic acid, dioctyl ester; UNII-609A3V1SUA; 609A3V1SUA; dicaprylyl carbonat; di-1-octyl carbonate; carbonic acid dioctyl ester CAS NO:1680-31-5

Carbonic acid,dioctyl ester; Di-n-octyl-carbonate; Kohlensaeure-di-n-octylester; Dioctyl carbonate; octyl carbonate; Dioctylcarbonat; cas no: 1680-31-5

DICAPRYLYL ETHER, N° CAS : 629-82-3, Nom INCI : DICAPRYLYL ETHER, Nom chimique : Dioctyl ether, N° EINECS/ELINCS : 211-112-6, Classification : Huile estérifiée. Emollient : Adoucit et assouplit la peau. Agent d'entretien de la peau : Maintient la peau en bon état. Solvant : Dissout d'autres substances. 1-(Octyloxy)octan [German] 1-(Octyloxy)octane 1-(Octyloxy)octane [French] 1,1'-Oxybisoctane 1748226 211-112-6 [EINECS] 629-82-3 [RN] 8O8 [WLN] Caprylic ether Dicaprylyl ether Di-n-octyl ether Dioctyl ether Ether, di-n-octyl- MFCD00009563 n-Dioctyl ether Octane, 1,1'-oxybis- [ACD/Index Name] Octyl ether RH8800000 [629-82-3] 1-octoxyoctane Antar [Wiki] Cetiol OE dicapryl ether Di-n-Octylether dioctylether EINECS 211-112-6 n-Octyl Ether n-Octylether Octane, 1,1'-oxybis-, octyloxyoctane TL8004344

Dicaprylyl maleate Dicaprylyl maleate is classified as : Emollient Skin conditioning Solvent CAS Number 2915-53-9 EINECS/ELINCS No: 220-835-6 COSING REF No: 75673 Chem/IUPAC Name: Dioctyl maleate Dicaprylyl maleate (DCM) has been reported rarely as a cause of allergic contact dermatitis. The objectives of this study were to identify patients from multiple centres with allergy to Dicaprylyl maleate in cosmetic products confirmed by patch testing and, in addition, to investigate the effect of testing with aged DCM. This is an international multicentre study of 22 patients with 26 reactions to products containing DCM. Patch testing was carried out to ingredients including Dicaprylyl maleate obtained from the manufacturer. Further testing was carried out with deliberately aged Dicaprylyl maleate in a sample of patients. 22 patients had clinical and positive patch test reactions at 4 days to a total of 26 cosmetic products containing DCM. 5 patients did not react to Dicaprylyl maleate prepared by the manufacturer from concurrent factory stock but did have positive reactions to a deliberately aged batch of Dicaprylyl maleate . Dicaprylyl maleate is an emerging cosmetic allergen. Testing with aged material yields a greater number of positive results. Co-operation between cosmetics manufacturers and clinicians is important in the identification of new allergens. Molecular Weight of Dicaprylyl maleate 340.5 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) XLogP3-AA of Dicaprylyl maleate 7 Computed by XLogP3 3.0 (PubChem release 2019.06.18) Hydrogen Bond Donor Count of Dicaprylyl maleate 0 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Hydrogen Bond Acceptor Count of Dicaprylyl maleate 4 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Rotatable Bond Count of Dicaprylyl maleate 18 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Exact Mass of Dicaprylyl maleate 340.26136 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Monoisotopic Mass of Dicaprylyl maleate 340.26136 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Topological Polar Surface Area of Dicaprylyl maleate 52.6 Ų Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Heavy Atom Count of Dicaprylyl maleate 24 Computed by PubChem Formal Charge of Dicaprylyl maleate 0 Computed by PubChem Complexity of Dicaprylyl maleate 305 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Isotope Atom Count of Dicaprylyl maleate 0 Computed by PubChem Defined Atom Stereocenter Count of Dicaprylyl maleate 0 Computed by PubChem Undefined Atom Stereocenter Count of Dicaprylyl maleate 0 Computed by PubChem Defined Bond Stereocenter Count of Dicaprylyl maleate 1 Computed by PubChem Undefined Bond Stereocenter Count of Dicaprylyl maleate 0 Computed by PubChem Covalently-Bonded Unit Count of Dicaprylyl maleate 1 Computed by PubChem Compound of Dicaprylyl maleate Is Canonicalized Yes Dicaprylyl maleate (DCM) has been reported rarely as a cause of allergic contact dermatitis. The objectives of this study were to identify patients from multiple centres with allergy to Dicaprylyl maleate in cosmetic products confirmed by patch testing and, in addition, to investigate the effect of testing with aged DCM. This is an international multicentre study of 22 patients with 26 reactions to products containing DCM. Patch testing was carried out to ingredients including Dicaprylyl maleate obtained from the manufacturer. Further testing was carried out with deliberately aged Dicaprylyl maleate in a sample of patients. 22 patients had clinical and positive patch test reactions at 4 days to a total of 26 cosmetic products containing DCM. 5 patients did not react to Dicaprylyl maleate prepared by the manufacturer from concurrent factory stock but did have positive reactions to a deliberately aged batch of Dicaprylyl maleate . Dicaprylyl maleate is an emerging cosmetic allergen. Testing with aged material yields a greater number of positive results. Co-operation between cosmetics manufacturers and clinicians is important in the identification of new allergens. NCI name: Dicaprylyl maleate Alternative names: Bernel EsterDom, Dicaprylylmaleat Origin: Different Definition:Dioctyl maleate INCI function:Emollient, Solvent CAS-No.2915-53-9 EINECS/EILINCS-No.220-835-6 Dicaprylyl maleate is an intermediate used in several chemical production processes. Dicaprylyl maleate is also used in coating applications, and as a phthalate-free alternative to common phthalate-based plasticizers such as Dicaprylyl maleate . Dicaprylyl maleate (DCM) Dicaprylyl maleate is a clear, virtually colorless liquid with an ester-like odor.Dicaprylyl maleate can be used in organic synthesis, e.g. in the production of derivatives of succinic acid. Dicaprylyl maleate is also used as a comonomer in vinyl and acrylic emulsion polymerization for paints and adhesives. Under the action of heat and in the presence of acids or bases, Dicaprylyl maleate transposes into the corresponding fumaric-acid dialkyl ester. Dicaprylyl maleate (DCM) CAS# 142-16-5 DOWNLOAD SPECSREQUEST QUOTE PROPERTY Appearance Color Ester Content Specific Gravity Moisture UNIT APHA % % SPECIFICATION Clear 50 Maximum 98.5 Minimum 0.939-0.945 0.20 Maximum APPLICATION Dicaprylyl maleate is a maleic acid that can act as a plasticizer and is used in resins to provide elasticity and flexibility. Dicaprylyl maleate is a co-monomer which can be polymerized with vinyl acetate, vinyl chloride (PVC), acrylates as well as stearates. These types of polymerizations with Dicaprylyl maleate can be used in the production of adhesives, emulsion paints, surfactants, textile coatings and wetting agents. GRADES AVAILABLE Technical SYNONYMS Bis(2-ethylhexyl) maleate, di(2-ethylhexyl) maleate (DEHM), Maleic Acid Di(2-ethylhexyl) Ester, Maleic Acid Dioctyl Ester

DICETYLDIMONIUM CHLORIDE, N° CAS : 1812-53-9, Nom INCI : DICETYLDIMONIUM CHLORIDE, Nom chimique : Dihexadecyldimethylammonium chloride, N° EINECS/ELINCS : 217-325-0, Classification : Ammonium quaternaire. Ses fonctions (INCI): Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance. Tensioactif : Réduit la tension superficielle des cosm��tiques et contribue à la répartition uniforme du produit lors de son utilisation

DICHLOROBENZYL ALCOHOL, N° CAS : 1777-82-8, Nom INCI : DICHLOROBENZYL ALCOHOL, Nom chimique : 2,4-Dichlorobenzyl alcohol, N° EINECS/ELINCS : 217-210-5, Classification : Règlementé, Alcool, Conservateur. Ses fonctions (INCI): Antimicrobien : Aide à ralentir la croissance de micro-organismes sur la peau et s'oppose au développement des microbes. Conservateur : Inhibe le développement des micro-organismes dans les produits cosmétiqu

SYNONYMS Diclosan; Soneclosan; Tinopal HP 100; Tinosan HP 100; p-Chlorophenyl 2-hydroxy-4-chlorophenyl ether CAS NO:3380-30-1

Cyanoguanidine; 1-Cyanoguanidine; Dicyandiamide; Dicy; DCD; N-Cyanoguanidine; Dicyandiamin; Cyanguanidin; Cianoguanidina; Cyanoguanidine; 2-Cyanoguanidine; Araldite XB; 1-CYANOGUANIDINE; 2-Cyanoguanidine; AKOS NCG-0013; CYANOGUANIDINE; DCD; DICY; DICYANDIAMIDE; DICYANODIAMIDE; DYHARD(R) 100; DYHARD(R) 100 S; DYHARD(R) 100 SF; DYHARD(R) 100 SH; DYHARD(R) G 03; DYHARD(R) T 03 CAS NO:461-58-5

Dicorantil представляет собой органоаммонийфосфат.
Dicorantil принадлежит к группе лекарств, называемых антиаритмическими средствами, которые используются для лечения нерегулярного сердцебиения.
Dicorantil выпускается как в пероральной, так и в внутривенной формах и имеет низкую степень токсичности.

Номер КАС: 3737-09-5
Формула: C21H29N3O
Молярная масса: 339,483 г·моль-1

Dicorantil является антиаритмическим химическим веществом, используемым для лечения желудочковой тахикардии.
Dicorantil блокирует натриевые каналы и относится к антиаритмическим средствам класса 1а.

Dicorantil оказывает отрицательное инотропное действие на миокард желудочков и значительно снижает сократительную способность.
Dicorantil также оказывает антихолинергическое действие на сердце, что является причиной многих негативных побочных эффектов.
Dicorantil выпускается как в пероральной, так и в внутривенной формах и имеет низкую степень токсичности.

Dicorantil зарегистрирован в соответствии с Регламентом REACH и производится и/или импортируется в Европейскую экономическую зону только для промежуточного использования.
Dicorantil используется на промышленных объектах и в производстве.

Dicorantil представляет собой органоаммонийфосфат.

Dicorantil является антиаритмическим средством класса Ia с кардиодепрессантными свойствами.
Dicorantil оказывает действие Dicorantilа, блокируя как натриевые, так и калиевые каналы в сердечной мембране во время нулевой фазы потенциала действия.

Это замедляет проведение импульса через АВ-узел и удлиняет продолжительность потенциала действия нормальных клеток сердца в тканях предсердий и желудочков.
Dicorantil удлиняет интервал QT и вызывает расширение комплекса QRS.

Dicorantil также обладает некоторыми антихолинергическими и местноанестезирующими свойствами.
Dicorantil применяют для лечения суправентрикулярной тахикардии.

Антиаритмический агент класса I (тот, который непосредственно препятствует деполяризации сердечной мембраны и, таким образом, служит мембраностабилизирующим агентом) с угнетающим действием на сердце, подобным действию гуанидина.
Dicorantil также обладает некоторыми антихолинергическими и местноанестезирующими свойствами.

Dicorantil принадлежит к группе лекарств, называемых антиаритмическими средствами, которые используются для лечения нерегулярного сердцебиения.
Нерегулярное сердцебиение — это состояние, при котором ваше сердце бьется нерегулярно, слишком быстро или слишком медленно.
Dicorantil помогает замедлить частоту сердечных сокращений и предотвратить аритмии (аномальные сердечные ритмы).

Dicorantil сульфат содержит Dicorantil, т.е. антиаритмические средства.
Dicorantil помогает привести нерегулярные сердечные сокращения к нормальному ритму, блокируя определенные электрические сигналы в сердце.
Лечение нерегулярного сердцебиения снижает риск образования тромбов, сердечного приступа или инсульта.

Dicorantil следует принимать по назначению врача.
Ваш врач может контролировать ЭКГ и артериальное давление во время лечения, чтобы контролировать дозу.

Некоторые люди могут испытывать общие побочные эффекты, такие как нечеткость или двоение в глазах, боль в животе, малое мочеиспускание или его отсутствие, а также низкий уровень сахара в крови.
Большинство из этих побочных эффектов Dicorantilа не требуют медицинской помощи и со временем будут постепенно улучшаться.
Однако, если побочные эффекты сохраняются, обратитесь к врачу.

Пожалуйста, сообщите своему врачу, если у вас аллергия на Dicorantil или какие-либо другие лекарства.
Dicorantil не рекомендуется применять у детей.
Беременным или кормящим женщинам рекомендуется проконсультироваться с врачом, прежде чем принимать Dicorantil.

Прежде чем принимать Dicorantil, сообщите своему врачу, если у вас есть заболевания почек или печени, увеличенная простата, глаукома (повышенное внутриглазное давление) или низкий уровень калия в крови (гипокалиемия).
Не принимайте Dicorantil, если вы уже принимаете другие лекарства для регуляции сердцебиения.

Не садитесь за руль и не работайте с механизмами, так как Dicorantil может вызвать нечеткость зрения, головокружение и снижение артериального давления.
Используйте Dicorantil с осторожностью, если вы пожилой человек (старше 65 лет), имеете низкую массу тела или проблемы с почками или печенью.

Dicorantil используется для лечения некоторых нерегулярных сердечных сокращений).
Dicorantil относится к классу препаратов, называемых антиаритмическими препаратами.
Dicorantil работает, делая ваше сердце более устойчивым к аномальной активности.

Непрерывное образование:
Dicorantil — это химическое вещество, используемое для лечения нарушений сердечного ритма, которые могут быть опасными для жизни, такими как желудочковая тахикардия/фибрилляция, или связаны с повышенной заболеваемостью и смертностью, такими как мерцательная аритмия и гипертрофическая кардиомиопатия.
В этом мероприятии рассматриваются несколько важных аспектов этого химического вещества, включая показания, механизм действия, применение, побочные эффекты, противопоказания, мониторинг и токсичность.
Эти важные знания об этом химическом веществе могут улучшить результаты межпрофессиональной медицинской бригады.

Цели:
Опишите механизм действия Dicorantilа.
Опишите возможные побочные эффекты Dicorantilа.

Объясняет важность мониторинга при использовании Dicorantilа в качестве антиаритмического химического вещества.
Наметьте стратегии профессиональной команды для улучшения координации ухода и коммуникации при использовании Dicorantilа, чтобы максимизировать преимущества этого химического вещества и минимизировать побочные эффекты Dicorantilа.

Показания:
В 1962 году потребовались новые антиаритмические препараты помимо хинидина и новокаинамида, которые были основными антиаритмическими средствами, доступными в то время.
Dicorantil является выбранным из более чем 500 соединений, синтезированных для программы исследований новых антиаритмических средств.
Химическая структура Dicorantilа аналогична синтетическому мускариновому антагонисту лака, что объясняет антихолинергические свойства Dicorantilа.

Хотя Dicorantil редко используется при нарушениях сердечного ритма из-за наличия более новых препаратов, которые обеспечивают лучшую эффективность и благоприятные профили побочных эффектов, Dicorantil по-прежнему является препаратом выбора для лечения вагус-опосредованной фибрилляции предсердий, такой как вызванная сном или мерцательная аритмия у спортсменов. группы.
Эффективность Dicorantilа при этих состояниях обусловлена антихолинергической активностью Dicorantilа, котор��й упраздняет парасимпатический тонус.

Dicorantil также является антиаритмическим средством третьей линии для пациентов с ишемической болезнью сердца.
Кроме того, у пациента с гипертрофией левого желудочка нарушена деполяризация, что может вызвать пируэтную желудочковую тахикардию.

Таким образом, антиаритмические средства, удлиняющие интервал QT, избегают, но если соталол или амиодарон неэффективны или не подходят, альтернативой может быть Dicorantil.
У пациентов с мерцательной аритмией и гипертрофической обструктивной кардиомиопатией (ГОКМ) Dicorantil является препаратом выбора, кроме амиодарона, поскольку Dicorantil может снижать градиент выходного тракта левого желудочка (ЛЖВ) (использование не по назначению).

Данные многоцентрового исследования безопасности и эффективности Dicorantilа при обструктивной кардиомиопатии показали, что Dicorantil достоверно снижал градиент СВОТ с 75+/-33 до 40+/-32 мм рт.ст. у 78 пациентов (66% участников исследования) (P<0,0001). ). показал. ) и повышает функциональный класс Нью-Йоркской кардиологической ассоциации (NYHA FC) с 23+/-07 до 17+/-06 (P<0,0001).
Когда Dicorantil используется в комбинации с недигидропиридиновыми блокаторами кальциевых каналов или бета-блокаторами, они могут эффективно предотвращать рецидивы ФП у пациентов с HCOM.

Пациенты с желудочковой экстрасистолией (ЖЭ) или преждевременными желудочковыми комплексами (ЖЭК) могут иметь большое количество симптомов.
Dicorantil можно применять у пациентов без структурных заболеваний сердца, хотя эффективность Dicorantilа ниже, чем при аблации.
Кроме того, по данным рандомизированного двойного слепого плацебо-контролируемого исследования в течение года, Dicorantil (n=44) был эффективен в поддержании синусового ритма после электрокардиоверсии по поводу фибрилляции предсердий по сравнению с плацебо (n=46) и значительно отличался (%) при последующем наблюдении в течение одного месяца. 70 против 39%) и продолжается через двенадцать месяцев (54% против 30%).

Применение Dicorantilа:
Dicorantil используется для лечения определенных типов серьезных (возможно, фатальных) нерегулярных сердечных сокращений (таких как устойчивая желудочковая тахикардия).
Dicorantil используется для восстановления нормального сердечного ритма и поддержания регулярного, устойчивого сердцебиения.

Dicorantil известен как антиаритмический препарат.
Dicorantil работает, блокируя определенные электрические сигналы в сердце, которые могут вызвать нерегулярное сердцебиение.
Лечение нерегулярного сердцебиения может снизить риск образования тромбов, и этот эффект может снизить риск сердечного приступа или инсульта.

Применение Dicorantilа:
Dicorantil выпускается в виде капсул и капсул с пролонгированным высвобождением (длительного действия) для приема внутрь.
Капсулы Dicorantil можно принимать каждые 6 или 8 часов.

Капсулы пролонгированного действия обычно принимают каждые 12 часов.
Внимательно следуйте указаниям на этикетке с рецептом и попросите своего врача или фармацевта объяснить любую часть, которую вы не понимаете.

Принимайте Dicorantil точно так, как указано.
Не принимайте большее или меньшее количество Dicorantilа и не принимайте его чаще, чем предписано врачом.

Проглотите капсулы с пролонгированным высвобождением; не открывать, раздавить или жевать их.

Dicorantil помогает контролировать ваше состояние, но не лечит его.
Продолжайте принимать Dicorantil, даже если вы чувствуете себя хорошо.
Не прекращайте прием Dicorantilа, не посоветовавшись с врачом.

Механизм действия Dicorantilа:
Активность Dicorantilа класса 1а аналогична активности хинидина в том смысле, что Dicorantil нацелен на натриевые каналы для подавления проводимости.
Dicorantil угнетает увеличение натриевой проницаемости сердечного миоцита во время фазы 0 сердечного потенциала действия, в свою очередь уменьшая направленный внутрь поток натрия.

Это приводит к повышению порога возбуждения и снижению скорости движения вверх.
Dicorantil удлиняет интервал PR, увеличивая продолжительность как QRS, так и зубца P.

Этот эффект особенно хорошо подходит для лечения желудочковой тахикардии, поскольку Dicorantil замедляет распространение потенциала действия через предсердия к желудочкам.
Dicorantil не действует как блокатор бета- или альфа-адренорецепторов, но оказывает значительное отрицательное инотропное действие на желудочковый миокард.
В результате применение Dicorantilа может снизить сократительную способность до 42 % при низких дозах и до 100 % при более высоких дозах по сравнению с хинидином.

Левитс предложил возможный вторичный механизм действия Dicorantilа против реципрокных аритмий после ишемического инсульта.
Dicorantil уменьшает неоднородность между инфарктным и нормальным рефрактерными периодами миокарда; кроме удлинения рефрактерного периода.

Это снижает вероятность повторной деполяризации, поскольку сигналы с большей вероятностью встречаются с тканью в рефрактерном состоянии, которая не может быть возбуждена.
Это обеспечивает возможное лечение фибрилляции предсердий и желудочков, поскольку Dicorantil восстанавливает контроль кардиостимулятора над тканью СА и АВ-узлов.

Фармакология и биохимия Dicorantilа:

Фармакологическая классификация MeSH:

Антиаритмические агенты:
Агенты, используемые для лечения или профилактики сердечных аритмий.
Они могут влиять на фазу поляризации-реполяризации потенциала действия, Dicorantilовую возбудимость или рефрактерность, проводимость импульса или чувствительность мембран в сердечных волокнах.
Антиаритмические средства часто делят на четыре основные группы в зависимости от их механизма действия: блокада натриевых каналов, блокада бета-адренергических каналов, пролонгация реполяризации или блокада кальциевых каналов.

Обструктивная гипертрофическая кардиомиопатия:
Гипертрофическая кардиомиопатия (ГКМП) является наиболее распространенным наследственным заболеванием сердца, встречающимся у 1:500 человек в общей популяции.
Dicorantil оценивается в 600 000 человек в Соединенных Штатах с гипертрофической кардиомиопатией.

Наиболее распространенный вариант ГКМП проявляется внутриполостной обструкцией левого желудочка (ЛЖ) из-за систолического движения митрального клапана вперед и митрально-септального контакта, что легко диагностируется с помощью эхокардиографии.
Фармакологическое лечение препаратами с отрицательным инотропным действием является терапией первой линии.

Бета-блокаторы используются в первую очередь, и хотя они улучшают симптомы одышки, боли в груди и непереносимости физической нагрузки, они не снижают градиенты внутрижелудочкового давления в покое и часто неадекватны для контроля симптомов.
Многие исследователи и клиницисты считают, что Dicorantil с контролируемым высвобождением является наиболее мощным доступным средством для снижения градиентов давления в покое и улучшения симптомов.

Dicorantil активно применяется уже более 30 лет.
Применение Dicorantilа при обструктивной ГКМП имеет рекомендацию IB в рекомендациях Американской кардиологической ассоциации/Американского колледжа кардиологов от 2020 г. по лечению обструктивной ГКМП.
Рекомендация по лечению ИБ указывает на то, что лечение рекомендуется и может быть полезным и выгодным.

Отрицательные инотропы улучшают обструкцию ЛЖ, уменьшая ускорение выброса ЛЖ и гидродинамические силы на митральном клапане.
Особая эффективность Dicorantilа обусловлена сильным отрицательным инотропным действием Dicorantilа; при прямом сравнении Dicorantil более эффективен для снижения градиента, чем бета-блокатор или верапамил.

Dicorantil чаще всего вводят вместе с бета-блокаторами.
При использовании у пациентов, резистентных к бета-блокаторам, Dicorantil эффективен в 60% случаев, уменьшая симптомы и их градиент до такой степени, что не требуются инвазивные процедуры, такие как хирургическая септальная миэктомия.

Dicorantil, несмотря на эффективность Dicorantilа, имеет один основной побочный эффект, который ограничивает использование Dicorantilа в США, хотя Dicorantil нашел более широкое применение в Канаде, Великобритании и Японии.
Блокада блуждающего нерва предсказуемо вызывает сухость во рту, а у мужчин с простатитом может вызывать задержку мочи.
Тейхман и др. показали, что пиридостигмин, используемый в комбинации с Dicorantilом, значительно уменьшает ваголитические побочные эффекты без снижения антиаритмической эффективности.

Также было показано, что эта комбинация эффективна и безопасна при обструктивной ГКМП у большой когорты пациентов.
Некоторые клиницисты назначают пиридостигмин замедленного высвобождения (продаваемый в США как Местинон Таймспан) каждому пациенту, начавшему принимать Dicorantil.
Эта комбинация повышает приемлемость более высоких доз Dicorantilа, что важно, поскольку существует корреляция доза-реакция при обструктивной ГКМП, более высокие дозы дают более низкие градиенты.

Другая проблема, связанная с Dicorantilом, связана с гипотетическим потенциалом вызывать внезапную смерть из-за антиаритмических эффектов Dicorantilа типа 1.
Однако многоцентровый регистр и два недавних когортных регистра в значительной степени уменьшили эту озабоченность, показав более низкие показатели внезапной смерти, чем наблюдаемые от самого заболевания.

Эти опасения по поводу препарата следует рассматривать с клинической точки зрения, поскольку Dicorantil, как правило, является последним препаратом, который испытывают пациенты перед тем, как их направят на инвазивное уменьшение перегородки с хирургической септальной миэктомией (операция на открытом сердце) или алкогольную аблацию перегородки (контролируемая операция). острое сердечно-сосудистое заболевание).
Обе эти инвазивные процедуры имеют риск заболеваемости и смертности.

Для отдельных пациентов пробный пероральный прием Dicorantilа является разумным подходом, прежде чем приступать к инвазивной редукции перегородки.
Пациенты, которые реагируют на Dicorantil, продолжают принимать этот препарат.

Те, у кого сохраняются симптомы инвалидности или побочные эффекты, немедленно направляются на уменьшение перегородки.
Используя такую ступенчатую стратегию, исследователи сообщили, что выживаемость не отличается от выживаемости, наблюдаемой в нормальном населении Соединенных Штатов того же возраста.

Экстракардиальные эффекты:
Атропиноподобные эффекты (антихолинергические)
Сухость во рту
Запор
Задержка мочи. Dicorantil не следует назначать пациентам с симптоматическим простатитом.
Затуманенное зрение
Глаукома
Сыпь
Агранулоцитоз

Кроме того, Dicorantil может усиливать гипогликемический эффект гликлазида, инсулина и метформина.

Метаболизм Dicorantilа:
Dicorantil может вызывать гипогликемию, возможно, за счет усиления секреции инсулина, а также может потенцировать эффекты обычных гипогликемических препаратов.
Этот эффект может быть связан с моно-N-деалкилDicorantilом, главным метаболитом Dicorantilа, поскольку многие зарегистрированные случаи гипогликемии наблюдались у пациентов с почечной недостаточностью, у которых метаболит накапливается.

У шести субъектов, которые рассматривались для лечения Dicorantilом, концентрации глюкозы в сыворотке крови измеряли через 13, 15, 17 и 19 часов после ужина, без дальнейшего приема пищи, с дополнительным приемом двух таблеток модифицированного высвобождения Dicorantil 150 и без него. мг с ужином и через 12 часов.
Dicorantil значительно снижал концентрацию глюкозы в сыворотке крови во все сроки измерения в среднем на 0,54 ммоль/л.
Падение концентрации глюкозы в сыворотке не было связано с концентрацией Dicorantilа в сыворотке или концентрацией креатинина в сыворотке; Dicorantil был выше у пожилых пациентов и у пациентов с недостаточным весом.

Сообщалось также о гипогликемии у 70-летней женщины с сахарным диабетом 2 типа, принимавшей Dicorantil.

Клинические данные Dicorantilа:
Торговые названия: Норпейс
AHFS/Drugs.com: Монография
МедлайнПлюс: a682408
Категория беременности: AU: B2
Пути введения: Пероральный, внутривенный
Код УВД: C01BA03 (ВОЗ)

Легальное положение:
Великобритания: POM (только по рецепту)
США: только ℞

Фармакокинетические данные Dicorantilа:
Биодоступность: высокая
Связывание с белками: от 50% до 65% (зависит от концентрации)
Метаболизм: печеночный (CYP3A4-опосредованный)
Период полувыведения: 6,7 часа (от 4 до 10 часов).
Выведение: через почки (80%).

Идентификаторы Dicorantilа:
Название IUPAC: (RS)-4-(диизопропиламино)-2-фенил-2-(пиридин-2-ил)бутанамид
Номер КАС: 3737-09-5
Идентификатор PubChem: 3114
ИУПХАР/БПС: 7167
Банк наркотиков: DB00280
ХимПаук: 3002
УНИИ: GFO928U8MQ
КЕГГ: D00303
ЧЕБИ: ЧЕБИ:4657
ЧЕМБЛ: ЧЕМБЛ517
Информационная панель CompTox (EPA): DTXSID1045536
Информационная карта ECHA: 100.021.010

Свойства Dicorantilа:
Формула: C21H29N3O
Молярная масса: 339,483 г·моль-1
Температура плавления: от 94,5 до 95 ° C (от 202,1 до 203,0 ° F)
УЛЫБКИ: O=C(N)C(c1ncccc1)(c2ccccc2)CCN(C(C)C)C(C)C
ИнХИ: ИнХИ=1S/C21H29N3O/c1-16(2)24(17(3)4)15-13-21(20(22)25,18-10-6-5-7-11-18)19- 12-8-9-14-23-19/h5-12,14,16-17H,13,15H2,1-4H3,(H2,22,25)
Ключ:UVTNFZQICZKOEM-UHFFFAOYSA-N

Молекулярная масса: 437,5 г/моль
Количество доноров водородной связи: 4
Количество акцепторов водородной связи: 7
Количество вращающихся связей: 8
Точная масса: 437,20795813 г/моль
Масса моноизотопа: 437,20795813 г/моль
Площадь топологической полярной поверхности: 137Ų
Количество тяжелых атомов: 30
Сложность: 459
Количество атомов изотопа: 0
Определенное число стереоцентров атома: 0
Количество стереоцентров неопределенного атома: 1
Определенное число стереоцентров связи: 0
Неопределенный счетчик стереоцентров связи: 0
Количество ковалентно-связанных единиц: 2
Соединение канонизировано: Да

Названия Dicorantilа:

Названия регуляторных процессов:

дизопирамид
дизопирамид

Названия ИЮПАК:
4-(диизопропиламино)-2-фенил-2-пиридин-2-илбутанамид
4-[бис(пропан-2-ил)амино]-2-фенил-2-(пиридин-2-ил)бутанамид
дизопирамид

Другие идентификаторы:
3737-09-5

Синонимы Dicorantilа:
Дизопирамид ФОСФАТ
22059-60-5
Норпейс
Дизопирамид ФОСФАТНАЯ СОЛЬ
Ритмодан
Норпейс Кр
SC 7031 фосфат
Диритмин са
Diso-дурилес
дизопирамидфосфат
ИНЭКС 244-756-1
SC 7031 (фосфат)
НСК-756744
СК-13957
SC-7031 ФОСФАТ
ЧЕБИ:4658
N6BOM1935W
22059-60-5 (фосфат)
СК 13957
Норпейс (Теннесси)
2-(1-(аммониокарбонил)-3-(диизопропиламмонио)-1-фенилпропил)пиридиния фосфат
Дизопирамидфосфат
4-(диизопропиламино)-2-фенил-2-(пиридин-2-ил)бутанамидфосфат
4-[ди(пропан-2-ил)амино]-2-фенил-2-пиридин-2-илбутанамид; фосфорная кислота
альфа-(2-диизопропиламиноэтил)-альфа-фенил-2-пиридинацетамидфосфат
(+-)-альфа-(2-(диизопропиламино)этил)-альфа-фенил-2-пиридинацетамидфосфат (1:1)
2-пиридинацетамид, альфа-(2-(бис(1-метилэтил)амино)этил)-альфа-фенил-фосфат
2-пиридинацетамид, альфа-(2-(бис(1-метилэтил)амино)этил)-альфа-фенил-фосфат (1:1)
2-пиридинацетамид, альфа-(2-(диизопропиламино)этил)-альфа-фенил-фосфат
альфа-(2-(диизопропиламино)этил)-альфа-фенил-2-пиридинацетамидфосфат (1:1)
2-пиридинацетамид, альфа-(2-(бис(1-метилэтил)амино)этил)-альфа-фенил-, (+-)-, фосфат (1:1)
СР-01000003039
Дизопирамид (фосфат)
УНИИ-N6BOM1935W
SCHEMBL41810
МЛС000028431
СПЕКТР1500261
C21H29N3O.H3O4P
ЧЕМБЛ1201020
HMS501I11
DTXSID30944685
Дизопирамидфосфат (JAN/USP)
HMS1920I14
HMS2094K15
HMS2234B16
HMS3259J21
HMS3261C04
HMS3369L05
HMS3652M20
HMS3885J07
Фармакон1600-01500261
Дизопирамид ФОСФАТ [MI]
XAA05960
Дизопирамид ФОСФАТ [ЯНВАРЬ]
Токс21_500411
CCG-40209
Дизопирамид ФОСФАТ [USAN]
HY-12533A
NSC756744
Дизопирамид ФОСФАТ [VANDF]
АКОС040744844
Дизопирамид ФОСФАТ [МАРТ.]
Дизопирамид ФОСФАТ [USP-RS]
Дизопирамид ФОСФАТ [WHO-DD]
LP00411
NC00683
СНБ 756744
Дизопирамидфосфат [USAN:BAN:JAN]
NCGC00093836-01
NCGC00093836-02
NCGC00093836-03
NCGC00093836-04
NCGC00261096-01
SMR000058438
Дизопирамид ФОСФАТ [ОРАНЖЕВАЯ КНИГА]
ЛС-130131
Дизопирамид ФОСФАТ [МОНОГРАФИЯ EP]
Дизопирамидфосфат [USAN:USP:BAN:JAN]
ЕС-0100411
FT-0630479
S4143
SW196836-3
SW196836-4
Дизопирамид ФОСФАТ [МОНОГРАФИЯ USP]
C07740
Д 6035
D00637
СР-01000003039-2
СР-01000003039-6
Q27106430
4-(диизопропиламино)-2-фенил-2-(2-пиридил)бутанамид
(R)-4-(диизопропиламино)-2-фенил-2-(пиридин-2-ил)бутанамидофосфат
4-[ди(пропан-2-ил)амино]-2-фенил-2-пиридин-2-илбутанамид, фосфорная кислота
4-ДИИЗОПРОПИЛАМИНО-2-ФЕНИЛ-2-(2-ПИРИДИЛ)БУТИРАМИД ФОСФАТ
Дизопирамидфосфат, справочный стандарт Европейской фармакопеи (EP)
Дизопирамидфосфат, эталонный стандарт Фармакопеи США (USP)
(+/-)-.АЛЬФА.-(2-(ДИИЗОПРОПИЛАМИН)ЭТИЛ)-.АЛЬФА.-ФЕНИЛ-2-ПИРИДИНАЦЕТАМИД ФОСФАТ (1:1)
2-ПИРИДИНАЦЕТАМИД, .АЛЬФА.-(2-(БИС(1-МЕТИЛЕТИЛ)АМИНО)ЭТИЛ)-.АЛЬФА.-ФЕНИЛ-, (+/-)-, ФОСФАТ (1:1)
223-110-2 [ЭИНЭКС]
2-пиридинацетамид, а-[2-[бис(1-метилэтил)амино]этил]-а-фенил-
2-пиридинацетамид, α-(2-(бис(1-метилэтил)амино)этил)-α-фенил-
2-пиридинацетамид, α-[2-[бис(1-метилэтил)амино]этил]-α-фенил- [ACD/название индекса]
3737-09-5 [РН]
4-(Диизопропиламино)-2-фенил-2-(2-пиридинил)бутанамид [немецкий] [ACD/название IUPAC]
4-(Диизопропиламино)-2-фенил-2-(2-пиридинил)бутанамид [ACD/название IUPAC]
4-(Диизопропиламино)-2-фенил-2-(2-пиридинил)бутанамид [французский] [ACD/название IUPAC]
4-(Диизопропиламино)-2-фенил-2-(2-пиридил)бутирамид
4-(Диизопропиламино)-2-фенил-2-(пиридин-2-ил)бутанамид
4-(дипропан-2-иламино)-2-фенил-2-(пиридин-2-ил)бутанамид
а-[2-(диизопропиламино)этил]-а-фенил-2-пиридинацетамид
а-[2-[Бис(1-метилэтил)амино]этил]а-фенил-2-пиридинацетамид
disopiramida [испанский] [INN]
Дизопирамид [французский] [INN]
Дизопирамид [BAN] [INN] [JAN] [JP15] [USAN] [Wiki]
Дизопирамид, (R)-
Дизопирамид, (S)-
disopyramidum [латиница] [INN]
изоритм
лиспайн
MFCD00057366 [количество леев]
Норпейс [торговое название]
Ритмодан [торговое название]
α-[2-(ДИИЗОПРОПИЛАМИН)ЭТИЛ]-α-ФЕНИЛ-2-ПИРИДИНАЦЕТАМИД
α-диизопропиламиноэтил-α-фенилпиридин-2-ацетамид
дизопирамид [Русский] [МНН]
ديسوبيراميد [арабский] [INN]
丙吡胺 [китайский] [INN]
свободное основание дизопирамида
НОРПЕЙС КР
Ритмодан-Ла
ξ-Дизопирамид
[3737-09-5] [РН]
1309283-08-6 [РН]
2-пиридинацетамид, α-(2-(диизопропиламино)этил)-α-фенил-
2-пиридинацетамид, α-[2-(диизопропиламино)этил]-α-фенил-
2-пиридинацетамид, α-[2-[бис(1-метилэтил)амино]этил]-α-фенил-
3737-09-5 (свободная база)
38236-46-3 [РН]
4-(диизопропиламино)-2-фенил-2-(2-пиридил)бутанамид
4-(диизопропиламино)-2-фенил-2-пиридин-2-илбутанамид
4-[бис(метилэтил)амино]-2-фенил-2-(2-пиридил)бутанамид
4-[бис(пропан-2-ил)амино]-2-фенил-2-(пиридин-2-ил)бутанамид
4-[бис(пропан-2-ил)амино]-2-фенил-2-(пиридин-2-ил)бутанимидиновая кислота
4-[ди(пропан-2-ил)амино]-2-фенил-2-(пиридин-2-ил)бутанамид
4-[ди(пропан-2-ил)амино]-2-фенил-2-пиридин-2-илбутанамид
492056 [Бейльштейн]
4-диизопропиламино-2-фенил-2-(2-пиридил)бутирамид
54687-36-4 [РН]
74464-83-8 [РН]
74464-84-9 [РН]
БС-17145
ДБ00280
Dicorantil
Дизопирамида
Дизопирамида [INN-испанский]
Дизопирамид-d5
дизопирамида
Дизопирамид [МНН-лат.]
MFCD00069254 [количество леев]
н-дезалкил дизопирамид
Норпейс®
Ритмодан
Ритмодан П [торговое название]
Ритмодан®
Сирл 703
α-(2-(диизопропиламино)этил)-α-фенил-2-пиридинацетамид
α-(2-(диизопропиламино)этил)-α-фенил-2-пиридинацетамид
α-[2-[бис(1-метилэтил)амино]этил]-α-фенил-2-пиридинацетамид
γ-диизопропиламино-α-фенил-α-(2-пиридил)бутирамид
γ-диизопропиламино-α-фенил-α-(2-пиридил)бутирамид
дизопирамид
ديسوبيراميد
丙吡胺

DICUMYL PEROXIDE The aim of this article was to determine the effect of the dicumyl peroxide (dicumyl peroxide) content on thermal and mechanical properties of polylactide (PLA). Reactive extrusion of the PLA and dicumyl peroxide blends was performed. The dicumyl peroxide content varied from 0.2 to 1.0 wt.%. The extruded samples were characterized by the Fourier transform infrared spectroscopy (FTIR), analyses of gel content and swelling degree, thermogravimetry (TG), differential scanning calorimetry (DSC), dynamic mechanical analysis (DMA), and tensile and impact strength tests. It was found that dicumyl peroxide caused crosslinking of PLA as well as contributed to formation of low-molecular weight products of decomposition and degradation processes. These products caused plasticization of PLA, which led to a decrease in the glass transition temperature. An increase in tensile strength and decrease in impact strength were observed as the dicumyl peroxide content increased. Dicumyl peroxide price More Price(4) Manufacturer Product number Product description CAS number Packaging Price Updated Buy Sigma-Aldrich 329541 Dicumyl peroxide 98% 80-43-3 100g $50 2020-08-18 Buy Sigma-Aldrich 329541 Dicumyl peroxide 98% 80-43-3 500g $154 2020-08-18 Buy Alfa Aesar H60442 Dicumyl peroxide, 98% 80-43-3 100g $35.9 2020-06-24 Buy Alfa Aesar H60442 Dicumyl peroxide, 98% 80-43-3 500g $140 2020-06-24 Buy Dicumyl peroxide Chemical Properties,Uses,Production Chemical Properties white powder Chemical Properties Dicumyl peroxide is a crystalline solid that melts at 42°C. It is insoluble in water and soluble in vegetable oil and organic solvents . It is used as a high-temperature catalyst in production of polystyrene plastics. The deflagration hazard potential of this peroxide was tested using 5 g of igniter in the revised time–pressure test, but no pressure rise was produced . Noller et al. found it to be an intermediate fire hazard. General Description White powder with a characteristic odor. Reactivity Profile The explosive instability of the lower dialkyl peroxides (e.g., dimethyl peroxide) and 1,1-bis-peroxides decreases rapidly with increasing chain length and degree of branching, the di-tert-alkyl derivatives being amongst the most stable class of peroxides. Though many 1,1-bis-peroxides have been reported, few have been purified because of the higher explosion hazards compared with the monofunctional peroxides. Dicumyl peroxide is unlikely that this derivative would be particularly unstable compared to other peroxides in it's class, Bretherick 2nd ed., p 44 1979. Safety Profile Mildly toxic by ingestion. See also PEROXIDES. When heated to decomposition it emits acrid smoke and irritating fumes. Purification Methods Crystallise the peroxide from 95% EtOH (charcoal). Store it at 0o. Potentially EXPLOSIVE. [Beilstein 6 IV 3220.] Dicumyl peroxide Preparation Products And Raw materials Raw materials Cumene Ethanol Sodium sulfite PERCHLORIC ACID Cumyl hydroperoxide Preparation Products microdispersoid acrylate resin filling emulsion dimethylacrolyl phenoxy propanestyrene copolymer optical plastics 80-43-3(Dicumyl peroxide)Related Search: ethyl hydroperoxide TERT-BUTYL CUMYL PEROXIDE Methyl acrylate Methyl Methanol Di-tert-butyl peroxide Dicumyl peroxide Benzoyl peroxide DIISOPROPYLBENZENE Acetonitrile Methylparaben 4,4'-Methylene bis(2-chloroaniline) Hydrogen peroxide Aluminum oxide 3,5-Diisopropylbenzene hydroperoxide 1,3-DIISOPROPYLBENZENE 2,2'-Dithiobis(benzothiazole) Vulcanizator Description and features Iniper DCP (dicumyl peroxide), is a white crystal which has C18H22O2 as chemical formula. This dialkyl peroxide is used for the (co)polymerization of styrene, besides it is used to crosslink polymers and elastomers. Further it finds its application as flame retardant synergist in EPS. Dicumyl Peroxide is also known as Diisopropylbenzene peroxide, Bis(α,α-dimethylbenzyl) peroxide and Dicumene hydroperoxide. Storage Store Dicumyl Peroxide in a cool, dry and well-ventilated area and in line with legal requirements. Keep Iniper DCP away from heat sources, avoid contact with acids, alkalines, heavy metal compounds and reducing agents. The Self Accelerating Decomposition Temperature (SADT) in original packaging is 75ºC. The aim of this article was to determine the effect of the dicumyl peroxide (dicumyl peroxide) content on thermal and mechanical properties of polylactide (PLA). Reactive extrusion of the PLA and dicumyl peroxide blends was performed. The dicumyl peroxide content varied from 0.2 to 1.0 wt.%. The extruded samples were characterized by the Fourier transform infrared spectroscopy (FTIR), analyses of gel content and swelling degree, thermogravimetry (TG), differential scanning calorimetry (DSC), dynamic mechanical analysis (DMA), and tensile and impact strength tests. It was found that dicumyl peroxide caused crosslinking of PLA as well as contributed to formation of low-molecular weight products of decomposition and degradation processes. These products caused plasticization of PLA, which led to a decrease in the glass transition temperature. An increase in tensile strength and decrease in impact strength were observed as the dicumyl peroxide content increased. Dicumyl peroxide price More Price(4) Manufacturer Product number Product description CAS number Packaging Price Updated Buy Sigma-Aldrich 329541 Dicumyl peroxide 98% 80-43-3 100g $50 2020-08-18 Buy Sigma-Aldrich 329541 Dicumyl peroxide 98% 80-43-3 500g $154 2020-08-18 Buy Alfa Aesar H60442 Dicumyl peroxide, 98% 80-43-3 100g $35.9 2020-06-24 Buy Alfa Aesar H60442 Dicumyl peroxide, 98% 80-43-3 500g $140 2020-06-24 Buy Dicumyl peroxide Chemical Properties,Uses,Production Chemical Properties white powder Chemical Properties Dicumyl peroxide is a crystalline solid that melts at 42°C. It is insoluble in water and soluble in vegetable oil and organic solvents . It is used as a high-temperature catalyst in production of polystyrene plastics. The deflagration hazard potential of this peroxide was tested using 5 g of igniter in the revised time–pressure test, but no pressure rise was produced . Noller et al. found it to be an intermediate fire hazard. General Description White powder with a characteristic odor. Reactivity Profile The explosive instability of the lower dialkyl peroxides (e.g., dimethyl peroxide) and 1,1-bis-peroxides decreases rapidly with increasing chain length and degree of branching, the di-tert-alkyl derivatives being amongst the most stable class of peroxides. Though many 1,1-bis-peroxides have been reported, few have been purified because of the higher explosion hazards compared with the monofunctional peroxides. Dicumyl peroxide is unlikely that this derivative would be particularly unstable compared to other peroxides in it's class, Bretherick 2nd ed., p 44 1979. Safety Profile Mildly toxic by ingestion. See also PEROXIDES. When heated to decomposition it emits acrid smoke and irritating fumes. Purification Methods Crystallise the peroxide from 95% EtOH (charcoal). Store it at 0o. Potentially EXPLOSIVE. [Beilstein 6 IV 3220.] Dicumyl peroxide Preparation Products And Raw materials Raw materials Cumene Ethanol Sodium sulfite PERCHLORIC ACID Cumyl hydroperoxide Preparation Products microdispersoid acrylate resin filling emulsion dimethylacrolyl phenoxy propanestyrene copolymer optical plastics 80-43-3(Dicumyl peroxide)Related Search: ethyl hydroperoxide TERT-BUTYL CUMYL PEROXIDE Methyl acrylate Methyl Methanol Di-tert-butyl peroxide Dicumyl peroxide Benzoyl peroxide DIISOPROPYLBENZENE Acetonitrile Methylparaben 4,4'-Methylene bis(2-chloroaniline) Hydrogen peroxide Aluminum oxide 3,5-Diisopropylbenzene hydroperoxide 1,3-DIISOPROPYLBENZENE 2,2'-Dithiobis(benzothiazole) Vulcanizator Description and features Iniper DCP (dicumyl peroxide), is a white crystal which has C18H22O2 as chemical formula. This dialkyl peroxide is used for the (co)polymerization of styrene, besides it is used to crosslink polymers and elastomers. Further it finds its application as flame retardant synergist in EPS. Dicumyl Peroxide is also known as Diisopropylbenzene peroxide, Bis(α,α-dimethylbenzyl) peroxide and Dicumene hydroperoxide. Storage Store Dicumyl Peroxide in a cool, dry and well-ventilated area and in line with legal requirements. Keep Iniper DCP away from heat sources, avoid contact with acids, alkalines, heavy metal compounds and reducing agents. The Self Accelerating Decomposition Temperature (SADT) in original packaging is 75ºC.

DICYCLOHEXYL SODIUM SULFOSUCCINATE, N° CAS : 23386-52-9, Nom INCI : DICYCLOHEXYL SODIUM SULFOSUCCINATE, Nom chimique : Sodium 1,4-dicyclohexyl sulphonatosuccinate, N° EINECS/ELINCS : 245-629-3. Ses fonctions (INCI): Agent nettoyant : Aide à garder une surface propre. Sinergiste de mousse : Améliore la qualité de la mousse produite en augmentant une ou plusieurs des propriétés suivantes: volume, texture et / ou stabilité. Hydrotrope : Augmente la solubilité d'une substance qui est peu soluble dans l'eau.Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation

DIDECYL-DIMETHYLAMMONIUM CHLORIDE; N-Decyl-N,N-dimethyl-1-decanaminium chloride; quaternium 12; 1-Decanaminium,N-decyl-N,N-dimethyl-,chloride; aliquat203; bardac22; bio-dac50-22; btc1010; btco1010; ddac(didecyldimethylammoniumchloride); didecyldimethyl-ammoniuchloride; didecyldimethylammoniumchloride(ddac); dimethyldidecylammoniumchloride; n-decyl-n,n-dimethyl-1-decanaminiuchloride; DIDECYLDIMONIUM CHLORIDE; didecyl dimethyl Ammonium Chloride 50% solution in Toluene; didecyl dimethyl Ammonium Chloride 70% solution; Didecildimethylammonium chloride; BARDAC2280; Bardac(R) 22 CAS NO:7173-51-5

2,2'-Iminobisethanol; Diethylolamine; DEA; Diolamine; Bis(2-hydroxyethyl)amine; N,N-Diethanolamine; Bis(hydroxyethyl)amine; 2,2'-Dihydroxydiethylamine; iminodiethanol; Diaethanolamin (German); Diethanolamin (Czech); 2,2'-iminobis-Ethanol; Di(2-hydroxyethyl)amine; Iminodiethanol; 2-[(2-Hydroxyethyl)amino]ethanol; 2,2'-Dihydroxydiethylamine; 2,2'-Iminobis[ethanol]; 2,2'-Iminodi-1-ethanol; 2,2'-Iminodiethanol; N,N-Bis(2-hydroxyethyl)amine; Bis(hydroxyethyl)amine; cas no: 111-42-2

2,2'-Iminobisethanol; Diethylolamine; DEA; Diolamine; Bis(2-hydroxyethyl)amine; N,N-Diethanolamine; Bis(hydroxyethyl)amine; 2,2'-Dihydroxydiethylamine; iminodiethanol; Diaethanolamin (German); Diethanolamin (Czech); 2,2'-iminobis-Ethanol; Di(2-hydroxyethyl)amine; Iminodiethanol; 2-[(2-Hydroxyethyl)amino]ethanol; 2,2'-Dihydroxydiethylamine; 2,2'-Iminobis[ethanol]; 2,2'-Iminodi-1-ethanol; 2,2'-Iminodiethanol; N,N-Bis(2-hydroxyethyl)amine; Bis(hydroxyethyl)amine; cas no: 111-42-2

Diethyl Isopropanol Amine; DiethanolisopropanolaMine (DEIPA); 2,2'-(2-Hydroxypropylimino)bisethanol; 2,2'-[(2-Hydroxypropyl)imino]bisethanol; 2-Propanol, 1-bis(2-hydroxyethyl)amino-; 1-[BIS(2-HYDROXYETHYL)AMINO]-2-PROPANOL; N,N-BIS(2-HYDROXYETHYL)ISOPROPANOLAMINE; 1-[Bis(2-hydroxyethyl)amino]propane-2-ol; 1-[bis-2-hydroxy-ethyl-amino]-propan-2-ol; 1-(N,N-bis(2-Hydroxyethyl)amino)propan-2-ol; 1-[bis-(2-hydroxy-ethyl)-amino]-propan-2-ol; 1-[N,N-BIS(2-HYDROXYETHYL)AMINO]-2-PROPANOL; 1-[N,N-Bis(2-hydroxyethyl)amino]-2-propanol,94%; 1-[N,N-Bis(2-hydroxyethyl)amino]-2-propanol 94% CAS NO:6712-98-7

2,2'-DIHYDROXYDIETHYLAMINE; 2,2'-IMINODIETHANOL; 2,2-IMINODIETHANOL; 2,2'-IMINODIETHANOL,BIS(BETA-HYDROXYETHYL)AMINE; BIS(2-HYDROXYETHYL)AMINE; BIS(2-HYDROXYETHYL)AMINE IMINODIETHANOL; DI(2-HYDROXYETHYL)AMINE; DI-BETA-HYDROXYETHYLAMINE; DIETHANOLAMINE; DIETHANOLAMINE SUBSTRATE BUFFER; DIETHYLOLAMINE; LABOTEST-BB LTBB000446; 2-((2-hydroxyethyl)amino)ethanol; 2-(2-hydroxyethylamino)ethanol; 2-(2-hydroxy-ethylamino)-ethanol; 2-(2-hydroxyethylamino)-ethanol; 2,2’-dihydroxy-diethylamin; 2,2’-iminobis-ethano; 2,2’-iminobisethanol; 2,2’-iminobis-Ethanol CAS NO:111-42-2

DIETHANOLAMINE Diethanolamine Diethanolamine Skeletal formula of Diethanolamine Ball-and-stick model of the Diethanolaminemolecule Names IUPAC name 2,2'-aminodiethanol Other names Bis(hydroxyethyl)amine N,N-Bis(2-hydroxyethyl)amine 2,2'-Dihydroxydiethylamine β,β'-Dihydroxydiethylamine Diolamine 2-[(2-Hydroxyethyl)amino]ethanol 2,2'-Iminobisethanol Iminodiethanol Di(2-hydroxyethyl)amine bis(2-Hydroxyethyl)amine 2,2'-Iminodiethanol Identifiers CAS Number 111-42-2 check 3D model (JSmol) Interactive image 3DMet B01050 Beilstein Reference 605315 ChEBI CHEBI:28123 check ChEMBL ChEMBL119604 check ChemSpider 13835604 check ECHA InfoCard 100.003.517 Edit this at Wikidata EC Number 203-868-0 KEGG D02337 check MeSH Diethanolamine PubChem CID 8113 RTECS number KL2975000 UNII AZE05TDV2V check CompTox Dashboard (EPA) DTXSID3021932 Edit this at Wikidata InChI[show] SMILES[show] Properties Chemical formula C4H11NO2 Molar mass 105.137 g·mol−1 Appearance Colourless crystals Odor Ammonia odor Density 1.097 g·mL−1 Melting point 28.00 °C; 82.40 °F; 301.15 K Boiling point 271.1 °C; 519.9 °F; 544.2 K Solubility in water Miscible log P -1.761 Vapor pressure <1 Pa (at 20 °C) UV-vis (λmax) 260 nm Refractive index (nD) 1.477 Thermochemistry Heat capacity (C) 137 J·K−1·mol−1 Std enthalpy of formation (ΔfH⦵298) −496.4 – −491.2 kJ·mol−1 Std enthalpy of combustion (ΔcH⦵298) −26.548 – −26.498 MJ·kmol−1 Hazards Safety data sheet sciencelab.com GHS pictograms GHS05: Corrosive GHS07: Harmful GHS08: Health hazard GHS Signal word Danger GHS hazard statements H302, H315, H318, H373 GHS precautionary statements P280, P305+351+338 Flash point 138 °C (280 °F; 411 K) Autoignition temperature 365 °C (689 °F; 638 K) Explosive limits 1.6–9.8%[1] Lethal dose or concentration (LD, LC): LD50 (median dose) 120 mg·kg−1 (intraperitoneal, rat) 710 mg·kg−1 (oral, rat) 778 mg·kg−1 (intravaneous, rat) 12.2 g·kg−1 (dermal, rabbit) NIOSH (US health exposure limits): PEL (Permissible) None[1] REL (Recommended) TWA: 3 ppm (15 mg/m3)[1] IDLH (Immediate danger) N.D.[1] Related compounds Related alkanols N-Methylethanolamine Dimethylethanolamine Diethylethanolamine N,N-Diisopropylaminoethanol Methyl Diethanolamine Triethanolamine Bis-tris methane Meglumine Related compounds Diethylhydroxylamine Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). check verify (what is check☒ ?) Infobox references Diethanolamine, often abbreviated as Diethanolamineor DEOA, is an organic compound with the formula HN(CH2CH2OH)2. Pure Diethanolaminei s a white solid at room temperature, but its tendencies to absorb water and to supercool[2] mean it is often encountered as a colorless, viscous liquid. Diethanolamine is polyfunctional, being a secondary amine and a diol. Like other organic amines, Diethanolamine acts as a weak base. Reflecting the hydrophilic character of the secondary amine and hydroxyl groups, Diethanolamine is soluble in water. Amides prepared from Diethanolamine are often also hydrophilic. In 2013, the chemical was classified by the International Agency for Research on Cancer as "possibly carcinogenic to humans" (Group 2B). Production The reaction of ethylene oxide with aqueous ammonia first produces ethanolamine: C2H4O + NH3 → H2NCH2CH2OH which reacts with a second and third equivalent of ethylene oxide to give Diethanolamineand triethanolamine: C2H4O + H2NCH2CH2OH → HN(CH2CH2OH)2 C2H4O + HN(CH2CH2OH)2 → N(CH2CH2OH)3 About 300M kg are produced annually in this way.[3] The ratio of the products can be controlled by changing the stoichiometry of the reactants.[4] Uses Diethanolamine is used as a surfactant and a corrosion inhibitor. It is used to remove hydrogen sulfide and carbon dioxide from natural gas. Diethanolamineis widely used in the preparation of diethanolamides and Diethanolaminesalts of long-chain fatty acids that are formulated into soaps and surfactants used in liquid laundry and dishwashing detergents, cosmetics, shampoos and hair conditioners.[5]In oil refineries, a Diethanolaminein water solution is commonly used to remove hydrogen sulfide from sour gas. It has an advantage over a similar amine, ethanolamine, in that a higher concentration may be used for the same corrosion potential. This allows refiners to scrub hydrogen sulfide at a lower circulating amine rate with less overall energy usage. Diethanolamineis a chemical feedstock used in the production of morpholine.[3][4] Morpholine from DEA.png Amides derived from Diethanolamineand fatty acids, known as diethanolamides, are amphiphilic. The reaction of 2-chloro-4,5-diphenyloxazole with Diethanolaminegave rise to Ditazole. The reaction of Diethanolamineand Isobutyraldehyde with water removed produces an Oxazolidine. Commonly used ingredients that may contain DEA Diethanolamineis used in the production of diethanolamides, which are common ingredients in cosmetics and shampoos added to confer a creamy texture and foaming action. Consequently, some cosmetics that include diethanolamides as ingredients contain DEA. [6]Some of the most commonly used diethanolamides include: Cocamide DEA DEA-Cetyl Phosphate DiethanolamineOleth-3 Phosphate Lauramide DEA Myristamide DEA Oleamide DEA Safety Diethanolamineis a potential skin irritant in workers sensitized by exposure to water-based metalworking fluids.[7] One study showed that Diethanolamineinhibits in baby mice the absorption of choline, which is necessary for brain development and maintenance;[8] however, a study in humans determined that dermal treatment for 1 month with a commercially available skin lotion containing Diethanolamineresulted in Diethanolaminelevels that were "far below those concentrations associated with perturbed brain development in the mouse".[9] In a mouse study of chronic exposure to inhaled Diethanolamineat high concentrations (above 150 mg/m3), Diethanolaminewas found to induce body and organ weight changes, clinical and histopathological changes, indicative of mild blood, liver, kidney and testicular systemic toxicity.[10] A 2009 study found that Diethanolaminehas potential acute, chronic and subchronic toxicity properties for aquatic species. Properties of diethanolamine Molecular Formula:C4H11NO2 Molecular Weight:105.137 g/mol Flash Point:176°(349°F) Boiling Point:268-270° Flash Point:176°(349°F) Density:1.097 Diethanolamine (DEA or DEOA) is a colorless, viscous liquid organic chemical compound that is both a secondary amine and a dialcohol. According to the International Agency for Research, the compound is a suspected carcinogen to humans. The hydrophilic liquid is used as a surfactant as well as a corrosion inhibitor. DEA is also used to remove hydrogen sulfide from natural gas. Reactivity Profile Diethanolamine is an aminoalcohol. Amines are chemical bases. They neutralize acids to form salts plus water. These acid-base reactions are exothermic. The amount of heat that is evolved per mole of amine in a neutralization is largely independent of the strength of the amine as a base. Amines may be incompatible with isocyanates, halogenated organics, peroxides, phenols (acidic), epoxides, anhydrides, and acid halides. Flammable gaseous hydrogen is generated by amines in combination with strong reducing agents, such as hydrides. This compound is hygroscopic. It may be sensitive to exposure to air and light. This compound can react with oxidizing materials, acids, CO2, copper alloys, aluminum, zinc, galvanized iron and copper. Applications Diethanolamine is used in the preparation of morpholine and diethanolamides, which is an active ingredient in cosmetics and shampoos. It acts as a surfactant and a corrosion inhibitor. It is utilized to remove hydrogen sulfide and carbon dioxide from natural gas. Further, it is an intermediate used in the rubber chemicals, as a humectant and a softening agent, and as an emulsifier and dispersing agent in agricultural chemicals. In addition to this, it is used in cutting oils, cleaners, soaps, polishers, and pharmaceuticals. Health Hazard Information Acute Effects: Acute inhalation exposure to diethanolamine in humans may result in irritation of the nose and throat, and dermal exposure may result in irritation of the skin. Animal studies indicate that exposure to diethanolamine by intravenous injections can cause increased blood pressure, pupillary dilatation, and salivation. At very high doses in animals, sedation, and coma may result. Acute animal studies have shown that dermal exposure to diethanolamine may burn skin, and eye contact with the chemical may impair vision. Acute animal tests in rats have shown diethanolamine to have moderate acute toxicity from oral exposure. Chronic Effects (Noncancer): No information is available on the chronic effects of diethanolamine in humans. Animal studies have reported effects on the liver, kidney, blood, and CNS from chronic oral exposure to diethanolamine. Skin lesions were observed in mice following daily topical administration of diethanolamine. EPA has not established a Reference Concentration (RfC) or a Reference Dose (RfD) for diethanolamine. The California Environmental Protection Agency (CalEPA) has established a chronic reference exposure level of 0.02 milligrams per cubic meter (mg/m ) for diethanolamine based on effects on the blood in rats. The CalEPA reference exposure level is a concentration at or below which adverse health effects are not likely to occur. It is not a direct estimator of risk but rather a reference point to gauge the potential effects. At lifetime exposures increasingly greater than the reference exposure level, the potential for adverse health effects increases. Reproductive/Developmental Effects: No information is available on the reproductive or developmental effects of diethanolamine in humans. Animal studies have reported testicular degeneration and reduced sperm motility and count from oral exposure to diethanolamine. Cancer Risk: No information is available on the carcinogenic effects of diethanolamine in humans. EPA has not classified diethanolamine for carcinogenicity. Air & Water Reactions Water soluble. Fire Hazard Special Hazards of Combustion Products: Irritating vapors are generated when heated. Health Hazard Irritation of eyes and skin. Breathing vapors may cause coughing, a smothering sensation, nausea, headache. Diethanolamine appears as oily colorless liquid or solid white crystals. Slight rotten fish or ammonia odor. Denser than water. (USCG, 1999) CAMEO Chemicals Diethanolamine is a member of the class of ethanolamines that is ethanolamine having a N-hydroxyethyl substituent. It has a role as a human xenobiotic metabolite. It derives from an ethanolamine. ChEBI Diethanolamine is used in a number of consumer products, such as shampoos, cosmetics, and pharmaceuticals. Limited information is available on the health effects of diethanolamine. Acute (short- term) inhalation exposure to diethanolamine in humans may result in irritation of the nose and throat, and dermal exposure may irritate the skin. No information is available on the chronic (long-term), reproductive, developmental, or carcinogenic effects of diethanolamine in humans. Animal studies have reported effects on the liver, kidney, blood, and central nervous system (CNS) from chronic oral exposure to diethanolamine. The National Toxicology Program (NTP) reported an increased incidence of liver and kidney tumors in mice from dermal exposure to diethanolamine. EPA has not classified diethanolamine for carcinogenicity. Molecular Weight of Diethanolamine 105.14 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) XLogP3 -1.4 Computed by XLogP3 3.0 (PubChem release 2019.06.18) Hydrogen Bond Donor Count of Diethanolamine 3 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Hydrogen Bond Acceptor Count of Diethanolamine 3 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Rotatable Bond Count of Diethanolamine 4 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Exact Mass of Diethanolamine 105.078979 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Monoisotopic Mass of Diethanolamine 105.078979 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Topological Polar Surface Area of Diethanolamine 52.5 Ų Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Heavy Atom Count of Diethanolamine 7 Computed by PubChem Formal Charge of Diethanolamine 0 Computed by PubChem Complexity of Diethanolamine 28.9 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Isotope Atom Count of Diethanolamine 0 Computed by PubChem Defined Atom Stereocenter Count of Diethanolamine 0 Computed by PubChem Undefined Atom Stereocenter Count of Diethanolamine 0 Computed by PubChem Defined Bond Stereocenter Count of Diethanolamine 0 Computed by PubChem Undefined Bond Stereocenter Count of Diethanolamine 0 Computed by PubChem Covalently-Bonded Unit Count of Diethanolamine 1 Computed by PubChem Compound of Diethanolamine Is Canonicalized Yes Technical products and impurities Diethanolamine is commercially available with the following specifications: purity, 99% min.; monoethanolamine, 0.5% max.; triethanolamine 0.5% max.; and water content, 0.15% max. (Huntsman Corporation, 2008). A lower grade of diethanolamine is commercially available with the following specifications: purity, 55% min.; monoethanolamine, 5% max.; triethanolamine 40% max.; and water content, 1% max. (Elarum, 2010). In Europe, diethanolamine is typically marketed with the following specifications: purity, > 99%; triethanolamine, 1% max.; monoethanolamine, 0.5% max.; and water content, 0.2% max. (OECD, 2007). Diethanolamine is also available as a blend of 83–87% diethanolamine and 13–17% deionized water with monoethanolamine and triethanolamine present as impurities at a maximum concentration of 1% (Huntsman Corporation, 2007). 1.1.5. Analysis Diethanolamine can be determined in workplace air by drawing the air sample through aqueous hexanesulfonic acid and analysing with ion chromatography. The range for this method is 0.30–19.5 mg for a 100-L air sample (NIOSH, 2003). Diethanolamine can be determined in air by drawing the air sample through sampling tubes containing XAD-2 resin coated with 10% 1-naphthylisothiocyanate. Samples are analysed by desorbing the adsorbent with dimethylformamide and quantitating the amine derivative by high performance liquid chromatography using ultraviolet detection (OSHA, 2010). Exposure to diethanolamine from metal working fluids has been determined by high performance liquid chromatography/mass spectrometry analysis of aqueous hand-washing solutions and personal air samples collected on acid-treated glass fibre filters (Henriks-Eckerman et al., 2007). Levels of diethanolamine in shampoo products can be determined by liquid chromatography/thermal energy analysis after conversion to N-nitrosodiethanolamine with acetic acid and sodium nitrite (Chou, 2005). 1.2. Production and use 1.2.1. Production Diethanolamine is produced by reacting ethylene oxide with ammonia. In most production facilities, ethylene oxide and ammonia are reacted in a batch process that yields a crude mixture of ethanolamine, diethanolamine and triethanolamine. The mixture is then distilled to separate and purify the individual compounds (Edens & Lochary, 2004). Ethanolamines became available commercially in the early 1930s; they assumed steadily growing commercial importance as intermediates after 1945, because of the large-scale production of ethylene oxide. Since the mid-1970s, economical production of very pure, colourless ethanolamines has been possible (IARC, 2000). It has been estimated that 45 900 and 75 400 tonnes of diethanolamine were produced in the USA in 1972 and 1983, respectively (HSDB, 2010). Estimated annual production of diethanolamine in the USA over three decades is presented in Table 1.1. Table 1.1. Estimated annual production of diethanolamine in the USA (thousand tonnes). Table 1.1 Estimated annual production of diethanolamine in the USA (thousand tonnes). Worldwide production of ethanolamines in 1985 was approximately (thousand tonnes per year): USA, 220; western Europe, 145; south-eastern Asia, 40; South America, 18; and eastern Europe, 4. Of the world production of ethanolamines in 1985, approximately 50% was mono-ethanolamine, 30–35% diethanolamine and 15–20% triethanolamine (Hammer et al., 1987). The annual world capacity for the ethanolamines in 2005 was estimated at 1 510 000 tonnes, subdivided into 400 000 tonnes for Europe (eight production sites), 780 000 tonnes for North and South America (seven production sites), 30 000 tonnes for the Middle East (one production site) and 300 000 tonnes for the Asia/Pacific region (11 production sites). No data on individual capacities for diethanolamine were available (OECD, 2007). Information available in 2010 indicated that diethanolamine was manufactured by 29 companies in the USA, seven companies in Mexico, three companies each in the People's Republic of China and the United Kingdom, two companies each in Canada, Germany, China (Hong Kong SAR) and India, and one company each in Belgium, Slovak Republic and Switzerland (Chemical Sources International, 2010). Other sources indicated that diethanolamine was produced by five companies in the USA (HSDB, 2010), five companies in Germany, three companies in the United Kingdom, three companies in the Netherlands and one company each in Austria, Belgium, Denmark and Sweden (IUCLID, 2000). 1.2.2. Use Diethanolamine is widely used in the preparation of diethanolamides and diethanolamine salts of long-chain fatty acids that are formulated into soaps and surfactants used in liquid laundry and dishwashing detergents, cosmetics, shampoos and hair conditioners. Diethanolamine is also used in the production of lubricants in the textile industry, in industrial gas purification to remove acid gases and as an emulsifer and dispersing agent in preparations of agricultural chemicals. Diethanolamine is used in metalworking fluids for cutting, stamping and die-casting operations as a corrosion inhibitor. In the production of detergents, cleaners, fabric solvents and metalworking fluids, diethanolamine is used for acid neutralization and soil deposition. Aqueous diethanolamine solutions are used as solvents for numerous drugs that are administered intravenously. Shampoos and hair dyes may contain free diethanolamine as a component and/or as a contaminant of fatty acid alkanolamides, generally in the range of 0.2–10% (Bailey, 2007). Diethanolamine is used with sulfolane in the sulfinol process to absorb carbon dioxide and hydrogen sulfide gases The database for substances in preparations in Nordic countries lists a wide variety of uses of diethanolamine registered in Denmark, Norway, Sweden and Finland. In 2004, 520 preparations containing diethanolamine, accounting for a total volume of 19 865.8 tonnes, were registered in Denmark. In Norway, Sweden, and Finland, 103 (856.8 tonnes), 307 (459.0 tonnes), and 75 (132.7 tonnes) products were registered, respectively. Use categories included intermediates, cleaning/washing agents, paints, lacquers and varnishes, surface treatments, cutting fluids, pH-regulation agents, impregnation materials, surface-active agents, corrosion inhibitors, process regulators, colouring agents, reprographic agents, lubricants and additives. Its use in consumer preparations was indicated for products registered in Norway and Sweden (SPIN, 2006; OECD, 2008). 1.3. Occurrence and exposure 1.3.1. Natural occurrence Diethanolamine is not known to occur as a natural product. 1.3.2. Occupational exposure Diethanolamine is present in water-based machining and grinding fluids (soluble oils, semi-synthetic and synthetic metalworking fluids) and has been detected in workplace air in the metal manufacturing industry. It was detected in bulk metalworking fluids at levels ranging from 4 to 5% (Kenyon et al., 1993). Recent exposure to diethanolamine can be inferred from studies showed dermal sensitivity among workers exposed to metalworking fluids (Geier et al., 2004a, b). Moreover, the presence of N-nitrosodiethanolamine in bulk fluids and in the urine of exposed workers may provide indirect evidence for the exposure to diethanolamine from these fluids (Ducos & Gaudin, 2003). According to the 1981–83 National Occupational Exposure Survey (NIOSH, 1999), 800 000 workers (many of whom were metalworkers) in the USA were potentially exposed to diethanolamine. The median air concentration of diethanolamine in nine machine shops in Finland was found to be 64 µg/m3 (Henriks-Eckerman et al., 2007). The presence of diethanolamine has also been reported in wetting fluids used in road paving. A level of 0.05 mg/m3 was detected in a stationary sample at a slurry machine discharging a bitumen emulsion containing 0.2% of the amine. All personal exposures were below the limit of detection (0.02 mg/m3) (Levin et al., 1994). In a study in Germany (1992–94), diethanolamine was detected in samples of metalworking fluids at a range of 0–44% (n = 69). The proportion of samples in which diethanolamine was present steadily declined from 90 to 60% over the study period (Pfeiffer et al., 1996). In 1996, 51 samples of cooling lubricant concentrates from the German market were analysed. Of these, six (12%) showed diethanolamine concentrations of more than 0.2%, with a maximum concentration reaching 0.85%. The occurrence of diethanolamine levels above 0.2% in these concentrates declined from 80% (1991–92), to 53% (1993), 25% (1994), 21% (1995), and 12% (1996). The reduction was due to a change in the composition of the coolant fluids that followed regulatory requirements in Germany (see Section 1.4). The detected residues above 0.2% were not due to the direct addition of diethanolamine as an ingredient, but to contamination by other components in the coolant fluids (Kaup et al., 1997). At a site in Germany, diethanolamine is produced in one production plant and is processed further within eight other operations and plants. Between January 2001 and December 2006, data on 53 workplace exposures covering all operations were collected by means of personal air sampling. The reported data are 8-hour time-weighted average (TWA) values for shifts. In the production plant, the highest value recorded was 0.026 mg/m3; at the filling stations, the maximum value recorded was 0.062 mg/m3; and the overall range of the measurements (53) was < 0.019–0.062 mg/m3 (OECD, 2008). 1.3.3. Environmental occurrence Production of diethanolamine and its wide use in industrial and consumer products may result in its release into the environment (Yordy & Alexander, 1981; Beyer et al., 1983; Environment Canada, 1995; Mathews et al., 1995; Knaak et al., 1997). (a) Air According to the Environmental Protection Agency (EPA) Toxics Release Inventory, air emissions of diethanolamine from 358 industrial facilities in 1994 were approximately 149 200 kg in the USA (US EPA, 1996). According to the National Pollutant Release Inventory (NPRI) of Canada, on-site releases of diethanolamine into the air from 74 facilities amounted to about 40 000 kg/year (Environment Canada, 1995). (b) Water Surface water discharges of diethanolamine from 358 industrial facilities in 1994 in the USA amounted to 100 350 kg, as reported in the Toxics Release Inventory (US EPA, 1996). On-site releases of diethanolamine (and its salts) to water from 74 facilities in Canada amounted to about 26 000 kg/year, as reported to the NPRI (Environment Canada, 1995). Because of the spectrum of industrial and consumer uses of diethanolamine and its miscibility with water, large amounts of the chemical can be discharged into wastewater and sewage in an unaltered form (Yordy & Alexander, 1981; Mathews et al., 1995). Diethanolamine was not detected in a study carried out in 1978 in any of the 21 samples taken from surface water in Japan (Japanese Department of Environmental Health, 1985). Diethanolamine was detected in German surface waters of the Rivers Elbe at 0.34–0.58 µg/L, Mulde at 2.54–4.6 µg/L, Neibe at 0.72–1.8 µg/L and Rhine at 0.30–0.59 µg/L (Pietsch et al., 2001; OECD, 2008). (c) Soil Releases of diethanolamine to the land and underground from 358 industrial facilities in the USA in 1994 (as reported to the Toxics Release Inventory) amounted to 77 050 kg and 36 850 kg, respectively (US EPA, 1996). Canadian on-site releases of diethanolamine (and its salts) to land and underground amounted to about 118 000 kg and 497 000 kg/year, respectively, as reported to the NPRI (Environment Canada, 1995). 1.3.4. Occurrence in personal care products Free diethanolamine is reported to be a contaminant in fatty acid-diethanolamine condensates (amides of coconut oil acid, oleic acid and lauric acid) at levels ranging from < 1% to nearly 19%. Diethanolamine also occurs as a contaminant in triethanolamine products (see Table 1.3). Table 1.3. Diethanolamine content of several condensates. Table 1.3 Diethanolamine content of several condensates. Potential exposure to diethanolamine in personal care products arises from the use of alkanolamides of diethanolamine, which are condensation products of diethanolamine and fatty acids (e.g. cocamide diethanolamine, a reaction product of diethanolamine and coconut oil-derived fatty acids). Cocamide diethanolamine, lauramide diethanolamine, linoleamide diethanolamine and oleamide diethanolamine are fatty acid diethanolamides that may contain 4r33% diethanolamine, and are present in cosmetics at concentrations of < 0.1–50% (Dea, 1986). Twenty shampoo products were analysed and 19 were found to contain diethanolamine at levels ranging from 140 to 15 200 ppm (Chou, 2005). In a substudy to assess skin absorption, a commercially available body lotion was found to contain 1.8 mg/g diethanolamine (Craciunescu et al., 2009). In a study of skin penetration, two representative shampoo formulations containing coconut diethanolamide at a concentration of 4% were found to contain 0.98% diethanolamine; two shampoos and a bubble bath containing 4.75% lauramide diethanolamine contained 0.25% diethanolamine; a leave-on emulsion containing 2% triethanolamine contained 0.008% diethanolamine; and an oxidative hair dye containing 4.7% lauramide diethanolamine contained 0.25% diethanolamine, while two other hair dye products containing 1.4% lauramide diethanolamine contained 0.075% diethanolamine (Brain et al., 2005). In a study of the penetration of cosmetic products through intact human skin, a shampoo containing cocamide diethanolamine was found to include 0.092% free diethanolamine, and a second shampoo containing lauramide diethanolamine included 0.28% free diethanolamine (Kraeling et al., 2004). 1.3.5. Detection in body fluids and daily exposure estimates After about 3 or 4 weeks of using a body lotion containing 1.8 mg/g diethanolamine, plasma concentrations of the compound in three volunteer subjects ranged from 3 to 7 nmol/mL (Craciunescu et al., 2009) [data were read from a graph]. Craciunescu et al., (2006) provided exposure estimates of 8–200 mg/kg per day from daily use of shampoo. An alternative calculation using a lower diethanolamine content in shampoo and lower skin penetration rates suggested that the exposure to diethanolamine for a 60-kg adult would be in the range of 0.2–2 µg/kg per day (Bailey, 2007). [The Working Group noted the large discrepancy in the estimated values between the two studies.] 1.4. Regulations and guidelines Occupational exposure limits and guidelines for diethanolamine are presented in Table 1.4. Table 1.4. Occupational exposure limits and guidelines for diethanolamine. Table 1.4 Occupational exposure limits and guidelines for diethanolamine. The Food and Drug Administration (FDA) permits the use of diethanolamine as a component of adhesives in food packaging, as an indirect food additive, as a component of uncoated or coated food contact surfaces of paper and paperboard for use with dry solid foods with no free fat or oil on the surface, and for use only as an adjuvant to control pulp absorbance and pitch content in the manufacture of paper and paperboard or for use only in paper mill boilers in the USA (FDA, 2010). A technical standard in Germany limits the level of diethanolamine in water-mixable cooling lubricants to 0.2% (Kaup et al., 1997). Go to: 2. Cancer in Humans The Working Group was not aware of any study that specifically examined the risk of cancer among persons exposed to diethanolamine. While diethanolamine is found in personal care products, no epidemiological studies evaluating human cancer in association with diethanolamine were identified. However, ethanolamines have been used as additives in metalworking fluids since the 1950s and are present in wetting fluids used in asphalt paving. Exposures to these agents occur as complex mixtures and there is a large database of studies on workers exposed in these occupational settings. In light of the complex mixtures, and concomitant occupational exposures, any observed elevations in risk cannot be specifically attributed to diethanolamine or to any other constituent of the complex mixtures. The Working Group, therefore, did not make a detailed evaluation of these studies. The data on metalworking fluids are reviewed below, although a formal evaluation by the Working Group is not provided. There are four major types of metalworking fluid: straight (generally mineral oils), soluble and semi-synthetic (straight oils diluted with water and additives) and synthetic (water and additives with no oil). [Exposure assessments for soluble and synthetic are often combined for analysis.] Ethanolamines — either diethanolamine or triethanolamine — are common additives to soluble, semi-synthetic and synthetic metal-working fluids (see Section 1). Diethanolamine may also be present as an unintended impurity of intended triethanolamine or fatty acid diethanolamide additives. Metalworking fluids are complex mixtures that may vary considerably, depending on the type of fluid and the additives used. These mixtures may contain many potential carcinogens and, in particular, potential exposure to N-nitrosodiethanolamine occurred in all of the studies considered. The use of diethanolamine and nitrites together as additives to metalworking fluids can lead to the formation of N-nitrosodiethanolamine. Therefore, workers in any study that noted exposure to N-nitrosodiethanolamine would also have been exposed to the diethanolamine from which the nitroso derivative was formed. In this review, only studies that included workers exposed to water-based (soluble, synthetic and semi-synthetic) metalworking fluids were included.

DIETHYL ADIPATE, N° CAS : 141-28-6, Nom INCI : DIETHYL ADIPATE, Nom chimique : Diethyl hexanedioate, N° EINECS/ELINCS : 205-477-0, Ses fonctions (INCI): Emollient : Adoucit et assouplit la peau, Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit, Agent d'entretien de la peau : Maintient la peau en bon état

Diethylamine; (Diethyl)amine; Diethylamine (deprecated[2]); diethyl amine; 2,2'-diethylamine cas no:109-89-7

DIETHYL CARBONATE, N° CAS : 105-58-8, Nom INCI : DIETHYL CARBONATE, Nom chimique : Carbonic acid, diethyl ester, N° EINECS/ELINCS : 203-311-1

DIETHYL ETHANOLAMINE, N° CAS : 100-37-8, Nom INCI : DIETHYL ETHANOLAMINE, Nom chimique : Ethanol, 2-(diethylamino), N° EINECS/ELINCS : 202-845-2. Ses fonctions (INCI): Régulateur de pH : Stabilise le pH des cosmétiques. Noms français : 2-Diethylaminoethanol; 2-HYDROXYTRIETHYLAMINE; BETA-DIETHYLAMINOETHYL ALCOHOL;DIETHYL ETHANOLAMINE DIETHYLAMINO-2 ETHANOL; Diethylaminoethanol; DIETHYLETHANOLAMINE; DIETHYLETHANOLAMINE (DEEA); Diéthylamino-2 éthanol; Diéthylaminoéthanol; N,N-DIETHYL-2-AMINOETHANOL; N,N-DIETHYLAMINOETHANOL; N,N-DIETHYLETHANOLAMINE. Noms anglais : 2-Diethylaminoethanol. Utilisation; Fabrication de produits organiques, agent dispersant. 2-(Diethylamino)ethanol 100-37-8 [RN] 2-(Diethylamino)ethanol [German] 2-(Diéthylamino)éthanol [French] 202-845-2 [EINECS] 2-Diethylaminoethanol 2-Hydroxytriethylamine 741863 [Beilstein] DEAE DEEA Diethylaminoethanol Ethanol, 2-(diethylamino)- [ACD/Index Name] KK5075000 N,N-DIETHYLETHANOLAMINE S6DL4M053U (2-HYDROXYETHYL)DIETHYLAMINE (DIETHYLAMINO)ETHANOL 1-(Diethylamino)ethanol 2-(Diethylamino)-ethanol 2-(Diethylamino)ethyl alcohol 2-(Diethylamino)ethyl cellulose 2-(DIETHYLAMONO)ETHANOL 2-(N,N-Diethylamino)ethanol 2-Diethylamino 2-diethylamino-ethanol 2-Diethylaminoethanol, 9CI 2-N-(Diethylamino)ethanol 2-N-Diethylaminoethanol 32954-58-8 [RN] 64346-24-3 [RN] 9013-34-7 [RN] DEAE|2-(DIETHYLAMINO)ETHAN-1-OL Dehydasal Di??thylamino??thanol Diaethylaminoaethanol Diaethylaminoaethanol [German] Diaethylaminoaethanol(german) Diethyl ethanolamine Diethyl ethanolamine;Diethylaminoethanol;2-Hydroxytriethylamine Diethyl(2-hydroxyethyl)amine Diethylamino ethanol Diethylamlnoethanol DIETHYLETHANOLAMINE Diethylmonoethanolamine ETHANOL,2-DIETHYLAMINO ipomeanol N-(2-Hydroxyethyl)diethylamine N-(Diethylamino)ethanol N, N-Diethylethanolamine N,N-DIETHYL ETHANOLAMINE N,N-Diethyl-2-aminoethanol N,N-Diethyl-2-hydroxyethylamine N,N-Diethylaminoethanol N,N-Diethylmonoethanolamine N,N-Diethyl-N-(β-hydroxyethyl)amine N,N-Diethyl-N-(β-hydroxyethyl)amine N-Diethylaminoethanol Pennad 150 Perdilaton Q2N2 & 2 [WLN] UN 2686 UNII:S6DL4M053U UNII-S6DL4M053U β-(Diethylamino)ethanol β-(Diethylamino)ethanol β-(diethylamino)ethyl alcohol β-(Diethylamino)ethyl alcohol β-Diethylaminoethanol β-Diethylaminoethyl alcohol β-hydroxytriethylamine β-Hydroxytriethylamine

DIETHYL SEBACATE, N° CAS : 110-40-7, Nom INCI : DIETHYL SEBACATE, Nom chimique : Diethyl sebacate, N° EINECS/ELINCS : 203-764-5. Emollient : Adoucit et assouplit la peau. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée.Agent d'entretien de la peau : Maintient la peau en bon état Solvant : Dissout d'autres substances

DIETHYL TOLUAMIDE, N° CAS : 134-62-3 / 26545-51-7, Nom INCI : DIETHYL TOLUAMIDE, Nom chimique : N,N-Diethyl-m-toluamide, N° EINECS/ELINCS : 205-149-7, Ses fonctions (INCI): Agent de protection de la peau : Aide à éviter les effets néfastes des facteurs externes sur la peau

Diethyl Sulfate Property of Diethyl sulfate Diethyl sulfate is moisture sensitive liquid. Heating can lead to release of irritating gases and vapors. Toxicity of Diethyl sulfate Diethyl sulfate is a strong alkylating agent which ethylates DNA and thus is genotoxic. According to the International Agency for Research on Cancer (IARC), as of 1999 there is not sufficient evidence for the carcinogenic properties of diethyl sulfate in humans, but there is in animals. Diethyl sulfate is classified as a Group 2A (probably carcinogenic to humans) carcinogen by the IARC. Preparation of Diethyl sulfate Diethyl sulfate can be prepared by absorbing ethylene into concentrated sulfuric acid or by fuming sulfuric acid into diethyl ether or ethanol. Properties of Diethyl sulfate Chemical formula C4H10O4S Molar mass 154.18 g·mol−1 Appearance Colorless liquid Density 1.2 g/mL Melting point −25 °C (−13 °F; 248 K) Boiling point 209 °C (408 °F; 482 K) (decomposes) Solubility in water decomposes in water Vapor pressure 0.29 mm Hg Magnetic susceptibility (χ) -86.8·10−6 cm3/mol Application of Diethyl sulfate Diethyl sulfate can be used as a reactant for the synthesis of: • Biologically active compounds such as bispyrazole, pyrazolopyrimidine and pyridine containing antipyrinyl moieties. • N-substituted-2-styryl-4(3H)-quinazolinones. • Ionic liquids with pyrrolidinium, piperidinium and morpholinium cations, having potential applications as electrolytes. Diethyl sulfate can also be used as an alkylating agent to synthesize 1-alkyl/aralkyl-2-(1-arylsufonylalkyl)benzimidazoles and an ionic liquid ethylmethylimidazole ethylsulfate. Diethyl sulfate is an alkyl sulfate. Diethyl sulfate appears as a clear colorless liquid with a peppermint odor. Burns, though may be difficult to ignite. Corrosive to metals and tissue. It is a potent alkylating agent. Flash point is 104° C (219° F) [Aldrich MSDS]. Diethyl Sulfate is a colorless, corrosive, oily liquid that darkens with age and has a faint peppermint odor. Diethyl sulfate is mainly used as an ethylating agent in organic synthesis and in the dye and textile manufacturing. Exposure to this substance results in severe irritation to the eyes, skin and respiratory tract. Diethyl Sulfate is a possible mutagen and is reasonably anticipated to be a human carcinogen based on evidence of carcinogenicity in experimental animals and may be associated with developing laryngeal cancer. After male CFE albino rats were administered 1 ml of a 5% (v/v) solution of diethyl sulfate in arachis oil by gavage or by intraperitoneal or subcutaneous injection, ethylmercapturic acid and a sulfoxide were identified as metabolites. Uses of Diethyl sulfate Diethyl sulfate is primarily used as an ethylating agent, and also as an accelerator in the sulfation of ethylene and in some sulfonations. Diethyl sulfate is also a chemical intermediate for ethyl derivatives of phenols, amines, and thiols, and as an alkylating agent. Diethyl sulfate is available as a technical grade product that contains 99.5% active ingredient or as a laboratory chemical with a purity of 95% to >98%. An analytical method for the determination of diethyl sulfate in air has been developed /using/ gas chromatography with a flame photometric detector. Hazards Summary of Diethyl sulfate Diethyl sulfate is used as an ethylating agent and as a chemical intermediate. No information is available on the acute (short-term), chronic (long-term), reproductive, or developmental effects of diethyl sulfate in humans. In an epidemiological study, an excess mortality rate from laryngeal cancer was associated with occupational exposure to high concentrations of diethyl sulfate. In one study, rats orally exposed to diethyl sulfate developed tumors in the forestomach. EPA has not classified diethyl sulfate with respect to potential carcinogenicity. The International Agency for Research on Cancer (IARC) has classified diethyl sulfate as a Group 2A, probable human carcinogen. The presence of moisture in a metal container of diethyl sulfate caused formation of sulfuric acid which reacted with the metal to release hydrogen which pressurized and exploded the container. This action promulgates standards of performance for equipment leaks of Volatile Organic Compounds (VOC) in the Synthetic Organic Chemical Manufacturing Industry (SOCMI). The intended effect of these standards is to require all newly constructed, modified, and reconstructed SOCMI process units to use the best demonstrated system of continuous emission reduction for equipment leaks of VOC, considering costs, non air quality health and environmental impact and energy requirements. Diethyl sulfate is produced, as an intermediate or a final product, by process units covered under this subpart. Listed as a hazardous air pollutant (HAP) generally known or suspected to cause serious health problems. The Clean Air Act, as amended in 1990, directs EPA to set standards requiring major sources to sharply reduce routine emissions of toxic pollutants. EPA is required to establish and phase in specific performance based standards for all air emission sources that emit one or more of the listed pollutants. Diethyl sulfate is included on this list. National Toxicology Program. Eleventh Report on Carcinogens (2005). The Report on Carcinogens is an informational scientific and public health document that identifies and discusses substances (including agents, mixtures, or exposure circumstances) that may pose a carcinogenic hazard to human health. Diethyl sulfate (64-67-5) is listed as reasonably anticipated to be a human carcinogen. Evidence for Carcinogenicity Evaluation: There is inadequate evidence for the carcinogenicity in humans of diethyl sulfate. There is sufficient evidence for the carcinogenicity of diethyl sulfate in experimental animals. Diethyl sulfate is probably carcinogenic to humans (2A). In making the overall evaluation, the Working Group took into account diethyl sulfate is a strong direct alkylating agent which ethylates DNA and that as a result, it is genotoxic in virtually all test systems examined including potent effects in somatic and germ cells of mammals exposed in vivo. Diethyl sulfate: reasonably anticipated to be a human carcinogen. In a historical cohort study of process workers, chemical mechanics, and refinery workers at a factory manufacturing isopropyl alcohol and ethanol by the strong acid process, a process which produces high concns of diethyl sulfate, excess mortality from upper respiratory (laryngeal) cancer was found among process workers. Diethyl sulfate induced unscheduled DNA synthesis in pollen of petunia hybrida. It induced chromosomal aberrations in meiotic cells and chlorophyll mutations in rice, ring chromosomes in Allium sativum root tips and anaphase and telophase aberrations in Papaver somniferum root meristemic cells. The dermal carcinogenicity of diethyl sulfate was evaluated in a group of 40 C3H/HeJ male mice painted 3 times/week for their lifespan on the skin of the back, with undiluted diethyl sulfate at an average dose of 0.0074 g/mouse/application. A negative control group of 40 animals was exposed to 0.0126 g acetone/mouse/application in the same manner as the treated group. All the treated mice were dead after 23 months of the study, 11 after 18 months, and 27 after one year. The first skin neoplasm was observed after 12 months of treatment, with a total of 21 animals developing malignant skin neoplasms. The total cancer incidence was 87.5% and the median latent periods for appearance of neoplasms and cancer were 15.7 and 16.2 months, respectively. No skin tumors were observed in the control group. The mutagenicity of diethyl sulfate was evaluated in the Chinese Hamster Ovary (CHO) Mutation test, both in the presence and absence of added metabolic activation by Aroclor-induced rat liver S9 fraction. Based on the results of preliminary toxicity determinations, diethyl sulfate, diluted with DMSO, was tested for mutagenicity at ranges of concentrations of 2.5-40x10(-3)% and 5-80x10(-3)% (v/v in DMSO) in the presence and absence of activation, respectively. All concentrations of diethyl sulfate tested caused a positive response in the tests both with and without activation. The ability of diethyl sulfate to induce sister chromatid exchanges (SCE) in Chinese hamster ovary (CHO) cells was evaluated in the absence of added metabolic activation. Based on preliminary toxicity tests, diethyl sulfate, diluted with DMSO, was tested at concentrations of 0, 0.00125, 0.0025, 0.0050, 0.010 or 0.020 % (v/v). A total of 15 cells/dose level were examined in all but the highest dose level tested since this dose level was toxic to the cells. There were statistically significant increases observed in the numbers of SCE/cell and SCE/chromosome relative to negative controls at concentrations of 0.0050 and 0.010% (p < 0.001, Student's t-test). A positive dose-response relationship was observed. The ability of diethyl sulfate to cause an increase in unscheduled DNA synthesis in rat liver cells was evaluated. Based on preliminary toxicity tests, diethyl sulfate, diluted in DMSO, was tested at concentrations of 0, 0.0001, 0.001, 0.003, 0.010, 0.030 or 0.100% (v/v). Cells were treated with test article for 2 hrs. Statistically significant increases in DNA synthesis relative to negative controls were observed at all tested concentrations using both values for radioactivity incorporation into either nuclei or DNA (p < 0.05 for concentrations of 0.001 and 0.100% and p < 0.001 for the remaining concentrations). A linear dose-response pattern was not observed although the cumulative responses observed over a wide range of concentrations suggested a significant biological effect. Diethyl sulfate's production and use as an ethylating agent for a wide variety of organic functional groups may result in its release to the environment through various waste streams. If released to air, a vapor pressure of 0.212 mm Hg at 25 °C indicates Diethyl sulfate will exist solely as a vapor in the ambient atmosphere. Vapor-phase Diethyl sulfate will be degraded in the atmosphere by reaction with photochemically-produced hydroxyl radicals; the half-life for this reaction in air is estimated to be 9 days. Diethyl sulfate is also degraded in the atmosphere by water and moisture and the half-life for this reaction is less than 1 day. If released to soil, Diethyl sulfate is expected to hydrolyze rapidly in moist soils. Adsorption, biodegradation, and volatilization from soil are not expected to be important fate processes because hydrolysis occurs rapidly. If released into water, Diethyl sulfate is expected to hydrolyze with an estimated half-life of 1.7 hours; ethanol and sulfuric acid have been identified as hydrolysis products. Volatilization, adsorption to suspended solids and sediments, biodegradation, and bioconcentration are not expected to be important fate processes in aquatic systems because of the rapid rate of hydrolysis. Occupational exposure to Diethyl sulfate may occur through inhalation and dermal contact with this compound at workplaces where Diethyl sulfate is produced or used in the synthesis of a variety of intermediates and products. Diethyl sulfate's production and use as an ethylating agent for a wide variety of organic functional groups(1-3) may result in its release to the environment through various waste streams. If released to water, Diethyl sulfate is expected to hydrolyze rapidly. A hydrolysis rate constant of 1.15X10-4/sec at 25 °C translates to a half-life of 1.7 hours at pH 7. The rate of hydrolysis will increase in both acidic and basic waters as the reaction is catalyzed under these conditions. Volatilization from water surfaces, adsorption to suspended solids and sediments, biodegradation, and bioconcentration are not expected to be important fate processes in aquatic systems because of hydrolysis. According to a model of gas/particle partitioning of semivolatile organic compounds in the atmosphere, Diethyl sulfate, which has a vapor pressure of 0.212 mm Hg at 25 °C, is expected to exist solely as a vapor in the ambient atmosphere. Vapor-phase Diethyl sulfate is degraded in the atmosphere by reaction with photochemically-produced hydroxyl radicals; the half-lives for this reaction in air is estimated to be about 9 days, calculated from its rate constant of 1.8X10-12 cu cm/molecule-sec at 25 °C. Diethyl sulfate also reacts rapidly with water in the atmosphere, with an estimated half-life of <1 day. Diethyl sulfate, present at 100 mg/l, achieved 89% of its theoretical BOD after 4 weeks using an activated sludge inoculum at 30 mg/l and the Japanese MITI test. The rate constant for the vapor-phase reaction of Diethyl sulfate with photochemically-produced hydroxyl radicals has been measured as 1.8X10-12 cu cm/molecule-sec at 25 °C. This corresponds to an atmospheric half-life of about 9 days at an atmospheric concentration of 5X10+5 hydroxyl radicals per cu cm. Experimental rate constants for the gas-phase reactions of Diethyl sulfate with ozone, <3.4X10-21 cu cm/mol-sec; ammonia, <1.4X10-21 cu cm/mol-sec; and water, <2.3X10-23 cu cm/mol-sec translate to atmospheric lifetimes of >12 yr, >9 yr, and <1 day, respectively. A measured hydrolysis rate constant of 1.15X10-4/sec for Diethyl sulfate in water at 25 °C translates to a half-life of 1.7 hrs at pH 7. The reaction is catalyzed under both acidic and basic conditions forming sulfuric acid and free ethanol. Based upon the rapid rate of hydrolysis for Diethyl sulfate in aqueous environments, bioconcentration in aquatic organisms is expected to be low. In 1989, total land releases of Diethyl sulfate in the US were estimated at approximately 114 kg and total air emissions were estimated as approximately 4 tons from 28 locations. Diethyl sulfate was qualitatively detected in the atmosphere of the Netherlands. In 1989, total air emissions of Diethyl sulfate in the U.S. were estimated at approximately 4 tons from 28 locations. NIOSH (NOES Survey 1981-1983) has statistically estimated that 2,261 workers (164 of these are female) are potentially exposed to Diethyl sulfate in the US. Occupational exposure to Diethyl sulfate may occur through inhalation and dermal contact with this compound at workplaces where Diethyl sulfate is produced or used. About Diethyl sulfate Diethyl sulfate is registered under the REACH Regulation and is manufactured in and / or imported to the European Economic Area, at ≥ 1 to < 10 tonnes per annum. Diethyl sulfate is used at industrial sites. Consumer Uses of Diethyl sulfate ECHA has no public registered data indicating whether or in which chemical products the substance might be used. ECHA has no public registered data on the routes by which Diethyl sulfate is most likely to be released to the environment. Article service life of Diethyl sulfate ECHA has no public registered data on the routes by which Diethyl sulfate is most likely to be released to the environment. ECHA has no public registered data indicating whether or into which articles the substance might have been processed. Widespread uses by professional workers ECHA has no public registered data indicating whether or in which chemical products the substance might be used. ECHA has no public registered data on the types of manufacture using Diethyl sulfate. ECHA has no public registered data on the routes by which Diethyl sulfate is most likely to be released to the environment. Formulation or re-packing of Diethyl sulfate ECHA has no public registered data indicating whether or in which chemical products the substance might be used. ECHA has no public registered data on the routes by which Diethyl sulfate is most likely to be released to the environment. Uses at industrial sites of Diethyl sulfate Diethyl sulfate is used in the following products: polymers. Diethyl sulfate has an industrial use resulting in manufacture of another substance (use of intermediates). Diethyl sulfate is used for the manufacture of: chemicals. Release to the environment of Diethyl sulfate can occur from industrial use: as an intermediate step in further manufacturing of another substance (use of intermediates). Manufacture of Diethyl sulfate ECHA has no public registered data on the routes by which Diethyl sulfate is most likely to be released to the environment. 1.1 Exposure data Diethyl sulfate is manufactured from ethylene and sulfuric acid. It is used principally as an intermediate (ethylating agent) in the manufacture of dyes, pigments and textile chemicals, and as a finishing agent in textile production. It is an obligatory intermediate in the indirect hydration (strong acid) process for the preparation of synthetic ethanol from ethylene. No data were available on levels of occupational exposure to diethyl sulfate. 1.2 Human carcinogenicity data One cohort study at a US isopropanol and ethanol manufacturing plant revealed an increased risk for laryngeal cancer. A subsequent case-control study nested in an expanded cohort at this plant indicated that the increased risk was related to exposure to sulfuric acid; the risk persisted even after exclusion of workers in the ethanol and isopropanol units. A cohort study from two US plants producing ethanol and isopropanol suggested an increased risk for cancers of the larynx, buccal cavity and pharynx, but not of the lung, in strong-acid workers. An association between estimated exposure to diethyl sulfate and risk for brain tumour was suggested in a study of workers at a US petrochemical plant. No measurement of exposure diethyl sulfate was available for the industrial processes investigated in the epidemiological studies. It is therefore difficult to assess the contribution of diethyl sulfate to the increased cancer risks. Furthermore, exposure to mists and vapours from strong inorganic acids, primarily sulfuric acid, may play a role in increasing these risks. 1.3 Animal carcinogenicity data Diethyl sulfate was tested for carcinogenicity by oral and subcutaneous administration in one strain of rats. After subcutaneous administration, a high incidence of malignant tumours occurred at the injection site. Following oral gavage of diethyl sulfate, forestomach tumours were observed. A low incidence of malignant tumours of the nervous system was observed in the same strain of rats after prenatal exposure. 1.4 Other relevant data Diethyl sulfate induced specific locus mutations in mouse germ-line cells. It was clastogenic in mice and newts, induced DNA damage in mice and rats and ethylated DNA in mice. Diethyl sulfate induced chromosomal aberrations and micronucleus formation in cultured human lymphocytes. It induced alkali-labile sites in cultured human leukocytes in one study. In cultured mammalian cells, diethyl sulfate induced chromosomal aberrations, micronucleus formation, sister chromatid exchange, forward mutation and DNA single-strand breaks; it also induced unscheduled DNA synthesis in primary cultures of rat hepatocytes. In single studies, diethyl sulfate did not induce aneuploidy or reciprocal translocation in Drosophila melanogaster but did induce sex-linked recessive lethal mutations and genetic crossing-over. In plant cells, diethyl sulfate induced chromosomal aberrations, mutation and unscheduled DNA synthesis. It induced reverse mutation and mitotic recombination in yeast. Diethyl sulfate induced mutation and DNA damage in bacteria. 1.5 Evaluation There is inadequate evidence for the carcinogenicity in humans of diethyl sulfate. There is sufficient evidence for the carcinogenicity in experimental animals of diethyl sulfate. Diethyl sulfate is a strong alkylating agent which ethylates DNA. As a result, it is genotoxic in virtually all test systems examined including induction of potent effects in somatic and germ cells of mammals exposed in vivo. Hazard Summary of Diethyl sulfate Diethyl sulfate is used as an ethylating agent and as a chemical intermediate. No information is available on the acute (short-term), chronic (long-term), reproductive, or developmental effects of diethyl sulfate in humans. In an epidemiological study, an excess mortality rate from laryngeal cancer was associated with occupational exposure to high concentrations of diethyl sulfate. In one study, rats orally exposed to diethyl sulfate developed tumors in the forestomach. EPA has not classified diethyl sulfate with respect to potential carcinogenicity. The International Agency for Research on Cancer (IARC) has classified diethyl sulfate as a Group 2A, probable human carcinogen. Uses of Diethyl sulfate Diethyl sulfate is primarily used as an ethylating agent, and also as an accelerator in the sulfation of ethylene and in some sulfonations. Diethyl sulfate is also a chemical intermediate for ethyl derivatives of phenols, amines, and thiols, and as an alkylating agent. Sources and Potential Exposure of Diethyl sulfate The most probable routes of exposure to diethyl sulfate are by dermal contact or inhalation during its production or use. Individuals may also be exposed to diethyl sulfate in the ambient environment from fugitive emissions. Physical Properties of Diethyl sulfate The chemical formula for diethyl sulfate is C4H10O4S, and its molecular weight is 154.19 g/mol. Diethyl sulfate occurs as a colorless, oily liquid that darkens with age and is practically insoluble with water. Diethyl sulfate has a faint ethereal or peppermint odor; the odor threshold has not been established. The vapor pressure for diethyl sulfate is 0.29 mm Hg at 25 °C, and its log octanol/water partition coefficient (log Kow) is 1.14. Diethyl sulfate Chemical Properties,Uses,Production Chemical Properties of Diethyl sulfate Diethyl sulfate is a colorless, oily liquid with a faint peppermint- like odor, which darkens with age (Budavari, 1996). It is miscible with alcohol and ether (O'Neil, 2006). At higher temperatures, DES rapidly decomposes into monoethyl sulfate and alcohol (NTP, 2011). Uses of Diethyl sulfate The primary use of diethyl sulfate is as a chemical intermediate (ethylating agent) in synthesis of ethyl derivatives of phenols, amines, and thiols; as an accelerator in the sulfation of ethylene; and in some sulfonation processes. It is used to manufacture dyes, pigments, carbonless paper, and textiles. It is an intermediate in the indirect hydration (strong acid) process for the preparation of synthetic ethanol from ethylene. Smaller quantities are used in household products, cosmetics, agricultural chemicals, pharmaceuticals, and laboratory reagents (IARC 1992, 1999, HSDB 2009). In 1966, it was used as a mutagen to create the Luther variety of barley (IARC 1974). Uses As an ethylating agent; as an accelerator in the sulfation of ethylene; intermediate in the production by one method of ethyl alcohol from ethylene and sulfuric acid Preparation of Diethyl sulfate Diethyl sulfate is produced from ethanol and sulfuric acid, from ethylene and sulfuric acid, or from diethyl ether and fuming sulfuric acid (Budavari, 1996). General Description of Diethyl sulfate A clear colorless liquid with a peppermint odor. Burns, though may be difficult to ignite. Corrosive to metals and tissue. Reactivity Profile of Diethyl sulfate The presence of moisture in a metal container of Diethyl sulfate caused the formation of sulfuric acid which reacts with the metal to release hydrogen which pressurized and exploded the container. Carcinogenicity of Diethyl sulfate Diethyl sulfate is reasonably anticipated to be a human carcinogenbased on sufficient evidence of carcinogenicity from studies in experimental animals. History of Diethyl sulfate Diethyl sulfate was studied contemporaneously with ether by German alchemist August Siegmund Frobenius in 1730, subsequently by French chemists Fourcroy in 1797 and Gay-Lussac in 1815. Swiss scientist Nicolas-Théodore de Saussure also studied it in 1807. In 1827, French chemist and pharmacist Félix-Polydore Boullay (1806-1835) along with Jean-Baptiste André Dumas noted the role of Diethyl sulfate in the preparation of diethyl ether from sulfuric acid and ethanol. Further studies by the German chemist Eilhard Mitscherlich and the Swedish chemist Jöns Berzelius suggested sulfuric acid was acting as a catalyst, this eventually led to the discovery of sulfovinic acid as an intermediate in the process. The advent of electrochemistry by Italian physicist Alessandro Volta and English chemist Humphry Davy in the 1800s confirmed ether and water were formed by the reaction of sub-stoichiometric amounts of sulfuric acid on ethanol and that sulfovinic acid was formed as an intermediate in the reaction. Production of Diethyl sulfate Ethanol was produced primarily by the sulfuric acid hydration process in which ethylene is reacted with sulfuric acid to produce Diethyl sulfate followed by hydrolysis, but this method has been mostly replaced by direct hydration of ethylene. Diethyl sulfate can be produced in a laboratory setting by reacting ethanol with sulfuric acid under a gentle boil, while keeping the reaction below 140 °C. The sulfuric acid must be added dropwise or the reaction must be actively cooled because the reaction itself is highly exothermic. CH3CH2OH + H2SO4 → CH3-CH2-O-SO3H + H2O If the temperature exceeds 140 °C, the Diethyl sulfate product tends to react with residual ethanol starting material, producing diethyl ether. If the temperature exceeds 170 °C in a considerable excess of sulfuric acid, the Diethyl sulfate breaks down into ethylene and sulfuric acid. Reactions of Diethyl sulfate The mechanism of the formation of Diethyl sulfate, diethyl ether, and ethylene is based on the reaction between ethanol and sulfuric acid, which involves protonation of the ethanolic oxygen to form the[vague] oxonium ion. Diethyl sulfate accumulates in hair after chronic alcohol consumption and its detection can be used as a biomarker for alcohol consumption. Salts Diethyl sulfate can exist in salt forms, such as sodium Diethyl sulfate, potassium Diethyl sulfate, and calcium Diethyl sulfate. The salt can be formed by adding the according carbonate, or bicarbonate salt. As an example, Diethyl sulfate and potassium carbonate forms potassium Diethyl sulfate and potassium bicarbonate. Ethyl glucuronide and diethyl sulfate are minor metabolites of alcohol that are found in various body fluids and also in human hair. Ethyl glucuronide is formed by the direct conjugation of ethanol and glucuronic acid through the action of a liver enzyme. Diethyl sulfate is formed directly by the conjugation of ethanol with a sulfate group. These compounds are water soluble and can be used as direct alcohol biomarkers. Fatty acid ethyl esters are also direct markers of alcohol abuse because they are formed due to the chemical reaction between fatty acids and alcohol. Fatty acid ethyl esters are formed primarily in the liver and pancreas and then are released into the circulation. These compounds are also incorporated into hair follicles through sebum and can be used as a biomarker of alcohol abuse.

SYNONYMS Diethylamino hydroxybenzoyl hexyl benzoate, Hexyl 2-[4-(diethylamino)-2-hydroxybenzoyl]benzoate CAS NO:302776-68-7

Diethylaminoethanol; 2-Dietilaminoetanol; 2-Diéthylaminoéthanol; 2-Diethylaminoethanol; 2-Hydroxytriethylamine; 2-N,N-diethylaminoethanol; beta-diethylaminoethanol; beta-hydroxytriethylamine; diethyl(2-hydroxyethyl)amine; Diethylaminoethanol; Diethylethanolamine; DEAE; N-diethylaminoethanol; N,N-Diethyl-2-hydroxyethylamine; N,N-Diethylethanolamine; N,N-diethyl-N-(beta-hydroxyethyl) Amine CAS NO:100-37-8

DIETHYLAMINOETHANOL Diethylaminoethanol Chemical synonyms: 2-Diethylaminoethanol; N,N-diethylethanolamine; 2-Diethylaminoethyl alcohol; Diethyl-(2-hydroxyethyl)amine, 2-; DEAE Product description Diethylaminoethanol (DEAE) is a clear liquid. It is used as a neutralizing amine for boiler water, coatings, etc. Diethylaminoethanol (DEAE) is used as neutralizing agent and CO2 scavenger in boiler water. The ideal vapor pressure and vapor-liquid distribution properties of DEAE make it the best choice for pH adjustment of process water. Beyond its application in the water treatment segment, DEAE is also used as a neutralizing amine for indrustrial coatings and an intermediate for various surfactants. Diethylaminoethanol Chemical synonyms: 2-Diethylaminoethanol; N,N-diethylethanolamine; 2-Diethylaminoethyl alcohol; Diethyl-(2-hydroxyethyl)amine, 2-; DEAE Product description Diethylaminoethanol (DEAE) is a clear liquid. It is used as a neutralizing amine for boiler water, coatings, etc. Diethylaminoethanol (DEAE) is used as neutralizing agent and CO2 scavenger in boiler water. The ideal vapor pressure and vapor-liquid distribution properties of DEAE make it the best choice for pH adjustment of process water. Beyond its application in the water treatment segment, DEAE is also used as a neutralizing amine for indrustrial coatings and an intermediate for various surfactants. Diethylaminoethanol Chemical synonyms: 2-Diethylaminoethanol; N,N-diethylethanolamine; 2-Diethylaminoethyl alcohol; Diethyl-(2-hydroxyethyl)amine, 2-; DEAE Product description Diethylaminoethanol (DEAE) is a clear liquid. It is used as a neutralizing amine for boiler water, coatings, etc. Diethylaminoethanol (DEAE) is used as neutralizing agent and CO2 scavenger in boiler water. The ideal vapor pressure and vapor-liquid distribution properties of DEAE make it the best choice for pH adjustment of process water. Beyond its application in the water treatment segment, DEAE is also used as a neutralizing amine for indrustrial coatings and an intermediate for various surfactants. Diethylaminoethanol Chemical Properties,Uses,Production Chemical Properties colourless liquid Physical properties Colorless, hygroscopic liquid with a nauseating, ammonia-like odor. Experimentally determined detection and recognition odor threshold concentrations were 50 μg/m3 (11 ppbv) and 190 μg/m3 (40 ppbv), respectively (Hellman and Small, 1974). Uses Water-soluble salts; textile softeners; antirust formulations; fatty acid derivatives; pharmaceuticals; curing agent for resins; emulsifying agents in acid media; organic synthesis. Uses Anticorrosive agent; chemical intermediate for the production of emulsifiers, detergents, solubilizers, cosmetics, drugs, and textile finishing agents Definition ChEBI: A member of the class of ethanolamines that is aminoethanol in which the hydrogens of the amino group are replaced by ethyl groups. Production Methods 2-Diethylaminoethanol (DEAE) is a tertiary amine produced by reaction of ethylene oxide or ethylene chlorhydrin and diethylamine (RTECS 1988). Itokazu (1987) has modified this process for manufacture of DEAE without eventual discoloration. Production in this country exceeds 2866 pounds per year (HSDB 1988). General Description A colorless liquid. Flash point 103-140°F. Less dense than water . Vapors heavier than air. Produces toxic oxides of nitrogen during combustion. Causes burns to the skin, eyes and mucous membranes. Air & Water Reactions Flammable. Soluble in water. Diethylaminoethanol is sensitive to moisture. Slowly hydrolyzes. Reactivity Profile Diethylaminoethanol is an aminoalcohol. Amines are chemical bases. They neutralize acids to form salts plus water. These acid-base reactions are exothermic. The amount of heat that is evolved per mole of amine in a neutralization is largely independent of the strength of the amine as a base. Amines may be incompatible with isocyanates, halogenated organics, peroxides, phenols (acidic), epoxides, anhydrides, and acid halides. Flammable gaseous hydrogen is generated by amines in combination with strong reducing agents, such as hydrides. Diethylaminoethanol can react with strong oxidizers and acids. Carcinogenicity DEAE was not mutagenic or clastogenic in a variety of in vitro and in vivo assays. The 2003 ACGIH threshold limit valuetime- weighted average (TLV-TWA) for 2- diethylaminoethanol is 2 ppm (9.6mg/m3) with a notation for skin absorption. Environmental Fate DEAE, when compared with other amino alcohols, was observed to be biologically undecomposable in an experiment using activated sludge (HSDB 1988). Metabolism The absorption of DEAE (administered orally as DEAE acid malate or 'Cerebrol') in healthy adult rats is very rapid, reaching a peak plasma level in 30 min (Bismut et al 1986). The biological half-life is 3.5 h with 39% of the excreted product appearing in the urine after 48 h (Bismut et al 1986). In an earlier study, Schulte et al (1972) demonstrated that in rats, following a single oral dose, excretion occurs mainly through the kidneys with 37-59% being eliminated in the first 24 h. After 48 h, elimination was independent of dose. The brain and spinal cord showed the highest concentration after 7 d. Metabolites produced were observed to be diethylaminoethanol N-oxide, diethylaminoacetic acid, and ethylaminoethanol. Diethylaminoethanol Preparation Products And Raw materials ChEBI Ontology Outgoing 2-diethylaminoethanol (CHEBI:52153) has functional parent ethanolamine (CHEBI:16000) 2-diethylaminoethanol (CHEBI:52153) has parent hydride triethylamine (CHEBI:35026) 2-diethylaminoethanol (CHEBI:52153) is a ethanolamines (CHEBI:23981) 2-diethylaminoethanol (CHEBI:52153) is a primary alcohol (CHEBI:15734) 2-diethylaminoethanol (CHEBI:52153) is a tertiary amino compound (CHEBI:50996) Incoming chloroprocaine (CHEBI:3636) has functional parent 2-diethylaminoethanol (CHEBI:52153) dicyclomine (CHEBI:4514) has functional parent 2-diethylaminoethanol (CHEBI:52153) oxybuprocaine (CHEBI:309594) has functional parent 2-diethylaminoethanol (CHEBI:52153) procaine (CHEBI:8430) has functional parent 2-diethylaminoethanol (CHEBI:52153) Human Health 2-Diethylaminoethanol was rapidly absorbed via the oral route. It is presumably absorbed by dermal and inhalation routes of administration. In the rat it was widely distributed to many tissues. It was primarily excreted unchanged via the urine in rats. Excretion via the feces was also observed in rats, but to a lesser extent. Urinary excretion was also reported in humans. The major metabolites in rats were reported to be diethylaminoacetic acid and diethyl-(2- hydroxyethyl)-amino-oxide. The LD50 for the rat after oral administration was 1320 mg/kg bw. The main clinical signs described were apathy and dyspnea. After inhalation of vapors of 2-diethylaminoethanol an LC50 of ca. 4600 mg/m3/4 hour was estimated in rats using Haber’s rule. Severe signs of irritation were observed, e.g. mucous membrane irritation and dyspnea. A dermal LD50 in guinea pigs was reported to be ca. 885 mg/kg bw. 2-Diethylaminoethanol was corrosive to the skin of rabbits; since the pH was measured to be 11.5 (100 g/l) at 20°C, the corrosive effects are not surprising. The potential for severe damage to the eyes can be expected based on the animal studies available and on the pH. 2-Diethylaminoethanol was not sensitizing to the skin in studies with guinea pigs. Repeated exposure of rats to 2-diethylaminoethanol vapors (up to 365 mg/m3) for 14 weeks caused local toxicity (irritation) at the site of contact, namely, the upper respiratory tract and the eyes; however, systemic toxicity was not observed (NOAEC, systemic toxicity, 365 mg/m3 or 76 ppm). After inhalation exposure, the main symptom described was respiratory irritation which led to noises called rales and irritation of the eyes. The LOAEC for local toxicity (irritation) to the respiratory tract was 120 mg/m3 (25 ppm) and the NOAEC for local toxicity was 53 mg/m3 (10 ppm) based on histopathological effects in the nasal cavity. However, since an effect (rales) was seen at the lowest concentration a NOEC was not reached. 2-Diethylaminoethanol gave no evidence of in vitro mutagenic activity nor in vivo clastogenic potential. Repeated exposure of rats to 2-diethylaminoethanol vapors (365 mg/m3) for 14 weeks did not cause any adverse effects on the reproductive organs when administered by inhalation. In pregnant rats even the highest concentration tested of 486 mg/m3, which already produced maternally toxic effects, did not lead to adverse developmental effects. In a limited study, 2-diethylaminoethanol was not carcinogenic to rats when given by feed (tested up to ca. 50-400 mg/kg/d). An odor threshold of 0.011 ppm (approx. 0.053 mg/mg3) has been reported. In a laboratory worker short-time exposure to approx. 100 ppm (480 mg/m3) 2-diethylaminoethanol caused nausea and vomiting. Subjects exposed to 2-diethylaminoethanol vapor by humidified air in office buildings complained about eye, nose and throat irritation, dizziness, nausea and vomiting. Also several cases of asthma were observed. However, these symptoms were more consistent with reactive airway dysfunction syndrome than with an allergic respiratory reaction. In one case detectable amounts of 2-diethylaminoethanol were 0.05 and 0.04 mg/m3. Environment 2-diethylaminoethanol is a colourless – light yellowish organic liquid. The hygroscopic substance is miscible with water in all proportions, has a vapor pressure of about 1.8 hPa at 20 °C. The density is 0.885 g/cm³. Melting point and boiling point are – 68 °C and 162-163 °C (at 1013 hPa) respectively. The distribution of the substance between the compartments of air, biota, sediment, soil and water was calculated according to Mackay Level I. The non-charged molecule distributes mainly to the water (99.1 %). A soil adsorption coefficient (KOC) of 5.98 was estimated for 2-diethylaminoethanol (DEAE). This Koc value suggests that this compound would be mobile in soil and adsorption to suspended solids would not be important. From the pKa-value of 9.87 it can be assumed that under environmental conditions the substance is available as a cation. Therefore, binding of the substance to the matrix of soils with high capacities for cation exchange (e.g. clay) cannot be excluded. However, no data was available for ionic-ionic interactions in soil. The calculated Henry’s law constant (3.16*10-4 Pa m³ mol-1 at 25 °C) and complete water solubility of 2-diethylaminoethanol suggest that volatilization from water would not be an important fate process. The substance has no considerable potential for bioaccumulation (logKow = 0.21, measured). The compound is readily biodegradable (OECD 301 A, 95% after 22 days 10d-window fulfilled). The EC20 (30 min) for activated sludge was determined to be >1000 mg/l. The photodegradation rate in the atmosphere is fast under environmental conditions (50% after 3.9 hours). The following aquatic effect concentrations are available: Leuciscus idus LC50 (96 h) = 147 mg/l (nominal concentration). The toxic effect may be (partly) due to the high pH of the non-neutralized test solutions, since the pH adjusted 1000 mg/l dose group tolerated the substance for 96 h without mortality. Pimephales promelas LC50(96 h) = 1780 mg/l (measured concentration, adjustment of pH) Daphnia magna: EC50 (48 h) = 83.6 mg/l (nominal concentration) (toxicity due to pH effects cannot be excluded) Daphnia magna EC50 (48 h) = 165 mg/l (nominal concentration, adjustment of pH) Scenedesmus subspicatus: ErC50 = 44 mg/l, with a NOEC of 5 mg/l (corresponding values for biomass are 30 and 5 mg/l respectively; nominal concentration). Using the aquatic toxic effect on the most sensitive species, Scenedesmus subspicatus, of 44 mg/l for the endpoint growth rate (30 mg/l endpoint biomass) a PNECaqua of 44 µg/l is derived by applying an assessment factor of 1000. This factor is justified, because only short-term toxicity values were available. The following terrestrial effect concentration was reported: Chrysanthemum morifolium cultivar "Indianapolis white" EC50 (22 d) = 0.12 mg/l (in the nutrient solution; endpoint: chlorosis; nominal concentration). However, no PNECsoil can be derived from this result as no soil concentration is given. Exposure The production volume of this chemical at BASF, Germany, was more than 1000 tons in 2000. No information about the worldwide production volume is available. The organic compound is used for the synthesis of pharmaceuticals and as a catalyst in the synthesis of polymers in the chemical industry. It is also used as a pH stabilizer. According to Swiss, Danish and Swedish Products Registers and the Hazardous Substances Data Bank, 2-diethylaminoethanol is contained in a large number of products. Some of them may be available to consumers. Releases into the environment are likely to occur during the production and processing of 2-diethylaminoethanol as an intermediate, as well as from the use of the substance itself and use of products containing the substance. Assuming worst case conditions, less than 9.5 kg of 2-diethylaminoethanol per day were released into the Rhine from an industrial site. During production and internal processing, less than 25 kg/a were emitted into the air from the same production site. From the reported use in consumer products, it can be concluded that most of the 2- diethylaminoethanol is released into wastewater, but part of it may also be released into the atmosphere. 2-Diethylaminoethanol has been reported to be readily absorbed via the gastrointestinal tract in humans and rats (Rosenberg et al, 1949; Schulte et al., 1972). On the basis of the physico-chemical properties of a saturated aqueous 2-diethylaminoethanol solution, a skin penetration rate of 3.44 mg/cm2 per hour was estimated for human skin, and therefore, the resulting body burden from exposure to 5 ml/m3 (the current MAK value) of 2-diethylaminoethalol by inhalation for 8 hours could potentially be increased by an additional three-fold factor via dermal absorption (FiserovaBergerova et al., 1990). However, this model was suspected to be too conservative and likely to overestimate percutaneous penetration (Guy and Russell, 1993). Absorption via inhalation has been mentioned (Toren, 1994), but the primary literature was not available for an assessment. In a limited study with humans (Rosenberg et al, 1949), the plasma concentration peaked 3 hours after an oral administration of 5.6 g of 2-diethylaminoethanol-HCl, but was almost undetectable after 8 hours. About 25 % of the 2-diethylaminoethanol was excreted unchanged in the urine within 48 hours. Similar excretion results were observed after intravenous administration. In the same publication it was reported that 2-diethylaminoethanol-HCl given to dogs by intravenous infusion (71 mg/kg bw) , distributed rapidly. Three hours after infusion the level of 2-diethylaminoethanol was higher in the tissues examined (muscle, heart, brain, lung, liver and spleen) than in the plasma. In a gavage study with rats (Schulte et al., 1972), 14C-labeled-2-diethylaminoethanol-HCl was reported to be rapidly absorbed into the blood stream (with a dose of 68 mg/kg the maximum concentration in the blood was reached in 30 minutes and with 679 mg/kg it was reached within 1 hour). Elimination occurred primarily via the kidney. Elimination via exhalation and the feces played only minor role. The kinetics of urinary elimination was affected by the dose. In this regard, by 6 hours after the application of a 679 mg/kg bw dose 40 % was eliminated in the urine, and by 24 hours after application 58.5% was eliminated. When a 68 mg/kg dose was given, then after 6 and 24 hours 17.5 % and 37.4% were excreted via the urine, respectively. In the experiment with 679mg/kg 2-diethylaminoethanol, 90 % of the test substance had been eliminated via the urine 10 days after treatment. Some radioactivity was still detectable in the urine 40 days after treatment. 2- Diethylaminoethanol was predominantly (> 60 %) excreted unchanged over the first 96 hours. In the same period, the following metabolites were seen based on the recovery of radioactive compounds: 2-ethylaminoethanol (ca. 1 %), phosphoric acid-mono-(2-diethylaminoethylester) (2- 8 %), diethylaminoacetic acid (ca. 10 %) and the N-oxide of 2-diethylaminoethanol (ca. 15 - 19 %). Incorporation into phospholipids was observed. In this study, autoradiography indicated that 2- diethylaminoethanol was widely distributed throughout the body after gavaging. 2- Diethylaminoethanol was concentrated in the liver, reaching a maximum at 7 hours, but thereafter, it decreased. Initially, the central nervous system showed very low levels of activity, but by day 7 it had increased. For the oral dose of 679 mg/kg the biological half-life was 19 hours and for the 67.9mg/kg dose it was 36 hours. In a separate study 14C-labeled-2-diethylaminoethanol-HCl was given to rats by intravenous injection at doses of 2.9 µmol/rat (ca. 1.94 mg/kg bw) (Michelot et al., 1981). Cumulative excretion of 19.9 and 42.2% of the radioactivity in the urine was observed after 24 and 48 hours, respectively. Additionally, 8.5 and 29.5% of the radioactivity was excreted via the feces during the same time interval. Excretion via the bile was only measured over the first 6 hours, and was reported to be 5 %. Diethylaminoethanol Chemical synonyms: 2-Diethylaminoethanol; N,N-diethylethanolamine; 2-Diethylaminoethyl alcohol; Diethyl-(2-hydroxyethyl)amine, 2-; DEAE Product description Diethylaminoethanol (DEAE) is a clear liquid. It is used as a neutralizing amine for boiler water, coatings, etc. Diethylaminoethanol (DEAE) is used as neutralizing agent and CO2 scavenger in boiler water. The ideal vapor pressure and vapor-liquid distribution properties of DEAE make it the best choice for pH adjustment of process water. Beyond its application in the water treatment segment, DEAE is also used as a neutralizing amine for indrustrial coatings and an intermediate for various surfactants. Diethylaminoethanol Chemical synonyms: 2-Diethylaminoethanol; N,N-diethylethanolamine; 2-Diethylaminoethyl alcohol; Diethyl-(2-hydroxyethyl)amine, 2-; DEAE Product description Diethylaminoethanol (DEAE) is a clear liquid. It is used as a neutralizing amine for boiler water, coatings, etc. Diethylaminoethanol (DEAE) is used as neutralizing agent and CO2 scavenger in boiler water. The ideal vapor pressure and vapor-liquid distribution properties of DEAE make it the best choice for pH adjustment of process water. Beyond its application in the water treatment segment, DEAE is also used as a neutralizing amine for indrustrial coatings and an intermediate for various surfactants. Diethylaminoethanol Chemical synonyms: 2-Diethylaminoethanol; N,N-diethylethanolamine; 2-Diethylaminoethyl alcohol; Diethyl-(2-hydroxyethyl)amine, 2-; DEAE Product description Diethylaminoethanol (DEAE) is a clear liquid. It is used as a neutralizing amine for boiler water, coatings, etc. Diethylaminoethanol (DEAE) is used as neutralizing agent and CO2 scavenger in boiler water. The ideal vapor pressure and vapor-liquid distribution properties of DEAE make it the best choice for pH adjustment of process water. Beyond its application in the water treatment segment, DEAE is also used as a neutralizing amine for indrustrial coatings and an intermediate for various surfactants. Diethylaminoethanol Chemical Properties,Uses,Production Chemical Properties colourless liquid Physical properties Colorless, hygroscopic liquid with a nauseating, ammonia-like odor. Experimentally determined detection and recognition odor threshold concentrations were 50 μg/m3 (11 ppbv) and 190 μg/m3 (40 ppbv), respectively (Hellman and Small, 1974). Uses Water-soluble salts; textile softeners; antirust formulations; fatty acid derivatives; pharmaceuticals; curing agent for resins; emulsifying agents in acid media; organic synthesis. Uses Anticorrosive agent; chemical intermediate for the production of emulsifiers, detergents, solubilizers, cosmetics, drugs, and textile finishing agents Definition ChEBI: A member of the class of ethanolamines that is aminoethanol in which the hydrogens of the amino group are replaced by ethyl groups. Production Methods 2-Diethylaminoethanol (DEAE) is a tertiary amine produced by reaction of ethylene oxide or ethylene chlorhydrin and diethylamine (RTECS 1988). Itokazu (1987) has modified this process for manufacture of DEAE without eventual discoloration. Production in this country exceeds 2866 pounds per year (HSDB 1988). General Description A colorless liquid. Flash point 103-140°F. Less dense than water . Vapors heavier than air. Produces toxic oxides of nitrogen during combustion. Causes burns to the skin, eyes and mucous membranes. Air & Water Reactions Flammable. Soluble in water. Diethylaminoethanol is sensitive to moisture. Slowly hydrolyzes. Reactivity Profile Diethylaminoethanol is an aminoalcohol. Amines are chemical bases. They neutralize acids to form salts plus water. These acid-base reactions are exothermic. The amount of heat that is evolved per mole of amine in a neutralization is largely independent of the strength of the amine as a base. Amines may be incompatible with isocyanates, halogenated organics, peroxides, phenols (acidic), epoxides, anhydrides, and acid halides. Flammable gaseous hydrogen is generated by amines in combination with strong reducing agents, such as hydrides. Diethylaminoethanol can react with strong oxidizers and acids. Carcinogenicity DEAE was not mutagenic or clastogenic in a variety of in vitro and in vivo assays. The 2003 ACGIH threshold limit valuetime- weighted average (TLV-TWA) for 2- diethylaminoethanol is 2 ppm (9.6mg/m3) with a notation for skin absorption. Environmental Fate DEAE, when compared with other amino alcohols, was observed to be biologically undecomposable in an experiment using activated sludge (HSDB 1988). Metabolism The absorption of DEAE (administered orally as DEAE acid malate or 'Cerebrol') in healthy adult rats is very rapid, reaching a peak plasma level in 30 min (Bismut et al 1986). The biological half-life is 3.5 h with 39% of the excreted product appearing in the urine after 48 h (Bismut et al 1986). In an earlier study, Schulte et al (1972) demonstrated that in rats, following a single oral dose, excretion occurs mainly through the kidneys with 37-59% being eliminated in the first 24 h. After 48 h, elimination was independent of dose. The brain and spinal cord showed the highest concentration after 7 d. Metabolites produced were observed to be diethylaminoethanol N-oxide, diethylaminoacetic acid, and ethylaminoethanol. Diethylaminoethanol Preparation Products And Raw materials ChEBI Ontology Outgoing 2-diethylaminoethanol (CHEBI:52153) has functional parent ethanolamine (CHEBI:16000) 2-diethylaminoethanol (CHEBI:52153) has parent hydride triethylamine (CHEBI:35026) 2-diethylaminoethanol (CHEBI:52153) is a ethanolamines (CHEBI:23981) 2-diethylaminoethanol (CHEBI:52153) is a primary alcohol (CHEBI:15734) 2-diethylaminoethanol (CHEBI:52153) is a tertiary amino compound (CHEBI:50996) Incoming chloroprocaine (CHEBI:3636) has functional parent 2-diethylaminoethanol (CHEBI:52153) dicyclomine (CHEBI:4514) has functional parent 2-diethylaminoethanol (CHEBI:52153) oxybuprocaine (CHEBI:309594) has functional parent 2-diethylaminoethanol (CHEBI:52153) procaine (CHEBI:8430) has functional parent 2-diethylaminoethanol (CHEBI:52153) Human Health 2-Diethylaminoethanol was rapidly absorbed via the oral route. It is presumably absorbed by dermal and inhalation routes of administration. In the rat it was widely distributed to many tissues. It was primarily excreted unchanged via the urine in rats. Excretion via the feces was also observed in rats, but to a lesser extent. Urinary excretion was also reported in humans. The major metabolites in rats were reported to be diethylaminoacetic acid and diethyl-(2- hydroxyethyl)-amino-oxide. The LD50 for the rat after oral administration was 1320 mg/kg bw. The main clinical signs described were apathy and dyspnea. After inhalation of vapors of 2-diethylaminoethanol an LC50 of ca. 4600 mg/m3/4 hour was estimated in rats using Haber’s rule. Severe signs of irritation were observed, e.g. mucous membrane irritation and dyspnea. A dermal LD50 in guinea pigs was reported to be ca. 885 mg/kg bw. 2-Diethylaminoethanol was corrosive to the skin of rabbits; since the pH was measured to be 11.5 (100 g/l) at 20°C, the corrosive effects are not surprising. The potential for severe damage to the eyes can be expected based on the animal studies available and on the pH. 2-Diethylaminoethanol was not sensitizing to the skin in studies with guinea pigs. Repeated exposure of rats to 2-diethylaminoethanol vapors (up to 365 mg/m3) for 14 weeks caused local toxicity (irritation) at the site of contact, namely, the upper respiratory tract and the eyes; however, systemic toxicity was not observed (NOAEC, systemic toxicity, 365 mg/m3 or 76 ppm). After inhalation exposure, the main symptom described was respiratory irritation which led to noises called rales and irritation of the eyes. The LOAEC for local toxicity (irritation) to the respiratory tract was 120 mg/m3 (25 ppm) and the NOAEC for local toxicity was 53 mg/m3 (10 ppm) based on histopathological effects in the nasal cavity. However, since an effect (rales) was seen at the lowest concentration a NOEC was not reached. 2-Diethylaminoethanol gave no evidence of in vitro mutagenic activity nor in vivo clastogenic potential. Repeated exposure of rats to 2-diethylaminoethanol vapors (365 mg/m3) for 14 weeks did not cause any adverse effects on the reproductive organs when administered by inhalation. In pregnant rats even the highest concentration tested of 486 mg/m3, which already produced maternally toxic effects, did not lead to adverse developmental effects. In a limited study, 2-diethylaminoethanol was not carcinogenic to rats when given by feed (tested up to ca. 50-400 mg/kg/d). An odor threshold of 0.011 ppm (approx. 0.053 mg/mg3) has been reported. In a laboratory worker short-time exposure to approx. 100 ppm (480 mg/m3) 2-diethylaminoethanol caused nausea and vomiting. Subjects exposed to 2-diethylaminoethanol vapor by humidified air in office buildings complained about eye, nose and throat irritation, dizziness, nausea and vomiting. Also several cases of asthma were observed. However, these symptoms were more consistent with reactive airway dysfunction syndrome than with an allergic respiratory reaction. In one case detectable amounts of 2-diethylaminoethanol were 0.05 and 0.04 mg/m3. Environment 2-diethylaminoethanol is a colourless – light yellowish organic liquid. The hygroscopic substance is miscible with water in all proportions, has a vapor pressure of about 1.8 hPa at 20 °C. The density is 0.885 g/cm³. Melting point and boiling point are – 68 °C and 162-163 °C (at 1013 hPa) respectively. The distribution of the substance between the compartments of air, biota, sediment, soil and water was calculated according to Mackay Level I. The non-charged molecule distributes mainly to the water (99.1 %). A soil adsorption coefficient (KOC) of 5.98 was estimated for 2-diethylaminoethanol (DEAE). This Koc value suggests that this compound would be mobile in soil and adsorption to suspended solids would not be important. From the pKa-value of 9.87 it can be assumed that under environmental conditions the substance is available as a cation. Therefore, binding of the substance to the matrix of soils with high capacities for cation exchange (e.g. clay) cannot be excluded. However, no data was available for ionic-ionic interactions in soil. The calculated Henry’s law constant (3.16*10-4 Pa m³ mol-1 at 25 °C) and complete water solubility of 2-diethylaminoethanol suggest that volatilization from water would not be an important fate process. The substance has no considerable potential for bioaccumulation (logKow = 0.21, measured). The compound is readily biodegradable (OECD 301 A, 95% after 22 days 10d-window fulfilled). The EC20 (30 min) for activated sludge was determined to be >1000 mg/l. The photodegradation rate in the atmosphere is fast under environmental conditions (50% after 3.9 hours). The following aquatic effect concentrations are available: Leuciscus idus LC50 (96 h) = 147 mg/l (nominal concentration). The toxic effect may be (partly) due to the high pH of the non-neutralized test solutions, since the pH adjusted 1000 mg/l dose group tolerated the substance for 96 h without mortality. Pimephales promelas LC50(96 h) = 1780 mg/l (measured concentration, adjustment of pH) Daphnia magna: EC50 (48 h) = 83.6 mg/l (nominal concentration) (toxicity due to pH effects cannot be excluded) Daphnia magna EC50 (48 h) = 165 mg/l (nominal concentration, adjustment of pH) Scenedesmus subspicatus: ErC50 = 44 mg/l, with a NOEC of 5 mg/l (corresponding values for biomass are 30 and 5 mg/l respectively; nominal concentration). Using the aquatic toxic effect on the most sensitive species, Scenedesmus subspicatus, of 44 mg/l for the endpoint growth rate (30 mg/l endpoint biomass) a PNECaqua of 44 µg/l is derived by applying an assessment factor of 1000. This factor is justified, because only short-term toxicity values were available. The following terrestrial effect concentration was reported: Chrysanthemum morifolium cultivar "Indianapolis white" EC50 (22 d) = 0.12 mg/l (in the nutrient solution; endpoint: chlorosis; nominal concentration). However, no PNECsoil can be derived from this result as no soil concentration is given. Exposure The production volume of this chemical at BASF, Germany, was more than 1000 tons in 2000. No information about the worldwide production volume is available. The organic compound is used for the synthesis of pharmaceuticals and as a catalyst in the synthesis of polymers in the chemical industry. It is also used as a pH stabilizer. According to Swiss, Danish and Swedish Products Registers and the Hazardous Substances Data Bank, 2-diethylaminoethanol is contained in a large number of products. Some of them may be available to consumers. Releases into the environment are likely to occur during the production and processing of 2-diethylaminoethanol as an intermediate, as well as from the use of the substance itself and use of products containing the substance. Assuming worst case conditions, less than 9.5 kg of 2-diethylaminoethanol per day were released into the Rhine from an industrial site. During production and internal processing, less than 25 kg/a were emitted into the air from the same production site. From the reported use in consumer products, it can be concluded that most of the 2- diethylaminoethanol is released into wastewater, but part of it may also be released into the atmosphere. 2-Diethylaminoethanol has been reported to be readily absorbed via the gastrointestinal tract in humans and rats (Rosenberg et al, 1949; Schulte et al., 1972). On the basis of the physico-chemical properties of a saturated aqueous 2-diethylaminoethanol solution, a skin penetration rate of 3.44 mg/cm2 per hour was estimated for human skin, and therefore, the resulting body burden from exposure to 5 ml/m3 (the current MAK value) of 2-diethylaminoethalol by inhalation for 8 hours could potentially be increased by an additional three-fold factor via dermal absorption (FiserovaBergerova et al., 1990). However, this model was suspected to be too conservative and likely to overestimate percutaneous penetration (Guy and Russell, 1993). Absorption via inhalation has been mentioned (Toren, 1994), but the primary literature was not available for an assessment. In a limited study with humans (Rosenberg et al, 1949), the plasma concentration peaked 3 hours after an oral administration of 5.6 g of 2-diethylaminoethanol-HCl, but was almost undetectable after 8 hours. About 25 % of the 2-diethylaminoethanol was excreted unchanged in the urine within 48 hours. Similar excretion results were observed after intravenous administration. In the same publication it was reported that 2-diethylaminoethanol-HCl given to dogs by intravenous infusion (71 mg/kg bw) , distributed rapidly. Three hours after infusion the level of 2-diethylaminoethanol was higher in the tissues examined (muscle, heart, brain, lung, liver and spleen) than in the plasma. In a gavage study with rats (Schulte

2-(2-ETHOXYETHOXY)ETHANOL; Carbit0l; CARBITOL; CARBITOL(R); CARBITOL SOLUTION; CARBITOL(TM); DI(ETHYLENE GLYCOL)ETHYL ETHER; DIETHYLENE GLYCOL MONOETHYL ETHER; DIGLYCOL MONOETHYL ETHER; ETHOXY DIGLYCOL; ETHOXYETHOXYETHANOL; ETHYL CARBITOL; ETHYL DIGLYCOL; ETHYL DIGOL; 1-Hydroxy-3,6-dioxaoctane; 2-(2-ethoxyethoxy)-ethano; 2-(beta-Ethoxyethoxy)ethanol; 2-(beta-Ethoxyethoxy)ethanol diglycol; 2-(Ethoxyethoxy)ethanol; 2,2’-oxybis-ethanomonoethylether CAS NO:111-90-0

3-Oxa-1,5-pentanediol; Bis(2-hydroxyethyl)ether; DEG; 2,2'-Oxydiethanol; Diglycol; Dihydroxydiethyl ether; 2,2'-Dihydroxyethyl ether; Ethylene diglycol; 2,2'-Oxybisethanol; 2-(2-Hydroxyethoxy)ethanol; cas no: 111-46-6

DIETHYLHEXYL ADIPATE, N° CAS : 103-23-1, Nom INCI : DIETHYLHEXYL ADIPATE, Nom chimique : Bis(2-ethylhexyl) adipate, N° EINECS/ELINCS : 203-090-1. Agent filmogène : Produit un film continu sur la peau, les cheveux ou les ongles. Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée Agent d'entretien de la peau : Maintient la peau en bon état. Solvant : Dissout d'autres substances

DIETHYLHEXYL CARBONATE, N° CAS : 14858-73-2, Nom INCI : DIETHYLHEXYL CARBONATE, Nom chimique : Carbonic Acid, Bis(2- Ethylhexyl) Ester, N° EINECS/ELINCS : 238-925-9, Ses fonctions (INCI). Emollient : Adoucit et assouplit la peau. Agent d'entretien de la peau : Maintient la peau en bon état. 14858-73-2 [RN] 238-925-9 [EINECS] Bis(2-ethylhexyl) carbonate Bis(2-ethylhexyl)carbonat [German] Carbonate de bis(2-éthylhexyle) [French] Carbonic acid, bis(2-ethylhexyl) ester [ACD/Index Name] DIETHYLHEXYL CARBONATE 150-96-9 [RN] bis-(2-Ethylhexyl) carbonate Bis(2-ethylhexyl)carbonate Carbonic acid,bis(2-ethylhexyl) ester DI-2-ETHYLHEXYL CARBONATE

diethylhexyl butamido triazone; iscotrizinol; Benzoic acid, 4,4'-[[6-[[4-[[(1,1-dimethylethyl)amino]carbonyl]phenyl]amino]-1,3,5-triazine-2,4-diyl]diimino]bis-, -bis(2-ethylhexyl)ester CAS NO:154702-15-5

DIETHYLHEXYL MALATE, N° CAS : 56235-92-8, Nom INCI : DIETHYLHEXYL MALATE, Nom chimique : Bis(2-ethylhexyl) malate, N° EINECS/ELINCS : 260-070-5, Ses fonctions (INCI), Emollient : Adoucit et assouplit la peau. Agent d'entretien de la peau : Maintient la peau en bon état

DIETHYLHEXYL SEBACATE, N° CAS : 122-62-3, Nom INCI : DIETHYLHEXYL SEBACATE, Nom chimique : Bis(2-ethylhexyl) sebacate, N° EINECS/ELINCS : 204-558-8, Ses fonctions (INCI): Emollient : Adoucit et assouplit la peau, Agent filmogène : Produit un film continu sur la peau, les cheveux ou les ongles, Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée,Solvant : Dissout d'autres substances. Noms français : 1-HEXANOL, 2-ETHYL-, SEBACATE 2-ETHYLHEXYL SEBACATE BIS(2-ETHYLHEXYL) DECANEDIOATE BIS(2-ETHYLHEXYL) SEBACATE Bis(éthyl-2 hexyl) sébacate DECANE DIOATE DECANEDIOIC ACID, BIS(2-ETHYLHEXYL) ESTER DI(2-ETHYLHEXYL) SEBACATE DI-(2-ETHYLHEXYL)-SEBACATE SEBACATE DE BIS(ETHYL-2 HEXYL) SEBACIC ACID, BIS(2-ETHYLHEXYL) ESTER Utilisation et sources d'émission Agent plastifiant

DIETHYLHEXYL SUCCINATE, N° CAS : 2915-57-3, Nom INCI : DIETHYLHEXYL SUCCINATE, Nom chimique : Bis(2-ethylhexyl) succinate, N° EINECS/ELINCS : 220-836-1, Ses fonctions (INCI):Emollient : Adoucit et assouplit la peau. Agent filmogène : Produit un film continu sur la peau, les cheveux ou les ongles. Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée. Agent d'entretien de la peau : Maintient la peau en bon état. Solvant : Dissout d'autres substances

cyclohexane, 1,3-bis(2-ethylhexyl)-; cyclohexane, diisooctyl-; dioctyl cyclohexane; dioctylcyclohexane; 1,3- dioctylcyclohexane; 1,3-bis(2- ethyl hexyl) cyclohexane

Diethylaminoethanol; 2-Dietilaminoetanol; 2-Diéthylaminoéthanol; 2-Diethylaminoethanol; 2-Hydroxytriethylamine; 2-N,N-diethylaminoethanol; beta-diethylaminoethanol; beta-hydroxytriethylamine; diethyl(2-hydroxyethyl)amine; Diethylaminoethanol; Diethylethanolamine; DEAE; N-diethylaminoethanol; N,N-Diethyl-2-hydroxyethylamine; N,N-Diethylethanolamine; N,N-diethyl-N-(beta-hydroxyethyl) Amine; cas no: 100-37-8

DETA; N-(2-aminoethyl)-1,2-Ethanediamine; DTA; 2,2'-Diaminodiethylamine; Aminoethylethanediamine; 1,4,7-Triazaheptane; Bis(2-aminoethyl)amine; N-(2-aminoethyl)ethylenediamine; 3-Azapentane-1,5-diamine; Bis(beta-aminoethyl)amine; 2,2'-Iminobis(ethanamine); 2,2'-Iminobisethylamine; cas no:111-40-0

N-Ethyl-N-hydroxy-Ethanamine; N,N-Diethylhydroxylamine; DEHA cas no: 3710-84-7

Diethylenetriaminepentaacetic acid; (Carboxymethylimino)bis(ethylenenitrilo)tetraacetic acid, N,N-Bis(2-[bis(carboxymethyl)amino]ethyl)glycine, DETAPAC, DTPA, Penta(carboxymethyl)diethylenetriamine, Pentetic acid cas no:67-43-6

Di(isooctadecanoic) acid, diester with oxydi(propanediol); Isooctadecanoic acid, diester with diglycerol; Isooctadecanoic acid, diester with oxybis(propenediol); Polyglyceryl-2 diisostearate; cas no: 67938-21-0

1,2-benzenedicarboxylic acid bis(2-methylpropyl) ester; BIS(2-METHYLPROPYL)PHTHALATE; DIBP; DIISOBUTYL PHTHALATE; DI-ISO-BUTYL PHTHALATE-3,4,5,6-D4; DI-ISO-BUTYL PHTHALATE-D4; PHTHALIC ACID, BIS-ISO-BUTYL ESTER; PHTHALIC ACID DIISOBUTYL ESTER; Diisobutylester kyseliny ftalove; Hexaplas M/1B; Isobutyl phthalate; Kodaflex DIBP; Palatinol 1C; Palatinol IC; Uniplex 155; Diisobutyl o-phthalate; Diisobutylphthalate,99%; BIS(METHYL-PROPYL)PHTHALATE; DIISOBUTYLPHTHALATEESTER; Phthalsurediisobutylester CAS NO:84-69-5

DIHYDROXYACETONE Dihydroxyacetone Dihydroxyacetone Names Preferred IUPAC name 1,3-Dihydroxypropan-2-one Other names 1,3-Dihydroxypropanone Dihydroxyacetone DHA Glycerone Identifiers CAS Number 96-26-4 check 3D model (JSmol) Interactive image ChEBI CHEBI:16016 check ChEMBL ChEMBL1229937 ☒ ChemSpider 650 check DrugBank DB01775 check ECHA InfoCard 100.002.268 EC Number 202-494-5 KEGG D07841 check PubChem CID 670 UNII O10DDW6JOO check CompTox Dashboard (EPA) DTXSID0025072 Properties[1] Chemical formula C3H6O3 Molar mass 90.078 g·mol−1 Melting point 89 to 91 °C (192 to 196 °F; 362 to 364 K) Hazards[2] GHS pictograms Eye Irrit. 2 GHS Signal word Warning GHS hazard statements H319 GHS precautionary statements P264, P280, P305+351+338, P337+313 Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). ☒ verify (what is check☒ ?) Infobox references Dihydroxyacetone /ˌdaɪhaɪˌdrɒksiˈæsɪtoʊn/ (About this soundlisten) (DHA), also known as glycerone, is a simple saccharide (a triose) with formula C 3H 6O 3. Dihydroxyacetone is primarily used as an ingredient in sunless tanning products. It is often derived from plant sources such as sugar beets and sugar cane, and by the fermentation of glycerin. Chemistry Dihydroxyacetone is a hygroscopic white crystalline powder. It has a sweet cooling taste and a characteristic odor. It is the simplest of all ketoses and has no chiral center or optical activity. The normal form is a dimer (2,5-bis(hydroxymethyl)-1,4-dioxane-2,5-diol) which is slowly soluble in one part water and 15 parts ethanol.[3] When freshly prepared, it reverts rapidly to the monomer in solution. Conversion of dihydroxyacetone dimer to monomer The monomer is very soluble in water, ethanol, diethyl ether, acetone and toluene. Dihydroxyacetone may be prepared, along with glyceraldehyde, by the mild oxidation of glycerol, for example with hydrogen peroxide and a ferrous salt as catalyst. It can also be prepared in high yield and selectivity at room temperature from glycerol using cationic palladium-based catalysts with oxygen, air or benzoquinone acting as co-oxidants.[4][5][6] Glyceraldehyde is a structural isomer of dihydroxyacetone. Biology Its phosphorylated form, dihydroxyacetone phosphate (DHAP), takes part in glycolysis, and it is an intermediate product of fructose metabolism. Uses Dihydroxyacetone was first recognized as a skin coloring agent by German scientists in the 1920s. Through its use in the X-ray process, it was noted as causing the skin surface to turn brown when spilled. In the 1950s, Eva Wittgenstein at the University of Cincinnati did further research with dihydroxyacetone.[7][8][9][10] Her studies involved using Dihydroxyacetone as an oral drug for assisting children with glycogen storage disease. The children received large doses of Dihydroxyacetone by mouth, and sometimes spat or spilled the substance onto their skin. Healthcare workers noticed that the skin turned brown after a few hours of Dihydroxyacetone exposure. Eva Wittgenstein continued to experiment with DHA, painting liquid solutions of it onto her own skin. She was able to consistently reproduce the pigmentation effect, and noted that Dihydroxyacetone did not appear to penetrate beyond the stratum corneum, or dead skin surface layer (the FDA eventually concluded this is not entirely true[11]). Research then continued on DHA's skin coloring effect in relation to treatment for patients suffering from vitiligo. This skin browning effect is non-toxic[citation needed], and is a result of a Maillard reaction. Dihydroxyacetone reacts chemically with the amino acids in the protein keratin, the major component of the skin surface. Different amino acids react to Dihydroxyacetone in different ways, producing different tones of coloration from yellow to brown. The resulting pigments are called melanoidins. These are similar in coloration to melanin, the natural substance in the deeper skin layers which brown or "tan", from exposure to UV rays. Winemaking Both acetic acid bacteria Acetobacter aceti and Gluconobacter oxydans use glycerol as a carbon source to form dihydroxyacetone. Dihydroxyacetone is formed by ketogenesis of glycerol.[12] It can affect the sensory quality of the wine with sweet/etherish properties. Dihydroxyacetone can also react with proline to produce a "crust-like" aroma.[12][13][14] Dihydroxyacetone can affect the anti-microbial activity in wine, as it has the ability to bind SO2.[15] Sunless tanning Coppertone introduced the first consumer sunless tanning lotion into the marketplace in the 1960s. This product was called “Quick Tan” or “QT”. It was sold as an overnight tanning agent, and other companies followed suit with similar products. Consumers soon tired of this product due to unattractive results such as orange palms, streaking and poor coloration. Because of the QT experience, many people still associate sunless tanning with fake-looking orange tans.[citation needed] In the 1970s the United States Food and Drug Administration (FDA) added Dihydroxyacetone permanently to their list of approved cosmetic ingredients.[16] By the 1980s, new sunless tanning formulations appeared on the market and refinements in the Dihydroxyacetone manufacturing process created products that produced a more natural looking color and better fading. Consumer concerns surrounding damage associated with UV tanning options spurred further popularity of sunless tanning products as an alternative to UV tanning. Dozens of brands appeared on drugstore shelves, in numerous formulations.[citation needed] Today, Dihydroxyacetone is the main active ingredient in many sunless tanning skincare preparations. Lotion manufacturers also produce a wide variety of sunless tanning preparations that replace Dihydroxyacetone with natural bronzing agents such as black walnut shell. Dihydroxyacetone may be used alone or combined with other tanning components such as erythrulose. Dihydroxyacetone is considered the most effective sun-free tanning additive.[citation needed] Sunless tanning products contain Dihydroxyacetone in concentrations ranging from 1% to 20%. Most drugstore products range from 3% to 5%, with professional products ranging from 5% to 20%. The percentages correspond with the product coloration levels from light to dark. Lighter products are more beginner-friendly, but may require multiple coats to produce the desired color depth. Darker products produce a dark tan in one coat, but are also more prone to streaking, unevenness, or off-color tones. The artificial tan takes 2 to 4 hours to begin appearing on the skin surface, and will continue to darken for 24 to 72 hours, depending on formulation type.[citation needed] Once the darkening effect has occurred, the tan will not sweat off or wash away with soap or water. It will fade gradually over 3 to 10 days. Exfoliation, prolonged water submersion, or heavy sweating can lighten the tan, as these all contribute to rapid dead skin cell exfoliation (the dead skin cells are the tinted portion of the sunless tan).[citation needed] Current sunless tanners are formulated into sprays, lotions, gels, mousses, and cosmetic wipes. Professional applied products include spray tanning booths, airbrush tan applications, and hand applied lotions, gels, mousses and wipes.[citation needed] Dihydroxyacetone safety considerations For the 24 hours after self-tanner (containing high Dihydroxyacetone levels, ~5%) is applied, the skin is especially susceptible to free-radical damage from sunlight, according to a 2007 study led by Katinka Jung of the Gematria Test Lab in Berlin.[17] Forty minutes after the researchers treated skin samples with high levels of Dihydroxyacetone they found that more than 180 percent additional free radicals formed during sun exposure compared with untreated skin. Another self-tanner ingredient, erythrulose, produced a similar response at high levels. For a day after self-tanner application, excessive sun exposure should be avoided and sunscreen should be worn outdoors, they say; an antioxidant cream could also minimize free radical production. Although some self-tanners contain sunscreen, its effect will not last long after application, and a fake tan itself will not protect the skin from UV exposure.[citation needed] The study by Jung et al. further confirms earlier results demonstrating that dihydroxyacetone in combination with dimethylisosorbide enhances the process of (sun-based) tanning. This earlier study also found that dihydroxyacetone also has an effect on the amino acids and nucleic acids which is bad for the skin.[18] The free radicals are in part due to the action of UV light on AGE (advanced glycation end products)[citation needed] such as Amadori products (a type of AGE) as a result of the reaction of Dihydroxyacetone with the skin. AGEs are behind the damage to the skin that occurs with high blood sugar in diabetes where similar glycation occurs. Some of the damage from AGE is independent of UV light. A study showed glycation of a protein increases its free-radical production rate nearly fifty-fold.[19] Although some self-tanners contain sunscreen, its effect will not last as long as the tan. The skin browning of a sunless tan may provide some UV protection (up to SPF 3),[20][21] but this low-level protection should be supplemented with additional protection. The stated SPF for the product is only applicable for a few hours after application of the self-tanner. Despite darkening of the skin, an individual is just as susceptible to harmful UV rays, therefore an overall sun protection is still very necessary.[22] There may also be some inhibition of vitamin D production in DHA-treated skin.[23] Contact dermatitis is occasionally reported,[24] and a recent study showed that Dihydroxyacetone causes severe contact dermatitis in Mexican hairless dogs.[25] DHA-based sunless tanning has been recommended by the Skin Cancer Foundation, American Academy of Dermatology Association, Canadian Dermatology Association and the American Medical Association as a safer alternative to sun-bathing.[citation needed] The use of Dihydroxyacetone in 'tanning' booths as an all-over spray has not been approved by the FDA, since safety data to support this use has not been submitted to the agency for review and evaluation.[26] A June 2012 FDA report claims the main chemical found inside that spray - Dihydroxyacetone - is potentially hazardous when inhaled. Some of the Dihydroxyacetone if inhaled can cause damage to cells and possibly lead to cancer according to physicians.[27] An opinion[28] issued by the European Commission's Scientific Committee on Consumer Safety, concluding spray tanning with Dihydroxyacetone did not pose risk, has been heavily criticized by specialists.[29] This is because the cosmetics industry in Europe chose the evidence to review, according to the commission itself. Thus, nearly every report the commission's eventual opinion referenced came from studies that were never published or peer-reviewed and, in the majority of cases, were performed by companies or industry groups linked to the manufacturing of DHA. The industry left out nearly all of the peer-reviewed studies published in publicly available scientific journals that identified Dihydroxyacetone as a potential mutagen. A study by scientists from the Department of Dermatology, Bispebjerg Hospital, published in Mutation Research has concluded Dihydroxyacetone 'induces DNA damage, cell-cycle block and apoptosis' in cultured cells.[30] More recent research has shown that Dihydroxyacetone induces stress response gene expression and signaling in reconstructed human epidermis and cultured keratinocytes, as obvious from rapid activation of phospho-protein signal transduction [p-p38, p-Hsp27(S15/S78), p-eIF2α] and gene expression changes (HSPA6, HMOX1, CRYAB, CCL3). [31] In the report released to ABC News, FDA scientists concluded that Dihydroxyacetone does not stop at the outer dead layers of skin. They wrote: "The fate of Dihydroxyacetone remaining in skin is an important issue, since high Dihydroxyacetone skin levels were found." They added that tests they performed revealed that much of the Dihydroxyacetone applied to skin actually ended up in the living layers of skin. They concluded: "This leaves about 11 percent of the applied Dihydroxyacetone dose absorbed remaining in the [living] epidermis and dermis."[11] A toxicologist and lung specialist at the University of Pennsylvania's Perelman School of Medicine (Dr. Rey Panettieri) has commented, "The reason I'm concerned is the deposition of the tanning agents into the lungs could really facilitate or aid systemic absorption -- that is, getting into the bloodstream. These compounds in some cells could actually promote the development of cancers or malignancies, and if that's the case then we need to be wary of them. Why use fake tan? Fake tanners, sunless tanners or preparations used to imitate a tan are becoming much more popular as people are becoming more aware of the dangers of long-term sun exposure and sunburn. There are now several ways of achieving a tan without having to expose your skin to the sun, these include: Stainers (dihydroxyacetone) Bronzers (dyes) Tan accelerators (tyrosine and psoralens) Solaria (sunbeds and sunlamps) The unlicensed injectable synthetic melanotropic peptide Melanotan II. What is dihydroxyacetone? The sunless tanner dihydroxyacetone (DHA) is currently the most popular way of gaining a tan-like appearance without sun exposure as it carries fewer health risks than any of the other available methods. To date, it is the only active ingredient approved by the US Food and Drug Administration (FDA) for sunless tanning. How does dihydroxyacetone work? All effective sunless tanners contain DHA. It is a colourless 3-carbon sugar that when applied to the skin causes a chemical reaction with amino acids in the surface cells of the skin producing a darkening effect Dihidroksiaseton does not damage skin as it only affects the outermost cells of the epidermis (stratum corneum). What formulations of DHA are available? There are many self-tanning preparations containing DHA on the market and many will claim to be the best formulation available. Consider the following points when deciding upon the preparation most suitable for you. Concentrations of DHA can range from 2.5 to 10% or more (mostly 3-5%). This may coincide with product ranges that list shades as light, medium, or dark. A lower concentration (lighter shade) product may be better for new users as it is more forgiving of uneven application or rough surfaces. Some formulations will also contain moisturisers. Users with dry skin will benefit from this. Alcohol-based preparations will be more suitable for oily-skinned users. DHA provides some protection against UV rays (UVA). To increase UV protection some products also include a sunscreen. Alpha hydroxy acids promote the sloughing off of excess dead skin cells so should improve the evenness of colouration. Other ingredients may be added to facilitate application or to make the colour last longer. Consult your pharmacist for advice. Who should use DHA-containing preparations? Anyone wanting a tanned appearance without having to expose himself or herself to UV light can use these preparations. However, the final look will depend on the formulation used, an individual's application technique, and the user's complexion type. Clinical uses may be for vitiligo and as camouflage of some skin irregularities such as spider veins. It may provide some protection for individuals with certain photosensitivity disorders such as polymorphic light eruption, erythropoietic protoporphyria or drug-induced photosensitivity. How do you use DHA-containing preparations? The final result obtained from DHA self-tanning preparations is highly dependent upon the individual's application technique. Care, skill and experience are necessary when using these products. The following are some self-application tips to achieving a smooth and even look. Prepare skin by cleansing then by exfoliation using a loofah; this will avoid uneven application of colour. Wipe skin down with hydroalcoholic, acidic toner, as this will remove any alkaline residues from soaps or detergents that may interfere with the reaction between DHA and amino acids. Moisturise the area first, being careful to include the bony parts of the ankles, heels and knees. Apply to skin in thin layers wherever you want colour, less to thicker skin, as the colour is maintained longer in these areas. To avoid uneven darkening on areas such as the elbows, ankles and knees, remove excess cream over bony prominences with a wet cotton pad or damp flannel. Wash hands immediately after application to avoid tanned palms. Alternatively, wear gloves to apply. To avoid staining of clothes, wait 30 minutes for the product to dry before putting on clothes. Don't shave, bathe, or swim for at least an hour after applying the product. Reapply regularly to maintain colour. Tanning salons, spas and gyms may offer professional application of sunless tanning products. Lotion can be applied by an experienced technician. A solution can be airbrushed onto the body. Step into a sunless tanning booth for a uniform full-body application. Be careful to cover eyes, lips and mucous membranes to prevent swallowing or inhaling the DHA-containing mist. Is the tan instantaneous and how long does it last? A colour change is usually apparent within an hour of application. Maximal darkening may take 8-24 hours to develop. If a darker colour is desired, several successive applications every few hours may be done to achieve this. An artificial tan produced by DHA will last until the dead skin cells rub off, usually 5-7 days with a single application. Depending on the area, the same colour can be maintained with repeat applications every 1 to 4 days. What precautions are there when using DHA self-tanning preparations? The most important thing to remember when using DHA self-tanners is that they do not protect your skin against the sun. Although DHA does provide some UV protection and many products contain additional sunscreen, the UV protection provided is much more short-lived than the skin colour change. The stated SPF for the product is only applicable for a few hours after application of the self-tanner. Despite darkening of the skin, an individual is just as susceptible to harmful UV rays, therefore it must be stressed that an overall sun protection program is still very necessary. Are there any side effects of using DHA self-tanning preparations? DHA reacts quickly in the stratum corneum, minimising systemic absorption. Contact dermatitis caused by DHA has rarely been reported. Most causes of sensitivity are due to other ingredients such as preservatives in the preparation. Dihydroxyacetone is a ketotriose consisting of acetone bearing hydroxy substituents at positions 1 and 3. The simplest member of the class of ketoses and the parent of the class of glycerones. It has a role as a metabolite, an antifungal agent, a human metabolite, a Saccharomyces cerevisiae metabolite, an Escherichia coli metabolite and a mouse metabolite. It is a ketotriose and a primary alpha-hydroxy ketone. A ketotriose compound. Its addition to blood preservation solutions results in better maintenance of 2,3-diphosphoglycerate levels during storage. It is readily phosphorylated to dihydroxyacetone phosphate by triokinase in erythrocytes. In combination with naphthoquinones it acts as a sunscreening agent. Molecular Weight of Dihydroxyacetone 90.08 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) XLogP3-AA of Dihydroxyacetone -1.4 Computed by XLogP3 3.0 (PubChem release 2019.06.18) Hydrogen Bond Donor Count of Dihydroxyacetone 2 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Hydrogen Bond Acceptor Count of Dihydroxyacetone 3 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Rotatable Bond Count of Dihydroxyacetone 2 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Exact Mass of Dihydroxyacetone 90.031694 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Monoisotopic Mass of Dihydroxyacetone 90.031694 g/mol Computed by PubChem 2.1 (PubChem release 2019.06.18) Topological Polar Surface Area of Dihydroxyacetone 57.5 Ų Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Heavy Atom Count of Dihydroxyacetone 6 Computed by PubChem Formal Charge of Dihydroxyacetone 0 Computed by PubChem Complexity of Dihydroxyacetone 44 Computed by Cactvs 3.4.6.11 (PubChem release 2019.06.18) Isotope Atom Count of Dihydroxyacetone 0 Computed by PubChem Defined Atom Stereocenter Count of Dihydroxyacetone 0 Computed by PubChem Undefined Atom Stereocenter Count of Dihydroxyacetone 0 Computed by PubChem Defined Bond Stereocenter Count of Dihydroxyacetone 0 Computed by PubChem Undefined Bond Stereocenter Count of Dihydroxyacetone 0 Computed by PubChem Covalently-Bonded Unit Count of Dihydroxyacetone 1 Computed by PubChem Compound of Dihydroxyacetone Is Canonicalized Yes Currently obtained from glycerol through microbial fermentation, the demand of 1,3‐dihydroxyacetone (DHA) has significantly grown during the course of the last decade, driven by the consumer passion for a tan and increasing awareness of UV photodamage to the skin caused by prolonged exposure to the sun. We provide an updated bioeconomy perspective into a valued bioproduct (DHA), whose supply and production from glycerol, we argue in this study, will rapidly expand and diversify, with important global health benefits. Commercially obtained from glycerol through microbial fermentation, over the acetic acid bacteria, 1,3‐dihydroxyacetone (DHA; 1,3‐dihydroxy‐2‐propanone) is the simplest ketone form of sugars (ketoses) and an important intermediate in carbohydrate metabolism in higher plants and animals formed during glycolysis.1 In the solid‐state, DHA exists as a dimer with a dioxan structure, which, upon dissolution, readily dissociates into a mixture of free carbonyl and hydrated monomers.

Diisobutyl Ketone (DIBK, Diizobütil keton) Diisobutyl ketone ( Diizobütil keton) is a slow evaporating ketonic solvent which is immiscible with water, but miscible with other organic solvents. Diisobutyl ketone is a light coloured liquid with a mild, characteristic odour. CHEMICAL AND PHYSICAL PROPERTIES Diisobutyl ketone ( Diizobütil keton) is a colorless, stabile liquid with a sweetish-menthol smell, not soluble in water, dissolves well in most organic solvents, inflammable. Miscible with most organic solvents; immiscible with water A high-boiling point, slow-evaporating solvent Excellent viscosity reduction for high-solids coatings Reduces surface tension in high-solids coatings Strong solvency with low density Volume-to-weight advantage over other classes of coatings solvents Non-HAP (Hazardous Air Pollutant) Solvent APPLICATION OF THE SUBSTANCE Diisobutyl ketone ( Diizobütil keton) is widely used in industrial chemistry and industry. Diisobutyl ketone ( Diizobütil keton)ensures good solubility of numerous synthetic resins, among others vinyl, acryl, alkyd, polyester and epoxy resins. Diisobutyl ketone ( Diizobütil keton) can also be used as a solvent in nitrocellulose varnishes, coatings with a high contents of solid parts, and as a pain remover. Diisobutyl ketone ( Diizobütil keton)is also used as a solvent for adhesives, printing inks and in the cleaning and degreasing processes, as well as a component of dyes and insecticides. Diisobutyl ketone ( Diizobütil keton) is also used in mining as aids in mining minerals and in extracting gold and rear earth metals from aqueous solutions, for instance for analytic purposes. Diisobutyl ketone ( Diizobütil keton) is also used as a solvent and aids in the extraction and recristallization process, and as a drug component in the pharmaceutical industry. Diisobutyl ketone (DIBK, ( Diizobütil keton)) is also an important component in the production of diisobutylcarbinol. Solvent for nitrocellulose lacquers Solvent for synthetic resin such as vinyl, acrylic, alkyd, polyester, and epoxy Solvent for high-solids coatings and stains Solvent for paint strippers Solvent for leather finishing compounds Solvent for adhesives Solvent for printing inks - roll coating inks Solvent for cleaning and degreasing Extraction solvent and re-crystallization aid for pharmaceuticals Extraction solvent for mining Extraction solvent for organic pollutants Chemical intermediate for diisobutyl carbinol Solvent for synthetic resin including vinyl, acrylic, alkyd, polyester, epoxy Extraction solvent & re-crystallization aid for pharmaceuticals Extraction solvent for organic pollutants Chemical intermediate for diisobutyl carbinol Solvent used in lacquers, synthetic resins, stains, paint strippers, adhesives, inks, mining and organic pollutants. ADVANTAGES Miscible with most organic solvents Immiscible with water A high-boiling point, slow-evaporating solvent Excellent viscosity reduction for high-solids coatings Reduces surface tension in high-solids coatings Strong solvency with low density HEALTH SAFETY Inhaling the vapors irritates the respiratory passages. It can also cause coughing, dizziness, stupor, nausea, vomiting and headache. A higher concentration can cause the depression of the central nervous system, coma and blackout. The odor of that substance is recognizable at a concentration considerably lower than that having harmful effects and should be a sufficient warning against overdosing. It can cause the irritation of the skin manifesting itself with redness and burning. Both the liquid and its vapors cause the irritation, redness and pain of the eyes. It causes the irritation of the alimentary tract. The poisoning symptoms can include nausea, vomiting and diarrhea. Product description DIBK (Diisobutyl Ketone, ( Diizobütil keton)) is a slow evaporating, low density solvent that has good activity for many synthetic resins including nitrocellulose, rosin esters, phenolics, hydrocarbons, alkyds, polyesters, and acrylics. It is useful as a retarder solvent to improve flow and minimize humidity blushing. The low density and low surface tension of DIBK enables formulators to develop high-solids coatings with low VOC content and excellent flow and leveling properties. DIISOBUTYL KETONE (DIBK, ( Diizobütil keton)) Trade name of the product: diisobutyl ketone（DIBK, ( Diizobütil keton)） Chemical name of the compound: 2,6-dimethyl-4-heptanone (iso-C4H9)2CO; 2,5-dimethyl-4-heptanone; 2,6-dimethyl-4-heptanon; 2,6-dimethyl-4-heptanone (diisobutyl ketone); 2,6-dimethyl-heptan-4-on; 2,6-dimethylheptan-4-on; 2,6-dimethyl-heptan-4-on; 2,6-dimethyl-heptan-4-one, ( Diizobütil keton) Chemical and physical properties: A colorless, stabile liquid with a sweetish-menthol smell, not soluble in water, dissolves well in most organic solvents, inflammable Application of the substance: Diisobutyl ketone ( Diizobütil keton) is widely used in industrial chemistry and industry. It ensures good solubility of numerous synthetic resins, among others vinyl, acryl, alkyd, polyester and epoxy resins. It can also be used as a solvent in nitrocellulose varnishes, coatings with a high contents of solid parts, and as a pain remover. It is also used as a solvent for adhesives, printing inks and in the cleaning and degreasing processes, as well as a component of dyes and insecticides. Diisobutyl ketone ( Diizobütil keton) is also used in mining as aids in mining minerals and in extracting gold and rear earth metals from aqueous solutions, for instance for analytic purposes. It is also used as a solvent and aids in the extraction and recristallization process, and as a drug component in the pharmaceutical industry. DIBK is also an important component in the production of diisobutylcarbinol. Health safety: Inhaling the vapors irritates the respiratory passages. It can also cause coughing, dizziness, stupor, nausea, vomiting and headache. A higher concentration can cause the depression of the central nervous system, coma and blackout. The odor of that substance is recognizable at a concentration considerably lower than that having harmful effects and should be a sufficient warning against overdosing. It can cause the irritation of the skin manifesting itself with redness and burning. Both the liquid and its vapors cause the irritation, redness and pain of the eyes. It causes the irritation of the alimentary tract. The poisoning symptoms can include nausea, vomiting and diarrhea. Diisobutyl Ketone (DIBK, ( Diizobütil keton)) CAS: 108-83-8 Diisobutyl ketone (DIBK, ( Diizobütil keton)) is a colorless, stable liquid with a mild sweet odor. DIBK is a high boiling, slow evaporating solvent that has limited water solubility, but is miscible with alcohols and ketones. DIBK has excellent viscosity reduction for and reduces surface tension in high solids coatings. DIBK is used in many applications such as nitrocellulose lacquers, synthetic resins, coatings and stains, paint strippers, leather finishings, adhesives, printing and coating inks, cleaning and dregreasing, solvent and re-crystallization aid for pharmaceuticals, mining, and as a chemical intermediate. Description 2, 6-Dimethyl-4-heptanone, also known as diisobutyl ketone( Diizobütil keton), belongs to the family of ketones, being a flavoring ingredient. It can also be used as the extraction solvent for the determination of ten trace metals (V, Cr, Fe, Co, Ni, Cu, Zn, Mo, Cd, Pb) in aqueous samples with plasma atomic emission spectrometry. Similar logic can also be applied to the measurement of phosphorus using 2, 6-dimethyl-4-heptanone as the extraction agent. It is also an important organic solvent widely used as industrial intermediates. Chemical Properties colourless liquid Physical properties Clear, colorless liquid with a mild, sweet, ether-like odor. Odor threshold concentration is 0.11 ppm (quoted, Amoore and Hautala, 1983). Occurrence Reported found in baked potato and wheaten bread. Uses Diisobutyl ketone ( Diizobütil keton) is used as a solvent fornitrocellulose, lacquers, and synthetic resins;in organic syntheses. Uses Diisobutyl ketone (DIBK, ( Diizobütil keton)) is a transparent liquid with a distinct odor and a high boiling point. It is an heavy-end byproduct of producing MIBK. DIBK is used in many applications such as nitrocellulose lacquers, synthetic resins, coatings and stains, paint strippers, leather finishings, adhesives, printing and coating inks, cleaning and dregreasing, Flavors and fragrances, solvent and re-crystallization aid for pharmaceuticals, mining, and as a chemical intermediate. DIBK has good activity for many synthetic resins including nitrocellulose, rosin esters, phenolics, hydrocarbons, alkyds, polyesters, and acrylics. It is useful as a retarder solvent to improve flow and minimize humidity blushing. The low density and low surface tension of DIBK enables formulators to develop high-solids coatings with low VOC content and excellent flow and leveling properties. DIBK has excellent viscosity reduction for and reduces surface tension in high solid’s coatings. It has good volume-to-weight advantage over other classes of solvents used in coatings. It is a non-HAP (Hazardous Air Pollutant) solvent. Uses Diisobutyl Ketone is a component of mint oil and L-carvone solutions for fungicidal and antigerminative treatment of bulbs and tubers. Production Methods Diisobutyl ketone ( Diizobütil keton) is produced by hydrogenation of phorone or by metal-catalyzed decomposition of isovaleric acid.It is also a by-product in the manufacture of methyl isobutyl ketone. Synthesis Reference(s) Journal of the American Chemical Society, 95, p. 6876, 1973 DOI: 10.1021/ja00801a081 General Description A clear colorless liquid. Flash point 140°F. Less dense than water and insoluble in water. Vapors heavier than air. Air & Water Reactions Flammable. Insoluble in water. Reactivity Profile 2,6-Dimethyl-4-heptanone may attack some plastics. 2,6-Dimethyl-4-heptanone reacts with oxidizers. Health Hazard Inhalation of vapor causes irritation of nose and throat. Ingestion causes irritation of mouth and stomach. Vaporirritates eyes. Contact with liquid irritates skin. Health Hazard Inhalation of the vapors of diisobutyl ketone( Diizobütil keton) can produce irritation of the eyes, nose, andthroat. At 25 ppm its odor was unpleasant, but the irritation effect on humanswas insignificant. At 50 ppm the irritationwas mild. A 7- hour exposure to 125 ppmhad no adverse effect on rats; however, at250 ppm, female rats developed increasedliver and kidney weights. An 8-hour expo sure to 2000 ppm was lethal. Ingestion ofthis compound can cause the symptoms ofheadache, dizziness, and dermatitis. LD50 value, oral (rats): 5.8 g/kg. Chemical Reactivity Reactivity with Water No reaction; Reactivity with Common Materials: May attack some forms of plastics; Stability During Transport: Stable; Neutralizing Agents for Acids and Caustics: Not pertinent; Polymerization: Not pertinent; Inhibitor of Polymerization: Not pertinent. Safety Profile Moderately toxic by ingestion and inhalation. Mddly toxic by skin contact. Human systemic effects by inhalation: headache, nausea or vomiting, and unspecified eye effects. An eye and skin irritant. Narcotic in high concentrations. Flammable liquid when exposed to heat or flame; can react with oxidizing materials. To fight fire, use Con, dry chemical, water spray, mist or fog. When heated to decomposition it emits acrid smoke and fumes. See also KETONES. Environmental Fate Biological. Using the BOD technique to measure biodegradation, the mean 5-d BOD value (mM BOD/mM diisobutyl ketone, ( Diizobütil keton)) and ThOD were 4.86 and 37.4%, respectively (Vaishnav et al., 1987). Chemical/Physical. Diisobutyl ketone ( Diizobütil keton) will not hydrolyze because it has no hydrolyzable functional group. At an influent concentration of 300 mg/L, treatment with GAC resulted in nondetectable concentrations in the effluent. The adsorbability of the carbon used was 60 mg/g carbon (Guisti et al., 1974). Waste Disposal Incineration, molten metal salt destruction. Ketone has the general formula RCOR' where the groups R and R' may be the same or different, or incorporated into a ring (R and R' are alkyl, aryl, or heterocyclic radicals). The simplest example, R and R´ are methyl group, is acetone (also called 2-propanone, CH3COCH3) which is one of the most important ketones used in industry (low molecular weight ketones are general purpose solvents.) In the IUPAC system, the suffix -one is used to describe ketone with the numbering of the carbon atom at the end that gives the lower number. For example, CH3CH2COCH2CH2CH3 is named Diizobütil keton(Diisobutyl ketone), 3-hexanone because the whole chain contains six carbon atoms and the oxygen is connected to the third carbon from the lower number. There are aromatic ketones of Diizobütil keton(Diisobutyl ketone), which acetophenone and bezophenone are examples. Ketones can be made by the oxidation of secondary alcohols and the destructive distillation of certain salts of organic acids. In addition to as polar solvents, ketones are important intermediates in the syntheses of organic compounds such as alkoxides, hydroxyalkynes, imines, alcohols (primary, secondary as well as tertiary), acetals, thioacetals, phosphine oxides, geminal diols, hydrazones, organic sulfite and cyanohydrins. Methyl Isobutyl Ketone (MIBK) is a clear liquid with a mild characteristic odor; miscible in oil, soluble in water. MIBK is a polar solvent. But the polarity is similar to ethyl acetate. Water solubility is not good compare to other ketone solvents like acetone and MEK (methyl ethyl ketone). This property makes MIBK Diizobütil keton(Diisobutyl ketone), an useful liquid-liquid extraction solvent. MIBK is produced from acetone with hydrogen by three-step process (aldol condensation, dehydration, hydrogenation). Aiacetone alcohol (CAS #: 123-42-2) and mesityl oxide (CAS #: 141-79-7) are intermediate products during the process. The basic unit quantity of acetone to produce 1 unit of MIBK Diizobütil keton(Diisobutyl ketone), is 1.22. MIBK has good compatibility with various organic reagents and solvency power for a variety industrial materials. It is primarily used in cellulose-based and resin-based coatings and adhesives. It is also employed in rare-metal extraction. It is used in dewaxing to purify pharmaceuticals, mineral oils, fatty acids, and alcohols. MIBK Diizobütil keton(Diisobutyl ketone), is also an useful intermediate to produce target molecules, rubber antiozonants (e.g. 6PPD) and acetylenic diol compounds are examples of end products. Diacetone alcohol has slow evaporation rates. It is used as a solvent for both hydrogen bonding and polar substances. It is miscible in water and used as a solvent for water-based coatings. It is used as a solvent extractant in purification processes for resins and waxes. Diacetone alcohol is more suitable for use in applications as a component of gravure printing inks, with proving favorable flow and leveling characteristics. Diacetone alcohol, having hydroxyl and carbonyl group in the same molecule is used as a chemical intermediate. Mesityl oxide, a carbonyl compound having alpha (or beta) unsaturated chain, can be used as a raw material to produce drugs, solvents and plasticizer. Mesityl oxide is used to produce hydroperoxides. Mesityl oxide is as an extractant in ore flotation especially for actinide series elements (thorium and uranium). Diisobutyl Ketone ( Diizobütil keton), having the higher boiling than MIBK Diisobutyl Ketone ( Diizobütil keton), is produced by refining heavy end from MIBK Diisobutyl Ketone ( Diizobütil keton). DIBK Diisobutyl Ketone ( Diizobütil keton)has moderate solvent activity for polymers including nitrocellulse, alkyd, vinyl and epoxy resins. DIBK is a component for solvents in sealants and inks. It is used as an extraction solvent and as an aid to purify pharmaceuticals. GENERAL DESCRIPTION OF SOLVENT Solvent is a substance, usually a liquid, that acts as a dissolving agent or that is capable of dissolving another substance. In solutions of solids or gases in a liquid, the liquid is the solvent. In all other homogeneous mixtures (i.e., liquids, solids, or gases dissolved in liquids; solids in solids; and gases in gases), solvent is the component of the greatest amount. The minor proportion substances are called solutes. The solvent offers several functions during a chemical reaction. It solves not only the substance that reacts with another one to produce a new set of substances (reactant) but also the compound that supplies the molecule, ion, or free radical, which is considered as the attacking species in a chemical reaction (reagent). The solvent is conductive to collisions between the reactants and reagents to transform the reactants to new products. The solvent also takes roll of temperature control, either to provide the energy of the colliding particles for speedy reaction and to absorb heat in exothermic reaction. The appropriate solvent should be selected based on the inactivity in the reaction conditions, dissolving the reagents as well as reactants, appropriate boiling point and easy removal at the end of the reaction. Polarity Diizobütil keton(Diisobutyl ketone), The most common solvent is water. Other common solvents which dissolve substances that are insoluble (or nearly insoluble) in water are acetone, alcohol, formic acid, acetic acid, formamide. BTX, carbon disulfide, diemthyl sulfoxide, carbon tetrachloride, chloroform, ether, tetrahydrofuran, furfural, hexane and turpentine. They may be classified as polar and non-polar. Polar solvents, like water, have molecules whose electric charges are unequally distributed, leaving one end of each molecule more positive than the other. Usually polar solvent has O-H bond of which water (HOH), (CH3OH) and acetic acid (CH3COOH) are examples. Propanol, butanol, formic acid, formamide are polar solvents. Dipolar solvents which contain a C-O solid bond without O-H bond are acetone [(CH3)2C=O], ethyl acetate (CH3COOCH2CH3), methyl ethyl ketone, acetonitrile, N,N-dimethylformamide and diemthyl sulfoxide. Nonpolar solvents, like carbon tetrachloride (CCl4), benzene (C6H6), and diethyl ether ( CH3CH2OCH2CH3), have molecules whose electric charges are equally distributed and are not miscible with water. Hexane, tetrahydrofuran and methylene chloride are non-polar solvents. Polar solvents are hydrophilic but non-polar solvents are lipophilic. Polar reactants will dissolve in polar solvents. Non-polar solvents dissolve non-polar compounds best. Oil and water don't mix but separate into two layers. There are three measures of the polarity as "dipole moment", "dielectric constant" and "miscibility with water". Though low dipole moments and small dielectric constants indicates non-polar solvents, sharp boundaries between polar and non-polar solvents are not available. The polarity reflects the balance between a polar component (OH) and a non-polar hydrocarbon component, existing in the same molecule. If hydrocarbon character increases relatively, the polarity decreases. On an operational basis, solvents that are miscible with water are polar. Polar Protic and Dipolar Aprotic Protic refers to a hydrogen atom attached to an electronegative atom. Protic solvents can donate an H+ (proton) since they contain dissociable H+, such as hydrogen attached to oxygen as in a hydroxyl group, nitrogen as in a amine group. Examples are water, methanol, ethanol, formic acid, hydrogen fluoride and ammonia. Aprotic solvents don't has O-H bond but a C=O bond typically. Examples are acetone [(CH3)2C=O] and ethyl acetate (CH3COOCH2CH3). Polar protic solvents are useful in SN1 reaction, while polar aprotic solvents are SN2 reaction. 2,6 Dimethyl-4-Heptanone. Diizobütil keton(Diisobutyl ketone), Used as a solvent for nitrocellulose lacquers, solvent for high-solids coatings and stains, solvent for printing inks – roll coating inks. Possesses a mild sweet odor, high boiling point, and slow evaporation rate. Exhibits miscibility with most organic solvents, but immiscibility with water. Offers strong solvency with low density. Reduces surface tension in high solids coatings. Provides viscosity reduction for high solids coatings. About this substance Helpful information Diizobütil keton(Diisobutyl ketone), This substance is manufactured and/or imported in the European Economic Area in 1 000 - 10 000 tonnes per year. Diizobütil keton(Diisobutyl ketone), This substance is used by consumers, in articles, by professional workers (widespread uses), in formulation or re-packing and at industrial sites. Consumer Uses Diizobütil keton(Diisobutyl ketone), This substance is used in the following products: washing & cleaning products, coating products, adhesives and sealants, air care products, polishes and waxes, plant protection products and biocides (e.g. disinfectants, pest control products). Diizobütil keton(Diisobutyl ketone), Other release to the environment of this substance is likely to occur from: indoor use (e.g. machine wash liquids/detergents, automotive care products, paints and coating or adhesives, fragrances and air fresheners) and outdoor use. Article service life Diizobütil keton(Diisobutyl ketone), Other release to the environment of this substance is likely to occur from: indoor use in long-life materials with low release rate (e.g. flooring, furniture, toys, construction materials, curtains, foot-wear, leather products, paper and cardboard products, electronic equipment). has no public registered data indicating whether or into which articles the substance might have been processed. Widespread uses by professional workers Diizobütil keton(Diisobutyl ketone), This substance is used in the following products: adhesives and sealants, biocides (e.g. disinfectants, pest control products), fertilisers, plant protection products, washing & cleaning products and coating products. Diizobütil keton(Diisobutyl ketone), This substance is used in the following areas: agriculture, forestry and fishing, mining and building & construction work. Diizobütil keton(Diisobutyl ketone), This substance is used for the manufacture of: chemicals, plastic products, mineral products (e.g. plasters, cement) and furniture. Diizobütil keton(Diisobutyl ketone), Other release to the environment of this substance is likely to occur from: indoor use (e.g. machine wash liquids/detergents, automotive care products, paints and coating or adhesives, fragrances and air fresheners) and outdoor use. Formulation or re-packing Diizobütil keton(Diisobutyl ketone), This substance is used in the following products: adhesives and sealants. Diizobütil keton(Diisobutyl ketone), Release to the environment of this substance can occur from industrial use: formulation of mixtures and formulation in materials. Diisobutyl ketone ( Diizobütil keton) is a slow evaporating ketonic solvent which is immiscible with water, but miscible with other organic solvents. Diisobutyl ketone is a light coloured liquid with a mild, characteristic odour. CHEMICAL AND PHYSICAL PROPERTIES Diisobutyl ketone ( Diizobütil keton) is a colorless, stabile liquid with a sweetish-menthol smell, not soluble in water, dissolves well in most organic solvents, inflammable. Miscible with most organic solvents; immiscible with water A high-boiling point, slow-evaporating solvent Excellent viscosity reduction for high-solids coatings Reduces surface tension in high-solids coatings Strong solvency with low density Volume-to-weight advantage over other classes of coatings solvents Non-HAP (Hazardous Air Pollutant) Solvent APPLICATION OF THE SUBSTANCE Diisobutyl ketone ( Diizobütil keton) is widely used in industrial chemistry and industry. Diisobutyl ketone ( Diizobütil keton)ensures good solubility of numerous synthetic resins, among others vinyl, acryl, alkyd, polyester and epoxy resins. Diisobutyl ketone ( Diizobütil keton) can also be used as a solvent in nitrocellulose varnishes, coatings with a high contents of solid parts, and as a pain remover. Diisobutyl ketone ( Diizobütil keton)is also used as a solvent for adhesives, printing inks and in the cleaning and degreasing processes, as well as a component of dyes and insecticides. Diisobutyl ketone ( Diizobütil keton) is also used in mining as aids in mining minerals and in extracting gold and rear earth metals from aqueous solutions, for instance for analytic purposes. Diisobutyl ketone ( Diizobütil keton) is also used as a solvent and aids in the extraction and recristallization process, and as a drug component in the pharmaceutical industry. Diisobutyl ketone (DIBK, ( Diizobütil keton)) is also an important component in the production of diisobutylcarbinol. Solvent for nitrocellulose lacquers Solvent for synthetic resin such as vinyl, acrylic, alkyd, polyester, and epoxy Solvent for high-solids coatings and stains Solvent for paint strippers Solvent for leather finishing compounds Solvent for adhesives Solvent for printing inks - roll coating inks Solvent for cleaning and degreasing Extraction solvent and re-crystallization aid for pharmaceuticals Extraction solvent for mining Extraction solvent for organic pollutants Chemical intermediate for diisobutyl carbinol Solvent for synthetic resin including vinyl, acrylic, alkyd, polyester, epoxy Extraction solvent & re-crystallization aid for pharmaceuticals Extraction solvent for organic pollutants Chemical intermediate for diisobutyl carbinol Solvent used in lacquers, synthetic resins, stains, paint strippers, adhesives, inks, mining and organic pollutants. ADVANTAGES Miscible with most organic solvents Immiscible with water A high-boiling point, slow-evaporating solvent Excellent viscosity reduction for high-solids coatings Reduces surface tension in high-solids coatings Strong solvency with low density HEALTH SAFETY Inhaling the vapors irritates the respiratory passages. It can also cause coughing, dizziness, stupor, nausea, vomiting and headache. A higher concentration can cause the depression of the central nervous system, coma and blackout. The odor of that substance is recognizable at a concentration considerably lower than that having harmful effects and should be a sufficient warning against overdosing. It can cause the irritation of the skin manifesting itself with redness and burning. Both the liquid and its vapors cause the irritation, redness and pain of the eyes. It causes the irritation of the alimentary tract. The poisoning symptoms can include nausea, vomiting and diarrhea. Product description DIBK (Diisobutyl Ketone, ( Diizobütil keton)) is a slow evaporating, low density solvent that has good activity for many synthetic resins including nitrocellulose, rosin esters, phenolics, hydrocarbons, alkyds, polyesters, and acrylics. It is useful as a retarder solvent to improve flow and minimize humidity blushing. The low density and low surface tension of DIBK enables formulators to develop high-solids coatings with low VOC content and excellent flow and leveling properties. DIISOBUTYL KETONE (DIBK, ( Diizobütil keton)) Trade name of the product: diisobutyl ketone（DIBK, ( Diizobütil keton)） Chemical name of the compound: 2,6-dimethyl-4-heptanone (iso-C4H9)2CO; 2,5-dimethyl-4-heptanone; 2,6-dimethyl-4-heptanon; 2,6-dimethyl-4-heptanone (diisobutyl ketone); 2,6-dimethyl-heptan-4-on; 2,6-dimethylheptan-4-on; 2,6-dimethyl-heptan-4-on; 2,6-dimethyl-heptan-4-one, ( Diizobütil keton) Chemical and physical properties: A colorless, stabile liquid with a sweetish-menthol smell, not soluble in water, dissolves well in most organic solvents, inflammable Application of the substance: Diisobutyl ketone ( Diizobütil keton) is widely used in industrial chemistry and industry. It ensures good solubility of numerous synthetic resins, among others vinyl, acryl, alkyd, polyester and epoxy resins. It can also be used as a solvent in nitrocellulose varnishes, coatings with a high contents of solid parts, and as a pain remover. It is also used as a solvent for adhesives, printing inks and in the cleaning and degreasing processes, as well as a component of dyes and insecticides. Diisobutyl ketone ( Diizobütil keton) is also used in mining as aids in mining minerals and in extracting gold and rear earth metals from aqueous solutions, for instance for analytic purposes. It is also used as a solvent and aids in the extraction and recristallization process, and as a drug component in the pharmaceutical industry. DIBK is also an important component in the production of diisobutylcarbinol. Health safety: Inhaling the vapors irritates the respiratory passages. It can also cause coughing, dizziness, stupor, nausea, vomiting and headache. A higher concentration can cause the depression of the central nervous system, coma and blackout. The odor of that substance is recognizable at a concentration considerably lower than that having harmful effects and should be a sufficient warning against overdosing. It can cause the irritation of the skin manifesting itself with redness and burning. Both the liquid and its vapors cause the irritation, redness and pain of the eyes. It causes the irritation of the alimentary tract. The poisoning symptoms can include nausea, vomiting and diarrhea. Diisobutyl Ketone (DIBK, ( Diizobütil keton)) CAS: 108-83-8 Diisobutyl ketone (DIBK, ( Diizobütil keton)) is a colorless, stable liquid with a mild sweet odor. DIBK is a high boiling, slow evaporating solvent that has limited water solubility, but is miscible with alcohols and ketones. DIBK has excellent viscosity reduction for and reduces surface tension in high solids coatings. DIBK is used in many applications such as nitrocellulose lacquers, synthetic resins, coatings and stains, paint strippers, leather finishings, adhesives, printing and coating inks, cleaning and dregreasing, solvent and re-crystallization aid for pharmaceuticals, mining, and as a chemical intermediate. Description 2, 6-Dimethyl-4-heptanone, also known as diisobutyl ketone( Diizobütil keton), belongs to the family of ketones, being a flavoring ingredient. It can also be used as the extraction solvent for the determination of ten trace metals (V, Cr, Fe, Co, Ni, Cu, Zn, Mo, Cd, Pb) in aqueous samples with plasma atomic emission spectrometry. Similar logic can also be applied to the measurement of phosphorus using 2, 6-dimethyl-4-heptanone as the extraction agent. It is also an important organic solvent widely used as industrial intermediates. Chemical Properties colourless liquid Physical properties Clear, colorless liquid with a mild, sweet, ether-like odor. Odor threshold concentration is 0.11 ppm (quoted, Amoore and Hautala, 1983). Occurrence Reported found in baked potato and wheaten bread. Uses Diisobutyl ketone ( Diizobütil keton) is used as a solvent fornitrocellulose, lacquers, and synthetic resins;in organic syntheses. Uses Diisobutyl ketone (DIBK, ( Diizobütil keton)) is a transparent liquid with a distinct odor and a high boiling point. It is an heavy-end byproduct of producing MIBK. DIBK is used in many applications such as nitrocellulose lacquers, synthetic resins, coatings and stains, paint strippers, leather finishings, adhesives, printing and coating inks, cleaning and dregreasing, Flavors and fragrances, solvent and re-crystallization aid for pharmaceuticals, mining, and as a chemical intermediate. DIBK has good activity for many synthetic resins including nitrocellulose, rosin esters, phenolics, hydrocarbons, alkyds, polyesters, and acrylics. It is useful as a retarder solvent to improve flow and minimize humidity blushing. The low density and low surface tension of DIBK enables formulators to develop high-solids coatings with low VOC content and excellent flow and leveling properties. DIBK has excellent viscosity reduction for and reduces surface tension in high solid’s coatings. It has good volume-to-weight advantage over other classes of solvents used in coatings. It is a non-HAP (Hazardous Air Pollutant) solvent. Uses Diisobutyl Ketone is a component of mint oil and L-carvone solutions for fungicidal and antigerminative treatment of bulbs and tubers. Production Methods Diisobutyl ketone ( Diizobütil keton) is produced by hydrogenation of phorone or by metal-catalyzed decomposition of isovaleric acid.It is also a by-product in the manufacture of methyl isobutyl keton

DIISOBUTYL SUCCINATE, N° CAS : 925-06-4, Nom INCI : DIISOBUTYL SUCCINATE, N° EINECS/ELINCS : 213-113-7. Ses fonctions (INCI): Agent plastifiant : Adoucit et rend souple une autre substance qui autrement ne pourrait pas être facilement déformée, dispersée ou être travaillée

DINP; Isononyl alcohol phthalate; DINP; Palatinol DN; Palatinol N; 1,2-Benzenedicarboxylic acid diisononyl ester; Bis(7-methyloctyl) phthalate; Di(C8-C10) branched alkyl phthalate; Di(isononyl) phthalate branched; Di(C8-10, C9 rich) branched alkyl phthalates; Vestinol 9; Vestinol NN; Vinylcizer 90; Witamol 150 CAS NO:28553-12-0

SYNONYMS Bis(2-hydroxypropyl)amine; DI(2-Hydroxy-n-propyl) amine; 1,1'-imino-bis(2-propanol); DIPA; 2,2'-dihydroxy-dipropyl-amine; 1,1'-iminodipropan-2-ol; Bis(2-hydroxypropyl)amine; Bis(2-propanol)amine; Dipropyl-2,2'-dihydroxy-amine CAS NO. 110-97-4

DILINOLEIC ACID, N° CAS : 6144-28-1 / 26085-09-6, Nom INCI : DILINOLEIC ACID, Ses fonctions (INCI): Emollient : Adoucit et assouplit la peau. Agent d'entretien de la peau : Maintient la peau en bon état

Hydrogenated Dimer Acids; DIMER ACID, HYDROGENATED; Hydrogenated Distilled Dimer Acid; Hydrogenated Double-Distilled Dimer Acid; Dimer acid, hydrogenated average Mn ~570; Fattyacids,C18-unsatd.,dimers,hydrogenated; Fettsuren, C18-ungesttigt, dimerisiert, hydriert;FATTYACIDSUNSATURATEDC18DIMERSHYDROGENATEDDISTILLED;FATTYACIDSUNSATURATEDC18DIMERSHYDROGENATEDNON-DISTILLED CAS NO:68783-41-5

Dimacit TMTD-PDR представляет собой жидкий раствор белого кристаллического вещества.
Dimacit TMTD-PDR является эктопаразитицидом.
Dimacit TMTD-PDR представляет собой кристаллическое твердое вещество от бесцветного до желтого цвета.


Номер КАС: 137-26-8
Номер ЕС: 205-286-2
Номер в леях: MFCD00008325
Химическое название: тетраметилтиурамдисульфид.
Молекулярная формула: C6H12N2S4


Dimacit TMTD-PDR представляет собой жидкий раствор белого кристаллического вещества.
Dimacit TMTD-PDR представляет собой органический дисульфид, образующийся в результате формальной окислительной димеризации N,N-диметилдитиокарбаминовой кислоты.
Dimacit TMTD-PDR содержит диметилдитиокарбамат.


Dimacit TMTD-PDR функционально связан с диметилдитиокарбаминовой кислотой.
Dimacit TMTD-PDR зарегистрирован в соответствии с Регламентом REACH и производится и/или импортируется в Европейскую экономическую зону в объеме от ≥ 1 000 до < 10 000 тонн в год.


Dimacit TMTD-PDR представляет собой простейший дисульфид тиурама и окисленный димер диметилдитиокарбамата.
Dimacit TMTD-PDR почти неподвижен в глинистых почвах или в почвах с высоким содержанием органического вещества.
Dimacit TMTD-PDR представляет собой кристаллическое твердое вещество от бесцветного до желтого цвета с характерным запахом.


Dimacit TMTD-PDR следует хранить в сухом и прохладном месте с хорошей вентиляцией, избегая попадания на упакованный продукт прямых солнечных лучей.
Dimacit TMTD-PDR разработан для резиновой промышленности.
Доступны два класса: pdr; пдр-д.


Все сорта от белого до почти белого.
Dimacit TMTD обеспечивает быструю вулканизацию и дает превосходное плато вулканизации с хорошей устойчивостью к тепловому старению и сжатию при использовании в бессернистых вулканизационных системах и системах EV.


Dimacit TMTD-PDR не оставляет пятен и не обесцвечивает.
Dimacit TMTD-PDR — это превосходные цвета, получаемые в нечерных вулканизатах.


Следует отметить, что при применении Dimacit TMTD N-нитрозодиметиламин может образовываться в результате реакции продукта разложения диметиламина с нитрозирующими агентами (оксидами азота).
Dimacit TMTD-PDR представляет собой сероорганическое соединение по коду cas 137-26-8, представляет собой серовато-белый порошок, нерастворимый в воде.


Dimacit TMTD-PDR — химикат для каучука, ускоритель вулканизации.
Dimacit TMTD-PDR представляет собой кристаллическое твердое вещество от бесцветного до желтого цвета.
Dimacit TMTD-PDR имеет характерный запах.


Dimacit TMTD-PDR представляет собой порошок от белого до почти белого цвета.
Dimacit TMTD-PDR представляет собой кристаллы от бесцветного до белого или кремового цвета.
Dimacit TMTD-PDR может темнеть под воздействием воздуха или света.


Dimacit TMTD-PDR представляет собой жидкий раствор белого кристаллического вещества.
Dimacit TMTD-PDR зарегистрирован в соответствии с Регламентом REACH и производится и/или импортируется в Европейскую экономическую зону в объеме от ≥ 1 000 до < 10 000 тонн в год.


Dimacit TMTD-PDR представляет собой порошок белого или светло-серого цвета (гранулированный).
Dimacit TMTD-PDR растворим в бензоле, ацетоне, хлороформе, CS2, частично растворим в спирте, диэтиловом эфире, CCl4, нерастворим в воде, бензине и щелочи с меньшей концентрацией.


Встреча горячей воды превращается в диметиламмоний и CS 2.
Хорошее сохранение цвета достигается при нечерной вулканизации.
Dimacit TMTD-PDR является ценным вторичным ускорителем для EPDM.


Dimacit TMTD-PDR представляет собой белый порошок без запаха.
Плотность Dimacit TMTD-PDR составляет 1,40-1,45 г/см³.
Dimacit TMTD-PDR растворим в бензоле, ацетоне, хлороформе; слабо растворим в этаноле, нерастворим в воде.


Dimacit TMTD-PDR представляет собой белый, светло-серый порошок или гранулы.
Плотность Dimacit TMTD-PDR составляет 1,29.
Встреча горячей воды делается с диметиламином аммония и CS2.


Dimacit TMTD-PDR растворим в бензоле, ацетоне, хлороформе, CS2 частично растворим в спирте, диэтиловом эфире, CCI4 нерастворим в воде, бензине и щелочи с меньшей концентрацией.
Dimacit TMTD-PDR имеет характерный запах.



ПРИМЕНЕНИЕ и ПРИМЕНЕНИЕ DIMACIT TMTD-PDR:
Dimacit TMTD-PDR используется в рецептуре или переупаковке, на промышленных площадках и в производстве.
Dimacit TMTD-PDR используется в следующих продуктах: регуляторах pH и продуктах для обработки воды.
Высвобождение Dimacit TMTD-PDR в окружающую среду может происходить в результате промышленного использования: составление смесей и внесение в материалы.


Dimacit TMTD-PDR используется для производства: резинотехнических изделий.
Выброс Dimacit TMTD-PDR в окружающую среду может происходить в результате промышленного использования: в качестве технологической добавки.
Выброс Dimacit TMTD-PDR в окружающую среду может происходить в результате промышленного использования: производство вещества.


Dimacit TMTD-PDR имеет и другие применения: от местного бактерицида до репеллентов для животных.
Dimacit TMTD-PDR (CAS: 137-26-8), также известный как дисульфид тетраметилтиурама или TMDT, используется в основном как фунгицид, дезинфицирующее и бактериостатическое средство в пищевой промышленности, но также используется в некоторых готовых продуктах.


Dimacit TMTD-PDR широко используется при переработке каучука в качестве ультраускорителя для низкотемпературного отверждения либо отдельно, либо в качестве активатора для других ускорителей, главным образом тиазолов.
Dimacit TMTD-PDR может использоваться в дерматологии в качестве чесоточного средства.


Dimacit TMTD-PDR в основном используется в качестве фунгицида для растений и обработки семян.
Dimacit TMTD-PDR широко используется для фунгицидной обработки семян.
Dimacit TMTD-PDR играет роль антибактериального препарата, антисептического препарата и противогрибкового агрохимиката.


Dimacit TMTD-PDR используется в качестве фунгицида, эктопаразитицида для предотвращения грибковых заболеваний семян и сельскохозяйственных культур, а также в качестве репеллентного средства для защиты фруктовых деревьев и декоративных растений от повреждения кроликами, грызунами и оленями.
Dimacit TMTD-PDR эффективен против стеблевой галлы кориандра, выпревания, головни проса, шейковой гнили лука и т.д.


Dimacit TMTD-PDR использовался при лечении чесотки у людей, в качестве солнцезащитного средства и в качестве бактерицида, наносимого непосредственно на кожу или включаемого в мыло.
Dimacit TMTD-PDR также используется в качестве источника серы и вторичного ускорителя серной вулканизации каучуков.


Dimacit TMTD-PDR традиционно использовался в яблоневом и винодельческом хозяйстве.
С 2010 года большая часть тирама применяется для обработки соевых бобов.
Dimacit TMTD-PDR — ценный вторичный ускоритель.


В модифицированном меркаптаном полихлоропрене, отвержденном с помощью ETU, Dimacit TMTD-PDR действует как замедлитель подвулканизации, не влияя на скорость отверждения.
Dimacit TMTD-PDR используется как первичный или вторичный (ультра) ускоритель в различных смесях.
ускорительные системы с тиазолами и сульфенамидами.


Dimacit TMTD-PDR также используется в качестве вулканизующего агента в большинстве эластомеров, отверждаемых серой.
Dimacit TMTD-PDR обжигает и обеспечивает высокую скорость отверждения.
Dimacit TMTD-PDR обеспечивает отличное плато вулканизации с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии в бессернистых системах и системах отверждения EV.


Превосходное сохранение цвета достигается при нечерной вулканизации.
Dimacit TMTD-PDR является ценным вторичным ускорителем для EPDM.
Dimacit TMTD-PDR можно использовать в качестве замедлителя схватывания при вулканизации полихлоропренового каучука с ETU.


Dimacit TMTD-PDR можно использовать как отдельный ускоритель, как вторичный ускоритель или как донор серы в большинстве эластомеров, отверждаемых серой.
Dimacit TMTD-PDR обеспечивает быструю вулканизацию и дает превосходное плато вулканизации с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии при использовании в бессернистых вулканизационных системах и системах EV.


Dimacit TMTD-PDR используется в качестве вспомогательного агента для каучука.
Dimacit TMTD-PDR можно использовать как отдельный ускоритель, как вторичный ускоритель или как донор серы в большинстве эластомеров, отверждаемых серой. Обжигающий и дает быстрые показатели излечения.


Dimacit TMTD-PDR обеспечивает превосходное плато вулканизации с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии в системах отверждения без содержания серы и EV.
Хорошее сохранение цвета достигается при нечерной вулканизации.
Dimacit TMTD-PDR является ценным вторичным ускорителем для EPDM.


Dimacit TMTD-PDR может использоваться в качестве замедлителя вулканизации полихлоропренового каучука с ETU, а также в качестве бактерицида и пестицида.
Dimacit TMTD-PDR рекомендуется для использования в мягких смесях благодаря способности диспергироваться.
Dimacit TMTD-PDR используется в сельском хозяйстве для предотвращения грибковых заболеваний семян и сельскохозяйственных культур.


Dimacit TMTD-PDR используется при обработке семян отдельно или в сочетании с добавленными инсектицидами или фунгицидами для борьбы с такими болезнями, как Pythium spp, и другими болезнями, такими как Fusarium spp, кукурузы, хлопка, зерновых, бобовых, овощей и декоративных растений.
Dimacit TMTD-PDR используется для дезинфекции семян.


Dimacit TMTD-PDR применяется как антиангинальное средство.
Dimacit TMTD-PDR является эктопаразитицидом.
Dimacit TMTD-PDR используется в сельском хозяйстве для предотвращения грибковых заболеваний семян и сельскохозяйственных культур.


Dimacit TMTD-PDR используется в качестве фунгицида; бактериостат; пестицид; ускоритель вулканизации каучука; скабицид; обеззараживающее средство для семян; отпугиватель животных; инсектицид; присадка к смазочному маслу; консервант для древесины; в антисептических спреях; при смешивании смазочных масел; применяется против серой гнили, ржавчины и ложной мучнистой росы; протравитель семян против «увядания» и вертициллезного увядания; антагонист и отпугиватель этанола в смесях метил-, этил-, пропил- и бутилпроизводных; антиоксидант в полиолефиновых пластмассах; пептизатор в полисульфидных эластомерах; в мылах и репеллентах от грызунов; ореховые, фруктовые, и дезинфицирующее средство от грибов.


Dimacit TMTD-PDR имеет и другие применения: от местного бактерицида до репеллентов для животных.
Используется Dimacit TMTD-PDR Ускоритель каучука; вулканизатор; обеззараживающее средство для семян; фунгицид; бактериостат в мыле; средство от животных.
Dimacit TMTD-PDR представляет собой органический дисульфид, образующийся в результате формальной окислительной димеризации N,N-диметилдитиокарбаминовой кислоты.


Dimacit TMTD-PDR широко используется для фунгицидной обработки семян.
Dimacit TMTD-PDR используется в качестве фунгицида, бактериостата, пестицида, ускорителя вулканизации каучука, скабицида, дезинфицирующего средства для семян, средства от животных, инсектицида, добавки к смазочному маслу и консерванта древесины.


Dimacit TMTD-PDR используется в антисептических спреях и при смешивании смазочных масел.
Dimacit TMTD-PDR используется против серой гнили, ржавчины и ложной мучнистой росы, а также в качестве протравителя семян против выпревания и вертициллезного увядания.
Dimacit TMTD-PDR также используется в качестве антагониста этанола и сдерживающего фактора в смесях производных метила, этила, пропила и бутила.


Другие области применения Dimacit TMTD-PDR включают антиоксидант в полиолефиновых пластмассах и пептизирующий агент в полисульфидных эластомерах.
Dimacit TMTD-PDR используется в мылах и репеллентах от грызунов, а также в качестве дезинфицирующего средства для орехов, фруктов и грибов.
Dimacit TMTD-PDR используется как ускоритель каучука и вулканизатор.


Dimacit TMTD-PDR относится к защитным фунгицидам широкого спектра действия с периодом остаточного действия до 7 дней или около того.
Dimacit TMTD-PDR в основном используется для обработки семян и почвы и предотвращения мучнистой росы, головни и выпревания всходов риса зерновых культур.
Dimacit TMTD-PDR представляет собой защитный фунгицид, наносимый на листву для борьбы с Botrytis spp на винограде, мягких фруктах, салате, овощах и декоративных растениях.


Dimacit TMTD-PDR также можно использовать для борьбы с некоторыми болезнями фруктовых деревьев и овощей.
Например, протравливание семян 500 г 50% смачивающегося порошка может контролировать пирикуляриоз риса, пятнистость рисовых листьев, ячменную и пшеничную головню.
В качестве пестицида Dimacit TMTD-PDR часто называют тирамом, и он в основном используется для обработки семян и почвы, а также для предотвращения и борьбы с мучнистой росой, головней и овощными болезнями зерновых.


Dimacit TMTD-PDR, как суперускоритель натурального каучука, синтетического каучука и латекса, часто называют ускорителем TMTD и является представителем тиурамового ускорителя вулканизации, на долю которого приходится 85% от общего количества аналогичных продуктов.
Ускоритель T также является суперускорителем натурального каучука, диенового синтетического каучука, Ⅱ , R и EPDM с самым высоким коэффициентом использования из всех.


Способствующая вулканизации сила ускорителя Т очень велика, но без присутствия оксида цинка он вообще не вулканизируется.
Dimacit TMTD-PDR используется для производства кабелей, проводов, шин и других резинотехнических изделий.
Dimacit TMTD-PDR используется в качестве суперускорителя натурального каучука, синтетического каучука и латекса.


Dimacit TMTD-PDR применяется для борьбы с вредителями риса, пшеницы, табака, сахарной свеклы, винограда и других культур, а также для протравливания семян и обработки почвы.
Dimacit TMTD-PDR подходит для производства натурального каучука, синтетического каучука и латекса, а также может использоваться в качестве отвердителя.


Dimacit TMTD-PDR является вторым ускорителем из тиазольных ускорителей, который можно использовать с другими ускорителями в качестве ускорителя непрерывной вулканизации.
В резиновой промышленности Dimacit TMTD-PDR можно использовать в качестве ускорителя супервулканизации, а затем использовать с тиазольным ускорителем.
Dimacit TMTD-PDR также контролирует ржавчину на декоративных растениях, паршу и болезни хранения на яблонях и грушах, курчавость листьев и монилию на косточковых плодах.


Его продукция обладает отличной стойкостью к старению и нагреву, поэтому Dimacit TMTD-PDR применим к натуральному каучуку, синтетическому каучуку и в основном используется в производстве шин, камер, обуви, кабелей и других промышленных изделий.
Dimacit TMTD-PDR используется в качестве промотора позднего действия натурального каучука, бутадиенового каучука, стирол-бутадиенового каучука и полиизопренового каучука.


В сельском хозяйстве Dimacit TMTD-PDR можно использовать в качестве фунгицида и инсектицида, а также в качестве присадки к смазочным материалам.
Методы получения из диметиламина, сероуглерода, аммиака реакцией конденсации диметилдитиокарбамата, а затем окислением перекисью водорода до готового продукта.


Dimacit TMTD-PDR используется при составлении рецептур или переупаковке, на промышленных площадках и в производстве.
Dimacit TMTD-PDR используется в следующих продуктах: регуляторах pH и продуктах для обработки воды.
Высвобождение Dimacit TMTD-PDR в окружающую среду может произойти в результате промышленного использования: составление смесей и внесение в материалы.


Выброс Dimacit TMTD-PDR в окружающую среду может происходить в результате промышленного использования: производство вещества.
Dimacit TMTD-PDR можно использовать как отдельный ускоритель, как вторичный ускоритель или как донор серы в большинстве эластомеров, отверждаемых серой.
Dimacit TMTD-PDR является Scorch и обеспечивает высокую скорость отверждения.


Dimacit TMTD-PDR обеспечивает превосходную вулканизацию.
плато с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии в бессернистых системах и системах отверждения EV.
Dimacit TMTD-PDR может использоваться в качестве замедлителя вулканизации полихлоропренового каучука с ETU, а также в качестве бактерицида и пестицида.


Dimacit TMTD-PDR может снижать показатели роста цыплят за счет снижения печеночного индекса, одновременно увеличивая почечный, сердечный и селезеночный индексы, а также индуцировать большеберцовую дисхондроплазию (TD) за счет изменения экспрессии VEGF, HIF-1α и WNT4.
Dimacit TMTD-PDR широко используется в производстве каучука в качестве ультраускорителя низкотемпературного отверждения, а также в сельском хозяйстве в качестве важного пестицида.


Dimacit TMTD-PDR используется в качестве ускорителя каучука или в качестве бактерицида и инсектицида.
Применение Dimacit TMTD-PDR: Модификация резины.
Dimacit TMTD-PDR также можно использовать в сочетании с другими ускорителями в качестве ускорителя непрерывного действия каучука.


Для медленного разложения свободной серы при температуре более 100 ℃ Dimacit TMTD-PDR также может использоваться в качестве отвердителя.
Dimacit TMTD-PDR широко используется при переработке каучука в качестве ультраускорителя низкотемпературного отверждения либо отдельно, либо в качестве активатора для других ускорителей, главным образом тиазолов.


Dimacit TMTD-PDR можно использовать как отдельный ускоритель, как вторичный ускоритель или как донор серы в большинстве эластомеров, отверждаемых серой.
Обжигающий и дает быстрые показатели излечения.
Dimacit TMTD-PDR является ценным вторичным ускорителем для EPDM.


Dimacit TMTD-PDR обеспечивает превосходное плато вулканизации с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии в бессернистых системах и системах отверждения EV. Хорошее сохранение цвета достигается при вулканизации без почернения.
Dimacit TMTD-PDR может использоваться в качестве замедлителя вулканизации полихлоропренового каучука с ETU, а также в качестве бактерицида и пестицида.


-Сельскохозяйственное использование:
*Фунгициды, родентициды:
используется в качестве фунгицида для предотвращения повреждения урожая в поле и предотвращения его порчи при хранении или транспортировке.
Dimacit TMTD-PDR также используется в качестве дезинфицирующего средства для семян, орехов, фруктов и грибов от различных грибковых заболеваний.

Кроме того, Dimacit TMTD-PDR используется в качестве репеллентного средства для защиты фруктовых деревьев и декоративных растений от повреждения кроликами, грызунами и оленями.
Dimacit TMTD-PDR использовался для лечения чесотки у человека, в качестве солнцезащитного средства и в качестве бактерицида, наносимого непосредственно на кожу или включаемого в мыло.

Dimacit TMTD-PDR используется в качестве ускорителя и вулканизатора каучука, а также в качестве бактериостата для пищевых масел и жиров.
Dimacit TMTD-PDR также используется в качестве средства от грызунов, консерванта древесины и может использоваться в смеси смазочных масел. Зарегистрировано для использования в странах ЕС.


-Применения Dimacit TMTD-PDR:
* Резиновая модификация
*Описание продукта


-Dimacit TMTD-PDR можно использовать:
*Без серы (2-4% от массы камеди),
*С серой в сочетании с оксидом цинка и жирной кислотой в качестве активаторов (0,1 - 1% ТМТД от массы камеди),
В сочетании с ускорителями, такими как меркаптобензотиазол (0,25–0,5 TMTD на массу камеди).



РЕАКЦИЯ DIMACIT TMTD-PDR С ВОЗДУХОМ И ВОДОЙ:
Dimacit TMTD-PDR нерастворим в воде.
Dimacit TMTD-PDR разлагается в кислой среде с образованием токсичных продуктов.
разлагается в определенной степени при длительном воздействии тепла, воздуха или влаги.



СВОЙСТВА DIMACIT TMTD-PDR:
Dimacit TMTD-PDR представляет собой белый, светло-серый порошок или гранулы.
Плотность Dimacit TMTD-PDR составляет 1,29.
Dimacit TMTD-PDR растворим в бензоле, ацетоне, хлороформе, CS2 частично растворим в спирте, диэтиловом эфире, CCI4 нерастворим в воде, бензине и щелочи с меньшей концентрацией.



ХИМИЧЕСКИЕ СВОЙСТВА DIMACIT TMTD-PDR:
Dimacit TMTD-PDR представляет собой чистый бесцветный кристалл; нет запаха; т.пл. 155~156°С; относительная плотность 1,29; легко растворим в бензоле, хлороформе (230 г/л), ацетоне (80 г/л), сероуглероде и других органических растворителях; слабо растворим в эфире и этаноле (<10 г/л); нерастворим в воде (30 мг/л); разлагается в кислой среде; промышленные продукты представляют собой белый или светло-желтый порошок с температурой плавления более 146 ℃ .



МЕТОД ПРОИЗВОДСТВА DIMACIT TMTD-PDR:
Получение диметилдитиокарбамата натрия (ДСД): реакция гидрохлорида диметиламина и сероуглерода в присутствии гидроксида натрия может привести к образованию диметиламинодитиокарбамата натрия.
Температура реакции составляет 50~55 ℃ , а значение pH составляет 8~9.

Приготовление тирама: реакция SDD (или дирама) и перекиси водорода в присутствии серной кислоты может дать тирам.
Температуру реакции контролируют на 10 ℃ ниже, а конечное значение pH составляет от 3 до 4.
Хлор также можно использовать вместо перекиси водорода и серной кислоты.

Реакцию проводят в колонне с ситчатыми тарелками, снизу которой вводят разбавленный хлор, а сверху распыляют 5% раствор натрия, что называется методом хлор-воздушного окисления.
Существуют и другие методы, такие как окисление нитрита натрия или электролитическое окисление.



ЧТО ТАКОЕ DIMACIT TMTD-PDR И ГДЕ НАХОДИТСЯ DIMACIT TMTD-PDR?
Dimacit TMTD-PDR используется в качестве фунгицида, бактериостата и пестицида.
Dimacit TMTD-PDR также используется при переработке каучука и смешивании смазочных масел.
Dimacit TMTD-PDR можно найти в таких продуктах, как дезинфицирующие средства для семян, антисептические спреи, репелленты для животных, инсектициды, консерванты для древесины, некоторые виды мыла, средства от грызунов, а также в качестве дезинфицирующего средства для орехов, фруктов и грибов.
Дальнейшие исследования могут выявить дополнительные продукты или промышленное использование Dimacit TMTD-PDR.



ХИМИЧЕСКИЕ СВОЙСТВА DIMACIT TMTD-PDR:
Dimacit TMTD-PDR представляет собой разновидность сернистого фунгицида.
Было обнаружено, что Dimacit TMTD-PDR полностью растворяется в хлороформе, ацетоне и эфире.
Dimacit TMTD-PDR доступен в виде порошка, текучего, смачивающегося порошка, вододиспергируемых гранул и водных суспензий, а также в смесях с другими фунгицидами.



ПРОФИЛЬ РЕАКЦИОННОЙ АКТИВНОСТИ DIMACIT TMTD-PDR:
Dimacit TMTD-PDR несовместим с окислителями и сильными кислотами.
Также несовместим с сильными щелочами и нитрующими агентами.



ФИЗИЧЕСКИЕ И ХИМИЧЕСКИЕ СВОЙСТВА DIMACIT TMTD-PDR:
Номер CAS: 137-26-8
ВНЕШНИЙ ВИД: мелкий белый порошок
Внешний вид: порошок от белого до почти белого цвета
Объемная плотность: +/-0,40
Молекулярная формула: C6H12N2S4
Молекулярный вес: 240,4
Молекулярная формула/молекулярный вес: C6H12N2S4 = 240,42.
Физическое состояние (20 град. C): Твердое
КАС РН: 137-26-8
Регистрационный номер Reaxys: 1725821
Идентификатор вещества PubChem: 125308534
SDBS (спектральная БД АИСТ): 4777
Индекс Мерк (14): 9371
Номер в леях: MFCD00008325
Химическая формула: C6H12N2S4
Молярная масса: 240,42 г•моль-1
Внешний вид: кристаллический порошок от белого до желтого цвета
Запах: Характерный [расплывчатый]
Плотность: 1,29 г/см3

Температура плавления: от 155 до 156 ° C (от 311 до 313 ° F, от 428 до 429 К)
Температура кипения разлагается
Растворимость в воде 30 мг/л
Давление паров 0,000008 мм рт.ст. (20 °C)
Молекулярный вес: 240,4 г/моль
XLogP3-AA: 1,7
Количество доноров водородной связи: 0
Количество акцепторов водородной связи: 4
Количество вращающихся связей: 3
Точная масса: 239,98833309 г/моль
Масса моноизотопа: 239,98833309 г/моль
Площадь топологической полярной поверхности: 121 Å ²
Количество тяжелых атомов: 12
Официальное обвинение: 0
Сложность: 158
Количество атомов изотопа: 0
Определенное число стереоцентров атома: 0
Количество стереоцентров неопределенного атома: 0
Определенное число стереоцентров связи: 0
Неопределенный счетчик стереоцентров связи: 0
Количество ковалентно-связанных единиц: 1
Соединение канонизировано: Да

Внешний вид: порошок
Физическое состояние: твердое
Растворимость: Растворим в CHCl3: 50 мг/мл.
Хранение: Хранить при комнатной температуре
Температура плавления: 156-158°C (лит.)
Плотность: 1,43 г/см3 при 20°С
Показатель преломления: n20D 1,68 (прогноз)
Значения pK: pKb: 0,87 (прогнозировано)
Внешний вид: порошок
Цвет: белый, светло-коричневый
Запах: без запаха
Порог восприятия запаха: не определено
pH: 6,75 (20 °C)
Концентрация: 4 %
Точка плавления/диапазон: 144–146 °C.
Точка кипения/диапазон кипения: 165 °C
Температура вспышки : Не применимо
Скорость испарения: не определено
Воспламеняемость (твердое вещество, газ): не самовоспламеняется
Самовоспламенение: 400 °C

Верхний предел взрываемости / Верхний предел воспламеняемости: не определено
Нижний предел взрываемости / Нижний предел воспламеняемости: не определено
Давление паров: 0,00002 Па (25 °C)
Относительная плотность паров: не определено
Относительная плотность : Нет данных
Плотность: 1,36 г/см3 (20 °C)
Растворимость(и)
Растворимость в воде: 0,018 г/л (20 °C)
Коэффициент распределения: октанол/вода: log Pow: 1,84
Температура самовоспламенения: не определено
Температура разложения: 165 °C
Вязкость
Вязкость, динамическая : не определено
Вязкость, кинематическая : Неприменимо
Взрывоопасные свойства : Нет данных
Окислительные свойства : Не классифицируется
Поверхностное натяжение: 71,5 мН/м, 20 °C

Физическое состояние: порошок
Цвет: бежевый
Запах: без запаха
Температура плавления/замерзания:
Точка плавления/диапазон: 156–158 °C – лит.
Начальная точка кипения и интервал кипения: данные отсутствуют.
Воспламеняемость (твердое тело, газ): Продукт негорючий.
Верхний/нижний пределы воспламеняемости или взрываемости: Данные отсутствуют.
Температура вспышки: 150,00 °C - открытый тигель
Температура самовоспламенения: Данные отсутствуют
Температура разложения: Данные отсутствуют.
pH: 6,75 при 20 °C
Вязкость
Вязкость, кинематическая: Нет данных
Вязкость, динамическая: Данные отсутствуют
Растворимость в воде 0,017 г/л при 20 °С
Коэффициент распределения: н-октанол/вода: log Pow: 2,1
Давление паров: данные отсутствуют
Плотность 1,36 г/см3 при 20 °С
Относительная плотность Данные отсутствуют
Относительная плотность паров: данные отсутствуют
Характеристики частиц: данные отсутствуют
Взрывоопасные свойства: Не взрывоопасен
Окислительные свойства: нет

Другая информация по безопасности:
Растворимость в других растворителях:
Ацетон 69,7 г/л при 25 °C
Бензол 41,2 г/л при 25 °С
Поверхностное натяжение 70 мН/м при 21,5 °C
Константа диссоциации 8,19 при 25 °С
Молекулярная форма: C6H12N2S4
Внешний вид: твердое вещество от белого до почти белого цвета
Мол. Вес: 240,43
Хранение: 2-8°C в холодильнике
Условия доставки: окружающая среда
Приложения: нет данных
Внешний вид: белое кристаллическое твердое вещество (оценка)
Анализ: от 95,00 до 100,00
Внесен в Кодекс пищевых химикатов: Нет
Температура плавления: 155,60°С. при 760,00 мм рт.ст.
Температура кипения: 307,40°С. @ 760,00 мм рт.ст. (расчетное)
Давление паров: 1,720000 мм рт.ст. при 25,00 °C. (стандартное восточное время)
Температура вспышки: 283,00 °F. TCC (139,70 ° C) (оценка)

logP (м/в): 1,730
Растворим в: воде, 30 мг/л при 25 °C (эксп.)
Молекулярный вес : 240,43
Точная масса : 240,43
БРН : 1725821
Номер ЕС : 205-286-2
Код HS : 29303000
Характеристики PSA : 121
XLogP3 : 1,7
Плотность : 1,29 г/см3 при температуре: 20 °C
Температура плавления : 155-156 °C
Точка кипения : 129 °C при давлении: 20 Торр
Температура вспышки : 89°C
Показатель преломления : 1,677
Растворимость в воде : H2O: 16,5 мг/л (20 ºC)
Условия хранения : 0-6°C
Давление паров : 0,000008 мм рт.ст.



МЕРЫ ПЕРВОЙ ПОМОЩИ DIMACIT TMTD-PDR:
-Описание мер первой помощи:
*Общие рекомендации:
Проконсультируйтесь с врачом.
Покажите этот паспорт безопасности материала лечащему врачу.
*При вдыхании:
При вдыхании вывести пострадавшего на свежий воздух.
Проконсультируйтесь с врачом.
*При попадании на кожу:
Смыть большим количеством воды с мылом.
Проконсультируйтесь с врачом.
*При попадании в глаза:
Тщательно промойте большим количеством воды в течение не менее 15 минут и обратитесь к врачу.
* При проглатывании:
Прополоскать рот водой.
Проконсультируйтесь с врачом.
- Указание на необходимость немедленной медицинской помощи и специального лечения:
Данные недоступны



МЕРЫ ПРИ СЛУЧАЙНОМ ВЫБРОСЕ DIMACIT TMTD-PDR:
- Экологические меры предосторожности:
Предотвратите дальнейшую утечку или разлив, если это безопасно.
Не допускайте попадания продукта в канализацию.
Следует избегать выброса в окружающую среду.
-Методы и материалы для локализации и очистки:
Подметать и сгребать.
Хранить в подходящих закрытых контейнерах для утилизации.



ПРОТИВОПОЖАРНЫЕ МЕРЫ DIMACIT TMTD-PDR:
-Средства пожаротушения:
*Подходящие средства пожаротушения:
Используйте распыление воды, спиртостойкую пену, сухой химикат или углекислый газ.
-Дальнейшая информация:
Данные недоступны



КОНТРОЛЬ ВОЗДЕЙСТВИЯ/СРЕДСТВА ИНДИВИДУАЛЬНОЙ ЗАЩИТЫ DIMACIT TMTD-PDR:
-Параметры управления:
--Ингредиенты с параметрами контроля рабочего места:
-Средства контроля воздействия:
--Средства индивидуальной защиты:
* Защита глаз/лица:
Маска для лица и защитные очки.
* Защита кожи:
Обращайтесь в перчатках.
Вымойте и высушите руки.
Полный контакт:
Материал: Нитриловый каучук
Минимальная толщина слоя: 0,11 мм
Время прорыва: 480 мин.
Всплеск контакта:
Материал: Нитриловый каучук
Минимальная толщина слоя: 0,11 мм
Время прорыва: 480 мин.
* Защита тела:
Полный костюм для защиты от химикатов.
-Контроль воздействия окружающей среды:
Предотвратите дальнейшую утечку или разлив, если это безопасно.
Не допускайте попадания продукта в канализацию.
Следует избегать выброса в окружающую среду.



ОБРАЩЕНИЕ И ХРАНЕНИЕ DIMACIT TMTD-PDR:
-Советы по безопасному обращению:
Тщательно мойте после обработки.
-Условия безопасного хранения:
Держите плотно закрытым.
Хранить в сухом, прохладном и хорошо проветриваемом месте.
Используйте только взрывозащищенное оборудование.



СТАБИЛЬНОСТЬ и РЕАКЦИОННАЯ СПОСОБНОСТЬ DIMACIT TMTD-PDR:
-Реактивность:
Данные недоступны
-Химическая стабильность:
Стабилен пр�� соблюдении рекомендуемых условий хранения.
-Возможность опасных реакций:
Данные недоступны
-Условия, чтобы избежать:
Данные недоступны
-Несовместимые материалы:
Данные недоступны



СИНОНИМЫ:
Тетраметилтиурамдисульфид
Тетраметилтиурам дисульфид
Бис (диметилдитиокарбамоил) дисульфид
Тирам
Тиурам
Тетраметилтиурам дисульфид
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Тетраметилтиурам дисульфид
137-26-8
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кв. 1489
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RCRA номер отходов U244
Защитное средство для семян Flo Pro T
Тетраметилтиурам бисульфид
Тетраметилтиурандисульфид
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НБК-1771
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Касвелл № 856
альфа, альфа'-дитиобис(диметилтио)формамид
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N,N,N',N'-тетраметилтиурамдисульфид
C6H12N2S4
N,N-тетраметилтиурам дисульфид
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Тиопероксидикарбоновый диамид, тетраметил-
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диметилкарбамотиоилсульфанил N,N-диметилкарбамодитиоат
Заправа Насиенна Т
[Me2NC(S)S]2
Вансида тм-95
Дисульфуродитетраметилтиоурам
Арасан 42С
Тирам [ISO]
Атака [противогрибковое]
ТУЭКС
КРИС 1282
ХДБ 863
ЛОР 987
НСК1771
Тирам [USAN:INN]
СНБ 1771
ВУАгТ-И-4
ИНЭКС 205-286-2
НСК 49512
СНБ 59637
НСК-49512
Тиопероксидикарбоновый диамид ([(H2N)C(S)]2S2), тетраметил-
RCRA отходов нет. U244
Химический код пестицида EPA 079801
СНБ 622696
НСК-622696
[дисульфандиилбис(карбонотиоилнитрил)]тетраметан
БРН 1725821
реногран
Ускоритель каучука Тиурам М
УНИИ-0D771IS0FH
АИ3-00987
МЛС000069752
МЛС002702972
0D771IS0FH
ЧЕБИ:9495
Тиурамдисульфид, тетраметил-
Тиурам-М
Тиопероксидикарбоновый диамид (((H2N)C(S))2S2), тетраметил-
NSC49512
CCG-35460
НСК-59637
NSC622696
ТНТД
SQ-1489
NCGC00091563-01
SMR000059023
Тиопероксидикарбоновый диамид ((H2N)C(S))2S2, тетраметил-
[дитиобис(карбонотиоилнитрил)]тетраметан
ЕС 205-286-2
.альфа.,.альфа.'-дитиобис(диметилтио)формамид
4-04-00-00242 (Справочник Beilstein)
DTXCID401332
69193-86-8
N,N-диметил[(диметилкарбамотиоил)дисульфанил]карботиоамид
N,N',N'-тетраметилтиурамдисульфид
ТМТ Дисульфид
Тиопероксидикарбоновый диамид (((H2N)C(S))2S2), N,N,N',N'-тетраметил-
КАС-137-26-8
Формамид, 1'-дитиобис(N,N-диметилтио-
Бис[(диметиламино)карбонотиоил] дисульфид
NSC59637
WLN: 1N1, ЮС, ССЮС, N1 и 1
тирамо
Тиопероксидикарбоновый диамид [(H2N)C(S)]2S2, тетраметил-
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Авангард ГФ
Ванцид ТМ
Акрохем ТМТД
Perkacit TMTD
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Робак ТМТ
Тирам (Tmtd)
Резифильм (ТН)
Арасан 50 красный
Спотрете WP 75
MFCD00008325
Ванцид ТМ-95
Нафтоцит тиурам 16
Тирам [BSI:ISO]
Спектр_001687
Тирам (USAN/INN)
Текучий тирам Agrichem
THR (Код КРИС)
ТИРАМ [HSDB]
ТИРАМ [IARC]
ТИРАМ [INCI]
ТИРАМ [США]
ТИРАМ [INN]
Спектр2_001554
Спектр3_001592
Спектр4_000860
Спектр5_001653
ТИРАМ [WHO-DD]
ТИРАМ [MI]
ТИРАМ [МАРТ.]
бмсе000928
D02UVS
NCIMech_000272
cid_5455
NCIOpen2_007854
SCHEMBL21144
BSPBio_003184
KBioGR_001499
KBioSS_002167
СТАВКА:ER0359
DivK1c_000741
СПЕКТР1503322
SPBio_001428
КЕМБЛ120563
Тирам [США:INN:BSI:ISO]
Тирам [США:INN:ISO:BSI]
БДБМ43362
HMS502F03
KBio1_000741
KBio2_002167
KBio2_004735
KBio2_007303
KBio3_002684
КУАЗQDVKQLNFPE-UHFFFAOYSA-
ENT-987
NINDS_000741
HMS1922A12
HMS2093E03
HMS2234B08
HMS3374C05
Фармакон1600-01503322
Тетраметилтиурамдисульфид, 97%
Токс21_111150
Токс21_201569
Токс21_301102
ЛС-803
NSC758454
с2431
STL264104
(диметиламино){[(диметиламино)тиоксометил]дисульфанил}метан-1-тион
АКОС000120200
бис (диметилтиокарбамоил) дисульфид
Бис(диметиламинотиокарбонил)дисульфид
Дисульфид, бис(диметилтиокарбамоил)-
Токс21_111150_1
бис (диметиламинотиокарбонил) дисульфид
ДБ13245
КС-5354
НСК-758454
Тетраметилтиопероксидикарбоновый диамид
IDI1_000741
QTL1_000082
NCGC00091563-02
NCGC00091563-03
NCGC00091563-04
NCGC00091563-05
NCGC00091563-06
NCGC00091563-07
NCGC00091563-08
NCGC00091563-09
NCGC00091563-10
NCGC00091563-12
NCGC00255002-01
NCGC00259118-01
NCI60_001477
NCI60_006736
ВОБ-0051813.P002
Тирам, PESTANAL®, аналитический стандарт
B0486
CS-0012858
FT-0631799
EN300-16677
D06114
D97716
AB00052345_10
Тирам; (тетраметилтиопероксидикарбоновый диамид)
Q416572
СР-01000736911
J-006992
J-524968
СР-01000736911-2
Тирам, сертифицированный эталонный материал, TraceCERT(R)
БРД-К29254801-001-06-3
Z56754480
F0001-0468
ТЕТРАМЕТИЛТИОПЕРОКСИДИКАРБОНОВАЯ КИСЛОТА [(H2N)C(S)]2S2
N,N-диметил[(диметилкарбамотиоил)-дисульфанил]карботиоамид
1-(диметилтиокарбамоилдисульфанил)-N,N-диметилметантиоамид
Сложный эфир N,N-диметилкарбамодитиовой кислоты (диметилтиокарбамоилтио)
Diamida Tioperoxidicarbonica ([(H2N) C (S)] 2S2), N,N,N',N'-тетраметил-
N(1),N(1),N(3),N(3)-тетраметил-2-дитиоперокси-1,3-дитиодикарбоновый диамид
[[диметиламино(сульфанилиден)метил]тио]эфир N,N-диметилкарбамодитиовой кислоты
ТЕТРАМЕТИЛТИОПЕРОКСИДИКАРБОДИАМИД ((((CH(SUB 3))(SUB 2)N)C(S))(SUB 2)S(SUB 2))
Бис(диметилтиокарбамоил)дисульфид
Тетраметилтиурам дисульфид
ТМТД
N,N,N',N'-тетраметилтиопероксидикарбоновый диамид
Тиопероксидикарбоновый диамид ([(H2N)C(S)]2S2), N,N,N',N'-тетраметил-
ААТИРАМ
АРАСАН(Р)
БИС(ДИМЕТИЛТИОКАРБАМОЙЛ) ДИСУЛЬФИД
БИС(ДИМЕТИЛТИОКАРБАМИЛ) ДИСУЛЬФИД
CEKUTMTD
ДЕЛЬСАН(R)
ДИМЕТИЛ ТИУРАМА ДИСУЛЬФИД
МЕРКУРАМ(R)
МЕТИЛ ТИУРАМ
МЕТИЛ ТУАДС
НОМЕРСАН(R)
ПОМАРСОЛ
ПОМАРСОЛ(R)
ПОМАСОЛ(R)
ПУРАЛИН(R)
РЕЗИФИЛЬМ(R)
РОДИАЗОН
СПОТРЕТЕ(R)
ТЕРСАН(R)
ТЕТРАМЕТИЛТИУРАМА ДИСУЛЬФИД
Бис(диметилтиокарбамоил)дисульфид
Тетраметилтиурам дисульфид
ТМТД
N,N,N',N'-тетраметилтиопероксидикарбоновый диамид
Тиопероксидикарбоновый диамид ([(H2N)C(S)]2S2),N,N,N',N'-тетраметил-
Дисульфид, бис (диметилтиокарбамоил)
Тиопероксидикарбоновый диамид ([(H2N)C(S)]2S2), тетраметил-
кв. 1489
Ускоритель Тиурам; Ацето ТЭТД
Арасан М
Арасан
Арасан-СФ
Бис (диметилтиокарбамоил) дисульфид
Бис(диметилтиокарбамил) дисульфид
Фернасан
Фернасан А
Hermal
Херил
Меркурам
Метилтирам
Нормерсан
Панорама 75
Помарсол
Помасол
пуралин
Резифильм
Королевский ТМТД
Спотрете
Терсан
Тетраметилтиурам бисульфид
N,N,N',N'-тетраметилтиурамдисульфид
Тетраметилтиурам дисульфид
Тетраметилтиурам дисульфид
Тиосан
Тирам
Тирам 75
Тиурад
Тиурам
Тиурам М
Тиурамдисульфид, тетраметил-
Тиурамил
Тиурамил
ТМТД
ТМТДС
Тилат
Тридипам
Туадс
Тулисан
Арасан 75
Ферниде
Крегасан
Полирам ультра
Садоплон
Тетрасиптон
Тиулин
Трипомол
ВУАгТ-И-4
Тиурам Д
Тиотокс
тиллат
Арасан 42С
Тирасан
Арасан 70
Экагом ТБ
Нобекутан
Вулкафор ТМТД
Вулкацит Th
Садоплон 75
Ускоритель Т
Траметан
Гексатир
Заправа Насиенна Т
Аатирам
Тирам 80
Вулкафор ТМТ
Вулкацит тиурам
Гермат ТМТ
Тирам Б.
Апирол
Атирам
Фалитирам
Формалсол
тиоскабин
Арасан 70-С Красный
Тутан
Ускорение ТМТ
Тирадин
Терсан 75
Пол-Тиурам
ТМТ
ТУЭКС
Тигам
Реногран ТМТД
Метиурак
Носелер ТТ
Родиаурам
Тиотокс (фунгицид)
Ускоритель Т
Ферна-Кол
Метил Туадс
Арасан 50 красный
Радотирам
Радотирам
Триде
Тиурам ТМТД
Тетраметилтиопероксидикарбоновый диамид
Зупа С 80
Бетоксин
Робак ТМТ
Помарсол Форте
12680-07-8
12680-62-5
39456-80-9
56645-31-9
66173-72-6
92481-09-9
93196-73-7
200889-05-0
1135443-08-1
2213445-87-3
ТТ
тмтд
ТМТД
анлес
тирам
арасан
аапирол
Аапирол
ускорение тмт
ацетотд
арасан 70
Ускорение ТМТ
арасан 75
ацето тетд
арасан 42с
арасан42-с
ускоритель
тирам (tmtd)
ускоритель т
тирам (tmtd)
Ускоритель Т
арасан 70-х красный
ускорительtmtd
ускорительтиурам
ускоритель тиурам
Ускоритель Тиурам
Резиновый ускоритель ТМТД
Тетраметилтиурам дисульфид
тетраметилтиурамдисульфид
тетраметилтиурам дисульфид
бис (диметилтиокарбамоил) дисульфид
бис (диметилтиокарбамил) дисульфид
тетраметилтиопероксидикарбоновый диамид
1,1'-дитиобис(н,н-диметилтиоформамид
1,1'-дитиобис(н,н-диметилтиоформамид
1,1'-дитиобис(н,н-диметилтиоформамид)
1,1'-дитиобис(н,н-диметилтиоформамид)
альфа, альфа'-дитиобис(диметилтио)формамид
[дисульфандиилбис(карбонотиоилнитрил)]тетраметан
тирам
Dimacit TMTD-PDR
тиурам
тмтд, помарсол
тираме
арасан
фернасан
нобекутан
резифильм
Бис (диметилтиокарбамоил) дисульфид
Бис(диметилтиокарбамил) дисульфид
Тирам
1,1'-дитиобис(N,N-диметилтиоформамид)
Чипко Тирам 75
Спотрете
Тетрапом
Бис((диметиламино)углерод
Фермид 850,
кв. 1489
Таймер
Бис(диметилтиокарбамил)дисульфид
Фернасан
Терсан
Тиокнок
Тетраметилтиопероксидикарбоновый диамид,
Гексатир
Тиосан
Тиотекс
Dimacit TMTD-PDR
Меркурам
Тиурад
Тирамад
Тетраметилтиурам бисульфид
Номерсан
Тиурамил
Тирасан
Атака
Полирам-Ультра
Тилат
тиурамин
Ацето тетд
Помарсол
Тиурамил
Тирампа
Арасан
пуралин
ТМТД
ТМТДС
Трипомол
Аулес
Резифильм
Тулисан
Ванцид ТМ.
Тетраметилтиурамдисульфид
Бис (диметилдитиокарбамоил) дисульфид
Тирам
Тиурам
ТМТД
ТИРАМ
1,1'-дитиобис(н,н-диметилтиоформамид
ТИУРАМ
ТЕТРАМЕТИЛТИУРАМА ДИСУЛЬФИД
Тетраметилтиурам
ТНТД
МЕТИЛ ТУАДС
АкселераторTMTD
ТИМТЕК-ВВ SBB000804
1,1'-дитиобис(N,N-диметилтиоформамид)
Чипко Тирам 75
Спотрете
Тетрапом
Бис((диметиламино)углерод
Фермид 850
кв. 1489
Таймер
Бис(диметилтиокарбамил)дисульфид
Фернасан
Терсан
Тиокнок
Тетраметилтиопероксидикарбоновый диамид
Гексатир
Тиосан
Тиотекс
Dimacit TMTD-PDR
Меркурам
Тиурад
Тирамад
Тетраметилтиурам бисульфид
Номерсан
Тиурамил
Тирасан
Полирам-Ультра
Тилат
тиурамин
Ацето тетд
Помарсол
Тиурамил
Тирампа
Арасан
пуралин
ТМТД
ТМТДС
Трипомол
Аулес
Резифильм
Тулисан, Ванцид ТМ.
бис (диметилтиокарбамил) дисульфид
тирам
тирам (tmtd)
тмтд
тирам (tmtd)
тетраметилтиурам дисульфид
тетраметилтиурамдисульфид
1,1'-дитиобис(н,н-диметилтиоформамид
1,1'-дитиобис(н,н-диметилтиоформамид)
аапирол
ускорение тмт
ускоритель т
ускоритель тиурам
ускоритель
ускорительтиурам
ускорительtmtd
ацето тетд
ацетотд
альфа, альфа'-дитиобис(диметилтио)формамид
анлес
арасан
арасан 42с
арасан 70
арасан 70-х красный
арасан 75
арасан42-с
бис (диметилтиокарбамоил) дисульфид
тетраметилтиопероксидикарбоновый диамид
[дисульфандиилбис(карбонотиоилнитрил)]тетраметан
Резиновый ускоритель ТМТД
ТМТД
Тетраметилтиурамдисульфид
УСКОРИТЕЛЬ ТТ
Ускоритель ТМТД
УСКОРИТЕЛЬ ТМТД(ТТ)

ОПИСАНИЕ:
DIMACIT TMTD-PDR обеспечивает быструю вулканизацию и дает превосходное плато вулканизации с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии при использовании в бессернистых вулканизационных системах и системах EV.
DIMACIT TMTD-PDR — ценный вторичный ускоритель.
В модифицированном меркаптаном полихлоропрене, отвержденном с помощью ETU, DIMACIT TMTD-PDR действует как замедлитель подвулканизации, не влияя на скорость отверждения.



ТИПИЧНЫЕ СВОЙСТВА DIMACIT TMTD-PDR:
Внешний вид: порошок от белого до почти белого цвета
Объемная плотность: +/-0,50
Молекулярная формула: C6H12N2S4
Молекулярный вес: 240,4
Внешний вид: порошок
Цвет: белый, светло-коричневый
Запах: без запаха
pH: 6,75, 4 % (20 °C)
Точка плавления/диапазон: 144–146 °C.
Точка кипения/диапазон кипения: 165 °C
Воспламеняемость (твердое вещество, газ): не самовоспламеняется
Давление паров: 0,00002 Па (25 °C)
Плотность: 1,36 г/см3 (20 °C)
Растворимость(и):
Растворимость в воде: 0,018 г/л (20 °C)
Коэффициент распределения: октанол/вода: log Pow: 1,84
разложения : 165 °C
Поверхностное натяжение: 71,5 мН/м, 20 °C

DIMACIT TMTD-PDR рекомендуется для использования в мягких смесях благодаря способности диспергироваться.
DIMACIT TMTD-PDR не оставляет пятен и не обесцвечивает.
Отличные цвета получаются в нечерных вулканизатах.
DIMACIT TMTD-PDR обеспечивает быструю вулканизацию и дает превосходное плато вулканизации с хорошей стойкостью к тепловому старению и остаточной деформации при сжатии при использовании в бессернистых вулканизационных системах и системах EV.

Следует отметить, что при применении DIMACIT TMTD-PDR N-нитрозодиметиламин может образовываться в результате реакции продукта разложения диметиламина с нитрозирующими агентами (оксидами азота).

ПРИМЕНЕНИЕ DIMACIT TMTD-PDR:
DIMACIT TMTD-PDR используется в качестве добавок к резине и пластмассам.
DIMACIT TMTD-PDR используется в модификации резины.

ХРАНЕНИЕ DIMACIT TMTD-PDR:
Хранить в сухом хорошо проветриваемом месте вдали от пищевых продуктов.
После хранения в оригинальной упаковке в течение 2 лет при нормальных условиях снижения содержания активного вещества не наблюдалось.
Двойная укладка материала на поддонах может привести к необычному уплотнению продукта.

В случае случайной утечки пролитый продукт следует собрать для сжигания.
Немедленно уведомить соответствующие органы в случае любого риска загрязнения водотоков.
Защищать от кислот и веществ, выделяющих кислоты.



ИНФОРМАЦИЯ ПО БЕЗОПАСНОСТИ О DIMACIT TMTD-PDR:
Меры первой помощи:
Описание мер первой помощи:
Общий совет:
Проконсультируйтесь с врачом.
Покажите этот паспорт безопасности лечащему врачу.
Выйти из опасной зоны:

При вдыхании:
При вдыхании вывести пострадавшего на свежий воздух.
Если нет дыхания проведите искусственную вентиляцию легких.
Проконсультируйтесь с врачом.
При попадании на кожу:
Немедленно снять загрязненную одежду и обувь.
Смыть большим количеством воды с мылом.
Проконсультируйтесь с врачом.

При попадании в глаза:
Тщательно промойте большим количеством воды в течение не менее 15 минут и обратитесь к врачу.
Продолжайте промывать глаза во время транспортировки в больницу.

При проглатывании:
Не вызывает рвоту.
Никогда не давайте ничего в рот человеку, находящемуся без сознания.
Прополоскать рот водой.
Проконсультируйтесь с врачом.

Противопожарные меры:
Средства пожаротушения:
Подходящие средства пожаротушения:
Используйте водяной спрей, спиртостойкую пену, сухой химикат или двуокись углерода.
Особые опасности, исходящие от вещества или смеси
Оксиды углерода, Оксиды азота (NOx), Газообразный хлористый водород

Совет пожарным:
При необходимости наденьте автономный дыхательный аппарат для тушения пожара.
Меры по случайному выбросу:
Индивидуальные меры предосторожности, защитное снаряжение и порядок действий в чрезвычайных ситуациях
Используйте средства индивидуальной защиты.

Избегайте вдыхания паров, тумана или газа.
Эвакуируйте персонал в безопасные зоны.

Меры предосторожности в отношении окружающей среды:
Предотвратите дальнейшую утечку или разлив, если это безопасно.
Не допускайте попадания продукта в канализацию.
Следует избегать выброса в окружающую среду.

Методы и материалы для локализации и очистки:
Впитать инертным абсорбирующим материалом и утилизировать как опасные отходы.
Хранить в подходящих закрытых контейнерах для утилизации.

Обращение и хранение:
Меры предосторожности для безопасного обращения:
Избегайте вдыхания паров или тумана.

Условия для безопасного хранения, включая любые несовместимости:
Хранить контейнер плотно закрытым в сухом и хорошо проветриваемом месте.
Контейнеры, которые открываются, должны быть тщательно запечатаны и храниться в вертикальном положении, чтобы предотвратить утечку.
Класс хранения (TRGS 510): 8A: Горючие, коррозионно-опасные материалы

Контроль воздействия / личная защита:
Параметры управления:
Компоненты с параметрами контроля рабочего места
Не содержит веществ с ПДК на рабочем месте.
Средства контроля воздействия:
Соответствующие инженерные средства контроля:
Обращайтесь в соответствии с правилами промышленной гигиены и техники безопасности.
Мойте руки перед перерывами и в конце рабочего дня.

Средства индивидуальной защиты:
Защита глаз/лица:
Плотно прилегающие защитные очки.
Маска для лица (минимум 8 дюймов).
Используйте средства защиты глаз, проверенные и одобренные в соответствии с соответствующими государственными стандартами, такими как NIOSH (США) или EN 166 (ЕС).

Защита кожи:
Обращайтесь в перчатках.
Перчатки должны быть проверены перед использованием.
Используйте подходящую перчатку
метод удаления (не касаясь внешней поверхности перчатки), чтобы избежать контакта с кожей с этим продуктом.
Утилизируйте загрязненные перчатки после использования в соответствии с применимыми законами и передовой лабораторной практикой.
Вымойте и высушите руки.

Полный контакт:
Материал: Нитриловый каучук
Минимальная толщина слоя: 0,11 мм
Время прорыва: 480 мин.
Испытанный материал: Дерматрил (KCL 740 / Aldrich Z677272, размер M)
Заставка контакта
Материал: Нитриловый каучук
Минимальная толщина слоя: 0,11 мм
Время прорыва: 480 мин.
Испытанный материал: Дерматрил (KCL 740 / Aldrich Z677272, размер M)
Его не следует рассматривать как предложение одобрения для какого-либо конкретного сценария использования.

Защита тела:
Полный костюм, защищающий от химических веществ. Тип средств защиты необходимо выбирать в зависимости от концентрации и количества опасного вещества на конкретном рабочем месте.
Защита органов дыхания:
Там, где оценка риска показывает, что воздухоочистительные респираторы уместны, используйте полнолицевые респираторы с многоцелевыми комбинированными (США) или респираторными картриджами типа ABEK (EN 14387) в качестве резерва средств технического контроля.

Если респиратор является единственным средством защиты, используйте полнолицевой респиратор с подачей воздуха.
Используйте респираторы и компоненты, проверенные и одобренные в соответствии с соответствующими государственными стандартами, такими как NIOSH (США) или CEN (ЕС).
Контроль воздействия окружающей среды
Предотвратите дальнейшую утечку или разлив, если это безопасно.
Не допускайте попадания продукта в канализацию.
Следует избегать выброса в окружающую среду.

Стабильность и химическая активность:
Химическая стабильность:
Стабилен при соблюдении рекомендуемых условий хранения.
Несовместимые материалы:
Сильные окислители:
Опасные продукты разложения:
Опасные продукты разложения, образующиеся в условиях пожара.
Оксиды углерода, Оксиды азота (NOx), Газообразный хлористый водород.

Утилизация отходов:
Методы обработки отходов:
Продукт:
Предложите излишки и неперерабатываемые решения лицензированной компании по утилизации.
Обратитесь в лицензированную профессиональную службу по утилизации отходов, чтобы утилизировать этот материал.
Загрязненная упаковка:
Утилизируйте как неиспользованный продукт.


ХИМИЧЕСКИЕ СИНОНИМЫ DIMACIT TMTD-PDR:
Тетраметилтиурам дисульфид
Бис (диметилдитиокарбамоил) дисульфид
Тирам
Тиурам

Mirasil DM 20; Belsil DM 100; Belsil DM 1000; Clearocast 10; DIMETICONE 350; SILICONE FLUID; DIMETICONUM 350; DIMETHICONE 350; DiMethicone 245; Dow Corning 365; Dow Corning 1413; Dow Corning 1664; Belsil DM 1 Plus; Dow Corning- 664; Dimethicone (nf); DIMETHICONE 1000; DIMETHYL SILICONE; POLYMETHYLSILOXANE; VISCOSITY STANDARD; Sentry dimethicone; Dow Corning 5-2117; Dow Corning 5-7137; Dow Corning 5-7139; SILICONE OIL DC 200; POLYDIMETHYLSILOXAN; DIMETHICONE COPOLYOL; Dimeticone (jan/inn); Dow Corning 200/10CST; Dow Corning 200/5 cst; Dow Corning 100-350CS; Vinyl-terminated PDMS; Sentry dimethicone (tn); POLYDIMETHYLSILOXANE GUM; POLYDIMETHYLSILOXANE 311; dimethicone macromolecule; POLYDIMETHYLSILOXANE 3'320; POLYDIMETHYLSILOXANE 7'100; POLYDIMETHYLSILOXANE 1'850; Dow Corning 200 Fluid 5cSt; POLYDIMETHYLSILOXANE 16'000; POLYDIMETHYLSILOXANE 71'000; POLYDIMETHYLSILOXANE 89'800; POLYDIMETHYLSILOXANE 47'500; POLYDIMETHYLSILOXANE 25'800; POLYDIMETHYLSILOXANE 303'000; POLYDIMETHYLSILOXANE 173'000; POLYDIMETHYLSILOXANE 197'000; POLYDIMETHYLSILOXANE 158'000; Dow Corning 200/100 cSt Fluid; Dow Corning 200 Fluid 350 c/s; DIMETHYLPOLYSILOXANE,TECHNICAL; EIGHT-ARM POLY(DIMETHYL SILOXANE); SILCOREL(R) ADP1000 ANTIFOAM COMPOUND; REDUCED VOLATILITY POLYDIMETHYLSILOXANE; Dow Corning 365 DiMethicone NF EMulsion; (Methoxy-dimethylsilyl)-trimethylsilane; POLY(DIMETHYLSILOXANE), METHYL TERMINATED; EXTREME LOW VOLATILITY POLYDIMETHYLSILOXANE; DOW CORNING 346 EMULSION SINGLE RELEASE AGENT; Polydimethylsiloxane trimethylsiloxy-terminated; POLYDIMETHYLSILOXANE, BRANCHED, METHYL TERMINATED; Silicone Fluid, High TeMperature Heat Transfer Fluid CAS NO:9006-65-9

DIMETHICONE 100 Polydimethylsiloxane (PDMS) DIMETHICONE 100, also known as dimethylpolysiloxane or dimethicone, belongs to a group of polymeric organosilicon compounds that are commonly referred to as silicones.[1] PDMS is the most widely used silicon-based organic polymer due to its versatility and properties leading to a manifold of applications.[2] It is particularly known for its unusual rheological (or flow) properties. PDMS is optically clear and, in general, inert, non-toxic, and non-flammable. It is one of several types of silicone oil (polymerized siloxane). Its applications range from contact lenses and medical devices to elastomers; it is also present in shampoos (as it makes hair shiny and slippery), food (antifoaming agent), caulking, lubricants and heat-resistant tiles. Contents 1 DIMETHICONE 100 Structure 1.1 DIMETHICONE 100 Branching and capping 2 DIMETHICONE 100 Mechanical properties 3 DIMETHICONE 100 Chemical compatibility 4 DIMETHICONE 100 Applications 4.1 DIMETHICONE 100 Surfactants and antifoaming agents 4.2 DIMETHICONE 100 Hydraulic fluids and related applications 4.3 DIMETHICONE 100 Soft lithography 4.4 DIMETHICONE 100 Stereo lithography 4.5 DIMETHICONE 100 Medicine and cosmetics 4.5.1 DIMETHICONE 100 Skin 4.5.2 DIMETHICONE 100 Hair 4.5.3 DIMETHICONE 100 Flea treatment for pets 4.6 DIMETHICONE 100 Foods 4.7 DIMETHICONE 100 Condom lubricant 4.8 DIMETHICONE 100 Domestic and niche uses 5 DIMETHICONE 100 Safety and environmental considerations 6 DIMETHICONE 100 See also 7 DIMETHICONE 100 References 8 DIMETHICONE 100 External links DIMETHICONE 100 Structure The chemical formula for PDMS DIMETHICONE 100 is CH3[Si(CH3)2O]nSi(CH3)3, where n is the number of repeating monomer [SiO(CH3)2] units.[3] Industrial synthesis can begin from dimethyldichlorosilane and water by the following net reaction: {\displaystyle n{\ce {Si(CH3)2Cl2}}+(n+1){\ce {H2O->HO[-Si(CH3)2O-]_{\mathit {n}}H}}+2n{\ce {HCl}}}{\displaystyle n{\ce {Si(CH3)2Cl2}}+(n+1){\ce {H2O->HO[-Si(CH3)2O-]_{\mathit {n}}H}}+2n{\ce {HCl}}} The polymerization reaction evolves hydrochloric acid. For medical and domestic applications, a process was developed in which the chlorine atoms in the silane precursor were replaced with acetate groups. In this case, the polymerization produces acetic acid, which is less chemically aggressive than HCl. As a side-effect, the curing process is also much slower in this case. The acetate is used in consumer applications, such as silicone caulk and adhesives. DIMETHICONE 100 Branching and capping Hydrolysis of Si(CH3)2Cl2 generates a polymer that is terminated with silanol groups (−Si(CH3)2OH]). These reactive centers are typically "capped" by reaction with trimethylsilyl chloride: 2 Si(CH3)3Cl + [Si(CH3)2O]n−2[Si(CH3)2OH]2 → [Si(CH3)2O]n−2[Si(CH3)2O Si(CH3)3]2 + 2 HCl Silane precursors with more acid-forming groups and fewer methyl groups, such as methyltrichlorosilane, can be used to introduce branches or cross-links in the polymer chain. Under ideal conditions, each molecule of such a compound becomes a branch point. This can be used to produce hard silicone resins. In a similar manner, precursors with three methyl groups can be used to limit molecular weight, since each such molecule has only one reactive site and so forms the end of a siloxane chain. Well-defined PDMS DIMETHICONE 100 with a low polydispersity index and high homogeneity is produced by controlled anionic ring-opening polymerization of hexamethylcyclotrisiloxane. Using this methodology it is possible to synthesize linear block copolymers, heteroarm star-shaped block copolymers and many other macromolecular architectures. The polymer is manufactured in multiple viscosities, ranging from a thin pourable liquid (when n is very low), to a thick rubbery semi-solid (when n is very high). PDMS molecules have quite flexible polymer backbones (or chains) due to their siloxane linkages, which are analogous to the ether linkages used to impart rubberiness to polyurethanes. Such flexible chains become loosely entangled when molecular weight is high, which results in PDMS' unusually high level of viscoelasticity. DIMETHICONE 100 Mechanical properties PDMS is viscoelastic, meaning that at long flow times (or high temperatures), it acts like a viscous liquid, similar to honey. However, at short flow times (or low temperatures), it acts like an elastic solid, similar to rubber. Viscoelasticity is a form of nonlinear elasticity that is common amongst noncrystalline polymers.[4] The loading and unloading of a stress-strain curve for PDMS do not coincide; rather, the amount of stress will vary based on the degree of strain, and the general rule is that increasing strain will result in greater stiffness. When the load itself is removed, the strain is slowly recovered (rather than instantaneously). This time-dependent elastic deformation results from the long-chains of the polymer. But the process that is described above is only relevant when cross-linking is present; when it is not, the polymer PDMS cannot shift back to the original state even when the load is removed, resulting in a permanent deformation. However, permanent deformation is rarely seen in PDMS, since it is almost always cured with a cross-linking agent. If some PDMS DIMETHICONE 100 is left on a surface overnight (long flow time), it will flow to cover the surface and mold to any surface imperfections. However, if the same PDMS is poured into a spherical mold and allowed to cure (short flow time), it will bounce like a rubber ball.[3] The mechanical properties of PDMS enable this polymer to conform to a diverse variety of surfaces. Since these properties are affected by a variety of factors, this unique polymer is relatively easy to tune. This enables PDMS to become a good substrate that can easily be integrated into a variety of microfluidic and microelectromechanical systems.[5][6] Specifically, the determination of mechanical properties can be decided before PDMS is cured; the uncured version allows the user to capitalize on myriad opportunities for achieving a desirable elastomer. Generally, the cross-linked cured version of PDMS resembles rubber in a solidified form. It is widely known to be easily stretched, bent, compressed in all directions.[7] Depending on the application and field, the user is able to tune the properties based on what is demanded. Overall PDMS DIMETHICONE 100has a low elastic modulus which enables it to be easily deformed and results in the behavior of a rubber.[8][9][10] Viscoelastic properties of PDMS can be more precisely measured using dynamic mechanical analysis. This method requires determination of the material's flow characteristics over a wide range of temperatures, flow rates, and deformations. Because of PDMS's chemical stability, it is often used as a calibration fluid for this type of experiment. The shear modulus of PDMS DIMETHICONE 100 varies with preparation conditions, and consequently dramatically varies in the range of 100 kPa to 3 MPa. The loss tangent is very low (tan δ ≪ 0.001).[10] DIMETHICONE 100 Chemical compatibility PDMS DIMETHICONE 100 is hydrophobic.[6] Plasma oxidation can be used to alter the surface chemistry, adding silanol (SiOH) groups to the surface. Atmospheric air plasma and argon plasma will work for this application. This treatment renders the PDMS surface hydrophilic, allowing water to wet it. The oxidized surface can be further functionalized by reaction with trichlorosilanes. After a certain amount of time, recovery of the surface's hydrophobicity is inevitable, regardless of whether the surrounding medium is vacuum, air, or water; the oxidized surface is stable in air for about 30 minutes.[11] Alternatively, for applications where long-term hydrophilicity is a requirement, techniques such as hydrophilic polymer grafting, surface nanostructuring, and dynamic surface modification with embedded surfactants can be of use. [12] Solid PDMS DIMETHICONE 100 samples (whether surface-oxidized or not) will not allow aqueous solvents to infiltrate and swell the material. Thus PDMS structures can be used in combination with water and alcohol solvents without material deformation. However most organic solvents will diffuse into the material and cause it to swell.[6] Despite this, some organic solvents lead to sufficiently small swelling that they can be used with PDMS, for instance within the channels of PDMS microfluidic devices. The swelling ratio is roughly inversely related to the solubility parameter of the solvent. Diisopropylamine swells PDMS to the greatest extent; solvents such as chloroform, ether, and THF swell the material to a large extent. Solvents such as acetone, 1-propanol, and pyridine swell the material to a small extent. Alcohols and polar solvents such as methanol, glycerol and water do not swell the material appreciably.[13] DIMETHICONE 100 Applications Surfactants and antifoaming agents PDMS DIMETHICONE 100 is a common surfactant and is a component of defoamers.[14] PDMS, in a modified form, is used as an herbicide penetrant[15] and is a critical ingredient in water-repelling coatings, such as Rain-X.[16] DIMETHICONE 100 Hydraulic fluids and related applications DIMETHICONE 100 is also the active silicone fluid in automotive viscous limited slip differentials and couplings. This is usually a non-serviceable OEM component but can be replaced with mixed performance results due to variances in effectiveness caused by refill weights or non-standard pressurizations.[citation needed] DIMETHICONE 100 Soft lithography PDMS DIMETHICONE 100is commonly used as a stamp resin in the procedure of soft lithography, making it one of the most common materials used for flow delivery in microfluidics chips.[17] The process of soft lithography consists of creating an elastic stamp, which enables the transfer of patterns of only a few nanometers in size onto glass, silicon or polymer surfaces. With this type of technique, it is possible to produce devices that can be used in the areas of optic telecommunications or biomedical research. The stamp is produced from the normal techniques of photolithography or electron-beam lithography. The resolution depends on the mask used and can reach 6 nm.[18] In biomedical (or biological) microelectromechanical systems (bio-MEMS), soft lithography is used extensively for microfluidics in both organic and inorganic contexts. Silicon wafers are used to design channels, and PDMS is then poured over these wafers and left to harden. When removed, even the smallest of details is left imprinted in the PDMS. With this particular PDMS block, hydrophilic surface modification is conducted using plasma etching techniques. Plasma treatment disrupts surface silicon-oxygen bonds, and a plasma-treated glass slide is usually placed on the activated side of the PDMS (the plasma-treated, now hydrophilic side with imprints). Once activation wears off and bonds begin to reform, silicon-oxygen bonds are formed between the surface atoms of the glass and the surface atoms of the PDMS, and the slide becomes permanently sealed to the PDMS, thus creating a waterproof channel. With these devices, researchers can utilize various surface chemistry techniques for different functions creating unique lab-on-a-chip devices for rapid parallel testing.[5] PDMS can be cross-linked into networks and is a commonly used system for studying the elasticity of polymer networks.[citation needed] PDMS can be directly patterned by surface-charge lithography.[19] PDMS DIMETHICONE 100 is being used in the making of synthetic gecko adhesion dry adhesive materials, to date only in laboratory test quantities.[20] Some flexible electronics researchers use PDMS DIMETHICONE 100 because of its low cost, easy fabrication, flexibility, and optical transparency.[21] DIMETHICONE 100 Stereo lithography In stereo lithography (SLA) 3D printing, light is projected onto photocuring resin to selectively cure it. Some types of SLA printer are cured from the bottom of the tank of resin and therefore require the growing model to be peeled away from the base in order for each printed layer to be supplied with a fresh film of uncured resin. A PDMS layer at the bottom of the tank assists this process by absorbing oxygen : the presence of oxygen adjacent to the resin prevents it adhering to the PDMS, and the optically clear PDMS permits the projected image to pass through to the resin undistorted. DIMETHICONE 100 Medicine and cosmetics Activated DIMETHICONE 100, a mixture of polydimethylsiloxanes and silicon dioxide (sometimes called simethicone), is often used in over-the-counter drugs as an antifoaming agent and carminative.[22][23] It has also been at least proposed for use in contact lenses.[24] Silicone breast implants are made out of a PDMS DIMETHICONE 100 elastomer shell, to which fumed amorphous silica is added, encasing PDMS gel or saline solution. [25] In addition, PDMS DIMETHICONE 100 is useful as a lice or flea treatment because of its ability to trap insects.[26] It also works as a moisturizer that is lighter and more breathable than typical oils. DIMETHICONE 100 Skin PDMS DIMETHICONE 100 is used variously in the cosmetic and consumer product industry as well. For example, PDMS can be used in the treatment of head lice on the scalp[26] and dimethicone is used widely in skin-moisturizing lotions where it is listed as an active ingredient whose purpose is "skin protection." Some cosmetic formulations use dimethicone and related siloxane polymers in concentrations of use up to 15%. The Cosmetic Ingredient Review's (CIR) Expert Panel, has concluded that dimethicone and related polymers are "safe as used in cosmetic formulations."[27] DIMETHICONE 100 Hair PDMS DIMETHICONE 100 compounds such as amodimethicone, are effective conditioners when formulated to consist of small particles and be soluble in water or alcohol/act as surfactants[28][29] (especially for damaged hair[30]), and are even more conditioning to the hair than common dimethicone and/or dimethicone copolyols.[31] DIMETHICONE 100 Flea treatment for pets Dimethicone DIMETHICONE 100 is the active ingredient in a liquid applied to the back of the neck of a cat or dog from a small one time use dose disposable pipette. The parasite becomes trapped and immoblised in the substance and thus breaks the life cycle of the insect. DIMETHICONE 100 Foods PDMS DIMETHICONE 100 is added to many cooking oils (as an antifoaming agent) to prevent oil splatter during the cooking process. As a result of this, PDMS can be found in trace quantities in many fast food items such as McDonald's Chicken McNuggets, french fries, hash browns, milkshakes and smoothies[32] and Wendy's french fries.[33] Under European food additive regulations, it is listed as E900. DIMETHICONE 100 Condom lubricant PDMS DIMETHICONE 100 is widely used as a condom lubricant.[34][35] DIMETHICONE 100 Domestic and niche uses Many people are indirectly familiar with PDMS DIMETHICONE 100 because it is an important component in Silly Putty, to which PDMS imparts its characteristic viscoelastic properties.[36] Another toy PDMS is used in is Kinetic Sand. The rubbery, vinegary-smelling silicone caulks, adhesives, and aquarium sealants are also well-known. PDMS is also used as a component in silicone grease and other silicone based lubricants, as well as in defoaming agents, mold release agents, damping fluids, heat transfer fluids, polishes, cosmetics, hair conditioners and other applications. PDMS has also been used as a filler fluid in breast implants. It can be used as a sorbent for the analysis of headspace (dissolved gas analysis) of food.[37] DIMETHICONE 100 Safety and environmental considerations According to Ullmann's Encyclopedia, no "marked harmful effects on organisms in the environment" have been noted for siloxanes. PDMS is nonbiodegradable, but is absorbed in waste water treatment facilities. Its degradation is catalyzed by various clays.[38] Polydimethylsiloxane PDMS DIMETHICONE 100 PDMS DIMETHICONE 100 DIMETHICONE 100 Names DIMETHICONE 100 IUPAC name poly(dimethylsiloxane) DIMETHICONE 100 Other names PDMS, dimethicone, dimethylpolysiloxane, E900 Identifiers DIMETHICONE 100 CAS Number 63148-62-9 DIMETHICONE 100 3D model (JSmol) n = 12: Interactive image DIMETHICONE 100 none DIMETHICONE 100 ECHA InfoCard 100.126.442 E number E900 (glazing agents, ...) DIMETHICONE 100 UNII 92RU3N3Y1O DIMETHICONE 100 CompTox Dashboard (EPA) DTXSID0049573 DIMETHICONE 100 Properties DIMETHICONE 100 Chemical formula (C2H6OSi)n DIMETHICONE 100 Density 965 kg/m3 DIMETHICONE 100 Melting point N/A (vitrifies) DIMETHICONE 100 Boiling point N/A (vitrifies) DIMETHICONE 100 is a silicone oil that is also known as polydimethylsiloxane (PDMS). It has viscoelastic properties. Dimethicone is used as a surfactant, antifoaming agent, carminative in various products such as medical devices, food products, and lubricants. It is used in a number of health and beauty products including hair care products such as shampoo, conditioner, leave-in conditioner, and de-tangling products. On skin, it is also observed to have moisturizing actions 6,8. A study found that that the 100 % DIMETHICONE 100 product is a safe and highly effective head lice treatment for children and may serve as less toxic and less resistance-prone alternative to pesticide-containing products. Stearoxy Dimethicone, Dimethicone, Methicone, Amino Bispropyl Dimethicone,Aminopropyl Dimethicone, Amodimethicone, Amodimethicone Hydroxystearate,Behenoxy Dimethicone, C24-28 Alkyl Methicone, C30-45 Alkyl Dimethicone, C30-45 Alkyl Methicone,Cetearyl Methicone, Cetyl Dimethicone, Dimethoxysilyl Ethylenediaminopropyl Dimethicone, Hexyl Methicone, Hydroxypropyldimethicone,Stearamidopropyl Dimethicone, Stearyl Dimethicone, Stearyl Methicone,and Vinyldimethicone At Puracy, we take natural skincare seriously. Discover what dimethicone is, how it's used, and why it's more harmful than you might think.As an eco-friendly skincare brand, Puracy wants to set the record straight about what dimethicone is – and why we never use it in our products.If you've ever used a makeup primer with a silky or slippery feel, it probably had some version of dimethicone (polydimethylsiloxane) in it. Because molecules of this silicone-based polymer are too large for the skin and hair to absorb, these products leave behind a thin layer. As a result, you get shinier-looking and smoother-feeling skin and hair – a major reason for the popularity of dimethicone in cosmetics.Board-certified dermatologist Dr. Julie Jackson states that dimethicone “does not interact with the stratum corneum (the top layer of the skin). It works by forming a film that prevents the loss of water through the skin, thus keeping the skin moisturized. It also works as an emollient, filling the spaces between cracks in the skin.”There are hundreds of dimethicone uses in personal care products, with the most popular being diaper rash cream, moisturizer, hand lotion, and liquid foundation. This ingredient allows products to be applied seamlessly. In makeup primers, it prevents foundation from changing colors and cracking.Most hair care companies use dimethicone and silicone to coat the hair cuticle and make detangling easier. A lot of this comes down to these ingredients’ affordability and effectiveness. There are simply very few eco-friendly, dimethicone-free products that can provide the same results.After years of research and development with expert chemists and testers, Puracy Natural Shampoo and Conditioner are rare examples of dimethicone-free hair products that manage to leave all hair types moisturized, bouncy, and shiny.Puracy is proud to be one of the first companies to use this 100% sustainable and biodegradable emollient, which seamlessly replicates the effects of both dimethicone and silicone. When pressed on whether dimethicone can clog pores and lead to acne, Dr. Jackson concluded, “There is no evidence that dimethicone can cause acne.”Even though it’s an unnatural, man-made substance, Dr. Jackson agrees that dimethicone is a good chemically-inert moisturizer. But it isn’t biodegradable – and the current environmental research isn’t positive. As a result, we’ll never include it in any Puracy formulas.The first step to avoiding dimethicone is by carefully reading labels and looking for products that pledge to use biodegradable, renewable ingredients. Next, choose items that are dimethicone, silicone-, and sulfate-free – like every Puracy personal care product.Dimethicone (also known as polydimethylsiloxane) – a silicon-based polymer – is a man-made synthetic molecule comprised of repeating units called monomers. Silicon is the second most abundant element in the Earth's crust (after oxygen). Dimethicone is one of the most widely used ingredients in cosmetics and personal care products and can also be found in many cooking oils, processed foods, and fast food items.According to 2019 data in U.S. FDA’s Voluntary Cosmetic Registration Program (VCRP), dimethicone was reported to be used in 12,934 products. This included products for use near the eye, shampoos and conditioners, hair dyes and colors, bath oils, skin care products, bath soaps and detergents, suntan preparations and baby products.Dimethicone works as an anti-foaming agent, skin protectant, skin conditioning agent, and hair conditioning agent. It prevents water loss by forming a barrier on the skin. Like most silicone materials, dimethicone has a unique fluidity that makes it easily spreadable and, when applied to the skin, gives products a smooth and silky feel. It can also help fill in fine lines/wrinkles on the face, giving it a temporary “plump” look.Dimethicone is an important component in several toys, including Silly Putty, to which it imparts its unique viscosity and elastic properties, and Kinetic Sand, which mimics the physical properties of wet sand and can be molded and shaped into any desired form. Dimethicone is also a critical ingredient in rubbery silicone caulks, adhesives, and aquarium sealants, as well as water-repelling coatings, such as Rain-X.f you were to ask your friends, "What is dimethicone?" you'd likely get a lot of blank stares. Buuut I'm also willing to bet you'd hear some very, very opinionated responses (if, you know, your friends happen to be beauty editors). Silicones (like dimethicone) in cosmetics is a controversial topic, and for every person who loves them and swears by their silicone-based makeup primer, there's another person who actively avoids all silicones in skincare, haircare, and makeup.So what's the deal? Is dimethicone okay to use, or do you need to overhaul your medicine cabinet? Welp, allow me to present you with the facts and expert insights from a dermatologist and trichologist about using dimethicone in your skincare and hair products so that you can make that decision for yourself. Because, spoiler, it really is a you decision in the end.Dimethicone is a silicon-based polymer that, when used in beauty products, gives the formula an incredibly smooth, velvety, slippery feel that you either love or hate (although I'll never understand the people who hate it TBH. I freakin' love the smooth feeling of silicones).But dimethicone is not only used for its sensory properties—it also helps to temporarily smooth fine lines and wrinkles, functions as an emollient (aka a skin-conditioning agent), and also has some occlusive properties (meaning it prevents water loss by creating a seal or a barrier on your skin). And because of these properties, you'll usually find dimethicone in your foundations, makeup primers, hair products, moisturizers, etc. Basically, unless a label specifically says it's silicone-free, you can almost guarantee it's in ev-ery-thing.Despite what the haters may say, according to the Cosmetic Ingredient Review Panel, dimethicone is safe when used in cosmetic products. What's more, the CIR Expert Panel also says because of the large molecular weight of dimethicone, it's unlikely that it can be absorbed into the skin in a significant way. Board-certified dermatologist Dhaval G. Bhanusali, MD, isn't concerned either: "I think, all too often, people put things in categories and say, 'all of this is bad,'" he says. "But in this case, I don't know of many colleagues who are concerned with dimethicone in skincare products."Although dimethicone is fine for use on the skin, things get a little trickier when using it on your hair, mainly because it can coat your strands and weigh them down (which is not great for curls or fine hair). But, "if you have dry, damaged hair that's prone to tangles, dimethicone can help create that sleek, slippery feel, making detangling easy and giving the appearance that the hair is super-conditioned and healthy," says trichologist and creator of Colour Collective, Kerry E. Yates. "Dimethicone is also heavily used in styling products to help 'glue' the cuticles down to create that smooth, shiny effect in hair."In short, yes. The reason why you might experience dry hair from using a dimethicone-based formula is that the product builds up, which prevents the hair from achieving a proper moisture balance. This is why excess use of dimethicone can result in dry, brittle ends that are prone to breakage.Just because the experts say dimethicone is not the enemy the internet has made it out to be, it doesn't mean you have to use it. Dimethicone has its pros and cons, so if you've read the above and decided you still don't want to use it, don't! No one's making you! The beauty of an oversaturated beauty market is that you have tons of silicone-free options to use instead, like the below:Dimethicone in its simplest form is polydimethylsiloxane, also known as silicone oil, but more commonly called dimethicone. Silicone oils are derived from silica (sand and quartz are silicas).Dimethicone comes in various viscosities, this one is 350 centistokes, a medium viscosity which offers excellent barrier properties when used in skin protectant formulations. It adds slip and glide, reducing tackiness. It offers conditioning properties when used in hair and skin care applications.Used at a rate of 1% to 30%, dimethicone conforms to the FDA's Tentative Final Monograph on OTC Skin Protectants. However, provided you make no drug claims for it, dimethicone does not have to be declared as an active ingredient, nor does your product or facility need to conform to OTC drug production standards. Dimethicone can be added to any cosmetic and declared on the ingredient label in descending order. When using dimethicone in cosmetic formulations, one should be guided by the usage rates in the Cosmetic Ingredient Review (CIR) tables (see our Reference Room for links to these PDFs) as these apply to cosmetics rather than OTC products.The CIR lists Dimethicone in the Cosmetic Ingredients Found Safe as Used in the following amounts,Dimethicone is promoted as a defoaming agent for relief of abdominal pain due to retained gas and for “colic” in infants. It has been suggested that it may provide mucosal protection3 and it is included in many combined antacid preparations. It is also used to improve visibility during endoscopy. This article reviews the actions and clinical uses of dimethicone.Dimethicone (also known as polydimethylsiloxane or PDMS) is technically called a silicone-based polymer. More simply, it’s a silicone oil with certain properties that make it extremely popular in today's personal care properties.In hair care products, dimethicone is used to provide smoothness, particularly in conditioners and detanglers, where the ingredient helps smooth hair and provide better comb-through. Because dimethicone leaves a sort of covering on the hair strands, it can also make hair appear shinier.In accordance with CIR Procedures, because it has been at least 15 years since the original safety assessment was published, the Panel should consider whether the safety assessment of Stearoxy Dimethicone, Dimethicone, Methicone,Amino Bispropyl Dimethicone,Aminopropyl Dimethicone, Amodimethicone, Amodimethicone Hydroxystearate,Behenoxy Dimethicone, C24-28 Alkyl Methicone, C30-45 Alkyl Methicone, C30-45 Alkyl Dimethicone, Cetearyl,Methicone, Cetyl Dimethicone, Dimethoxysilyl Ethylenediaminopropyl Dimethicone, Hexyl Methicone,Hydroxypropyldimethicone, Stearamidopropyl Dimethicone, Stearyl Dimethicone, Stearyl Methicone, and Vinyl Dimethicone should be re-opened. An exhaustive search of the world’s literature was performed for studies dated 1998 forward. A synopsis of the relevant new data is enclosed Stearoxy Dimethicone, Dimethicone, Methicone, Amino Bispropyl Dimethicone,Aminopropyl Dimethicone, Amodimethicone, Amodimethicone Hydroxystearate,Behenoxy Dimethicone, C24-28 Alkyl Methicone, C30-45 Alkyl Dimethicone,C30-45 Alkyl Methicone, Cetearyl Methicone, Cetyl Dimethicone, Dimethoxysilyl,Ethylenediaminopropyl Dimethicone, Hexyl Methicone, Hydroxypropyldimethicone,Stearamidopropyl Dimethicone, Stearyl Dimethicone, Stearyl Methicone, and Vinyldimethicone. Dimethicone and mineral spirits from the CIR report. He noted that the necrosis observed was due to the mineral spirits, and not Dimethicone. The Panel voted unanimously in favor of issuing a Final Report with a safe as used conclusion on the Stearoxy Dimethicone ingredient family. Dimethicone has been used as a physical barrier method of eradicating head lice and eggs. 3,4 Dimethicone use is also prevalent in condom lubricants5, and, it is used industrially in various construction sealants, rubber, and paints, and is taken orally as an anti-flatulence agent.6

DIMETHYL CARBONATE, N° CAS : 616-38-6, Nom INCI : DIMETHYL CARBONATE, Nom chimique : Carbonic acid, dimethyl ester, N° EINECS/ELINCS : 210-478-4. Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Agent propulseur : Génère de la pression dans un emballage en aérosol, expulsant le contenu lorsque la vanne est ouverte. Certains propulseurs liquéfiés peuvent agir comme solvants. Solvant : Dissout d'autres substances. Noms français : Carbonate de diméthyle Carbonate de méthyle Carbonic acid, dimethyl ester Methyl carbonate Noms anglais : Dimethyl carbonate

DIMETHICONE 5 Polydimethylsiloxane (PDMS) Dimethicone 5 ( DİMETİKON 5 ), also known as dimethylpolysiloxane or Dimethicone 5, belongs to a group of polymeric organosilicon compounds that are commonly referred to as silicones.[1] PDMS is the most widely used silicon-based organic polymer due to its versatility and properties leading to a manifold of applications.[2] It is particularly known for its unusual rheological (or flow) properties. PDMS is optically clear and, in general, inert, non-toxic, and non-flammable. It is one of several types of silicone oil (polymerized siloxane). Its applications range from contact lenses and medical devices to elastomers; it is also present in shampoos (as it makes hair shiny and slippery), food (antifoaming agent), caulking, lubricants and heat-resistant tiles. Contents 1 Dimethicone 5 ( DİMETİKON 5 ) Structure 1.1 Dimethicone 5 ( DİMETİKON 5 ) Branching and capping 2 Dimethicone 5 ( DİMETİKON 5 ) Mechanical properties 3 Dimethicone 5 ( DİMETİKON 5 ) Chemical compatibility 4 Dimethicone 5 ( DİMETİKON 5 ) Applications 4.1 Dimethicone 5 ( DİMETİKON 5 ) Surfactants and antifoaming agents 4.2 Dimethicone 5 ( DİMETİKON 5 ) Hydraulic fluids and related applications 4.3 Dimethicone 5 ( DİMETİKON 5 ) Soft lithography 4.4 Dimethicone 5 ( DİMETİKON 5 ) Stereo lithography 4.5 Dimethicone 5 ( DİMETİKON 5 ) Medicine and cosmetics 4.5.1 Dimethicone 5 ( DİMETİKON 5 ) Skin 4.5.2 Dimethicone 5 ( DİMETİKON 5 ) Hair 4.5.3 Dimethicone 5 ( DİMETİKON 5 ) Flea treatment for pets 4.6 Dimethicone 5 ( DİMETİKON 5 ) Foods 4.7 Dimethicone 5 ( DİMETİKON 5 ) Condom lubricant 4.8 Dimethicone 5 ( DİMETİKON 5 ) Domestic and niche uses 5 Dimethicone 5 ( DİMETİKON 5 ) Safety and environmental considerations 6 Dimethicone 5 ( DİMETİKON 5 ) See also 7 Dimethicone 5 ( DİMETİKON 5 ) References 8 Dimethicone 5 ( DİMETİKON 5 ) External links Dimethicone 5 ( DİMETİKON 5 ) Structure The chemical formula for PDMS Dimethicone 5 ( DİMETİKON 5 ) is CH3[Si(CH3)2O]nSi(CH3)3, where n is the number of repeating monomer [SiO(CH3)2] units.[3] Industrial synthesis can begin from dimethyldichlorosilane and water by the following net reaction: {\displaystyle n{\ce {Si(CH3)2Cl2}}+(n+1){\ce {H2O->HO[-Si(CH3)2O-]_{\mathit {n}}H}}+2n{\ce {HCl}}}{\displaystyle n{\ce {Si(CH3)2Cl2}}+(n+1){\ce {H2O->HO[-Si(CH3)2O-]_{\mathit {n}}H}}+2n{\ce {HCl}}} The polymerization reaction evolves hydrochloric acid. For medical and domestic applications, a process was developed in which the chlorine atoms in the silane precursor were replaced with acetate groups. In this case, the polymerization produces acetic acid, which is less chemically aggressive than HCl. As a side-effect, the curing process is also much slower in this case. The acetate is used in consumer applications, such as silicone caulk and adhesives. Dimethicone 5 ( DİMETİKON 5 ) Branching and capping Hydrolysis of Si(CH3)2Cl2 generates a polymer that is terminated with silanol groups (−Si(CH3)2OH]). These reactive centers are typically "capped" by reaction with trimethylsilyl chloride: 2 Si(CH3)3Cl + [Si(CH3)2O]n−2[Si(CH3)2OH]2 → [Si(CH3)2O]n−2[Si(CH3)2O Si(CH3)3]2 + 2 HCl Silane precursors with more acid-forming groups and fewer methyl groups, such as methyltrichlorosilane, can be used to introduce branches or cross-links in the polymer chain. Under ideal conditions, each molecule of such a compound becomes a branch point. This can be used to produce hard silicone resins. In a similar manner, precursors with three methyl groups can be used to limit molecular weight, since each such molecule has only one reactive site and so forms the end of a siloxane chain. Well-defined PDMS Dimethicone 5 ( DİMETİKON 5 ) with a low polydispersity index and high homogeneity is produced by controlled anionic ring-opening polymerization of hexamethylcyclotrisiloxane. Using this methodology it is possible to synthesize linear block copolymers, heteroarm star-shaped block copolymers and many other macromolecular architectures. The polymer is manufactured in multiple viscosities, ranging from a thin pourable liquid (when n is very low), to a thick rubbery semi-solid (when n is very high). PDMS molecules have quite flexible polymer backbones (or chains) due to their siloxane linkages, which are analogous to the ether linkages used to impart rubberiness to polyurethanes. Such flexible chains become loosely entangled when molecular weight is high, which results in PDMS' unusually high level of viscoelasticity. Dimethicone 5 ( DİMETİKON 5 ) Mechanical properties PDMS is viscoelastic, meaning that at long flow times (or high temperatures), it acts like a viscous liquid, similar to honey. However, at short flow times (or low temperatures), it acts like an elastic solid, similar to rubber. Viscoelasticity is a form of nonlinear elasticity that is common amongst noncrystalline polymers.[4] The loading and unloading of a stress-strain curve for PDMS do not coincide; rather, the amount of stress will vary based on the degree of strain, and the general rule is that increasing strain will result in greater stiffness. When the load itself is removed, the strain is slowly recovered (rather than instantaneously). This time-dependent elastic deformation results from the long-chains of the polymer. But the process that is described above is only relevant when cross-linking is present; when it is not, the polymer PDMS cannot shift back to the original state even when the load is removed, resulting in a permanent deformation. However, permanent deformation is rarely seen in PDMS, since it is almost always cured with a cross-linking agent. If some PDMS Dimethicone 5 ( DİMETİKON 5 ) is left on a surface overnight (long flow time), it will flow to cover the surface and mold to any surface imperfections. However, if the same PDMS is poured into a spherical mold and allowed to cure (short flow time), it will bounce like a rubber ball.[3] The mechanical properties of PDMS enable this polymer to conform to a diverse variety of surfaces. Since these properties are affected by a variety of factors, this unique polymer is relatively easy to tune. This enables PDMS to become a good substrate that can easily be integrated into a variety of microfluidic and microelectromechanical systems.[5][6] Specifically, the determination of mechanical properties can be decided before PDMS is cured; the uncured version allows the user to capitalize on myriad opportunities for achieving a desirable elastomer. Generally, the cross-linked cured version of PDMS resembles rubber in a solidified form. It is widely known to be easily stretched, bent, compressed in all directions.[7] Depending on the application and field, the user is able to tune the properties based on what is demanded. Overall PDMS Dimethicone 5 ( DİMETİKON 5 )has a low elastic modulus which enables it to be easily deformed and results in the behavior of a rubber.[8][9][10] Viscoelastic properties of PDMS can be more precisely measured using dynamic mechanical analysis. This method requires determination of the material's flow characteristics over a wide range of temperatures, flow rates, and deformations. Because of PDMS's chemical stability, it is often used as a calibration fluid for this type of experiment. The shear modulus of PDMS Dimethicone 5 ( DİMETİKON 5 ) varies with preparation conditions, and consequently dramatically varies in the range of 100 kPa to 3 MPa. The loss tangent is very low (tan δ ≪ 0.001).[10] Dimethicone 5 ( DİMETİKON 5 ) Chemical compatibility PDMS Dimethicone 5 ( DİMETİKON 5 ) is hydrophobic.[6] Plasma oxidation can be used to alter the surface chemistry, adding silanol (SiOH) groups to the surface. Atmospheric air plasma and argon plasma will work for this application. This treatment renders the PDMS surface hydrophilic, allowing water to wet it. The oxidized surface can be further functionalized by reaction with trichlorosilanes. After a certain amount of time, recovery of the surface's hydrophobicity is inevitable, regardless of whether the surrounding medium is vacuum, air, or water; the oxidized surface is stable in air for about 30 minutes.[11] Alternatively, for applications where long-term hydrophilicity is a requirement, techniques such as hydrophilic polymer grafting, surface nanostructuring, and dynamic surface modification with embedded surfactants can be of use. [12] Solid PDMS Dimethicone 5 ( DİMETİKON 5 ) samples (whether surface-oxidized or not) will not allow aqueous solvents to infiltrate and swell the material. Thus PDMS structures can be used in combination with water and alcohol solvents without material deformation. However most organic solvents will diffuse into the material and cause it to swell.[6] Despite this, some organic solvents lead to sufficiently small swelling that they can be used with PDMS, for instance within the channels of PDMS microfluidic devices. The swelling ratio is roughly inversely related to the solubility parameter of the solvent. Diisopropylamine swells PDMS to the greatest extent; solvents such as chloroform, ether, and THF swell the material to a large extent. Solvents such as acetone, 1-propanol, and pyridine swell the material to a small extent. Alcohols and polar solvents such as methanol, glycerol and water do not swell the material appreciably.[13] Dimethicone 5 ( DİMETİKON 5 ) Applications Surfactants and antifoaming agents PDMS Dimethicone 5 ( DİMETİKON 5 ) is a common surfactant and is a component of defoamers.[14] PDMS, in a modified form, is used as an herbicide penetrant[15] and is a critical ingredient in water-repelling coatings, such as Rain-X.[16] Dimethicone 5 ( DİMETİKON 5 ) Hydraulic fluids and related applications Dimethicone 5 ( DİMETİKON 5 ) is also the active silicone fluid in automotive viscous limited slip differentials and couplings. This is usually a non-serviceable OEM component but can be replaced with mixed performance results due to variances in effectiveness caused by refill weights or non-standard pressurizations.[citation needed] Dimethicone 5 ( DİMETİKON 5 ) Soft lithography PDMS Dimethicone 5 ( DİMETİKON 5 )is commonly used as a stamp resin in the procedure of soft lithography, making it one of the most common materials used for flow delivery in microfluidics chips.[17] The process of soft lithography consists of creating an elastic stamp, which enables the transfer of patterns of only a few nanometers in size onto glass, silicon or polymer surfaces. With this type of technique, it is possible to produce devices that can be used in the areas of optic telecommunications or biomedical research. The stamp is produced from the normal techniques of photolithography or electron-beam lithography. The resolution depends on the mask used and can reach 6 nm.[18] In biomedical (or biological) microelectromechanical systems (bio-MEMS), soft lithography is used extensively for microfluidics in both organic and inorganic contexts. Silicon wafers are used to design channels, and PDMS is then poured over these wafers and left to harden. When removed, even the smallest of details is left imprinted in the PDMS. With this particular PDMS block, hydrophilic surface modification is conducted using plasma etching techniques. Plasma treatment disrupts surface silicon-oxygen bonds, and a plasma-treated glass slide is usually placed on the activated side of the PDMS (the plasma-treated, now hydrophilic side with imprints). Once activation wears off and bonds begin to reform, silicon-oxygen bonds are formed between the surface atoms of the glass and the surface atoms of the PDMS, and the slide becomes permanently sealed to the PDMS, thus creating a waterproof channel. With these devices, researchers can utilize various surface chemistry techniques for different functions creating unique lab-on-a-chip devices for rapid parallel testing.[5] PDMS can be cross-linked into networks and is a commonly used system for studying the elasticity of polymer networks.[citation needed] PDMS can be directly patterned by surface-charge lithography.[19] PDMS Dimethicone 5 ( DİMETİKON 5 ) is being used in the making of synthetic gecko adhesion dry adhesive materials, to date only in laboratory test quantities.[20] Some flexible electronics researchers use PDMS Dimethicone 5 ( DİMETİKON 5 ) because of its low cost, easy fabrication, flexibility, and optical transparency.[21] Dimethicone 5 ( DİMETİKON 5 ) Stereo lithography In stereo lithography (SLA) 3D printing, light is projected onto photocuring resin to selectively cure it. Some types of SLA printer are cured from the bottom of the tank of resin and therefore require the growing model to be peeled away from the base in order for each printed layer to be supplied with a fresh film of uncured resin. A PDMS layer at the bottom of the tank assists this process by absorbing oxygen : the presence of oxygen adjacent to the resin prevents it adhering to the PDMS, and the optically clear PDMS permits the projected image to pass through to the resin undistorted. Dimethicone 5 ( DİMETİKON 5 ) Medicine and cosmetics Activated Dimethicone 5 ( DİMETİKON 5 ), a mixture of polydimethylsiloxanes and silicon dioxide (sometimes called simethicone), is often used in over-the-counter drugs as an antifoaming agent and carminative.[22][23] It has also been at least proposed for use in contact lenses.[24] Silicone breast implants are made out of a PDMS Dimethicone 5 ( DİMETİKON 5 ) elastomer shell, to which fumed amorphous silica is added, encasing PDMS gel or saline solution. [25] In addition, PDMS Dimethicone 5 ( DİMETİKON 5 ) is useful as a lice or flea treatment because of its ability to trap insects.[26] It also works as a moisturizer that is lighter and more breathable than typical oils. Dimethicone 5 ( DİMETİKON 5 ) Skin PDMS Dimethicone 5 ( DİMETİKON 5 ) is used variously in the cosmetic and consumer product industry as well. For example, PDMS can be used in the treatment of head lice on the scalp[26] and Dimethicone 5 is used widely in skin-moisturizing lotions where it is listed as an active ingredient whose purpose is "skin protection." Some cosmetic formulations use Dimethicone 5 and related siloxane polymers in concentrations of use up to 15%. The Cosmetic Ingredient Review's (CIR) Expert Panel, has concluded that Dimethicone 5 and related polymers are "safe as used in cosmetic formulations."[27] Dimethicone 5 ( DİMETİKON 5 ) Hair PDMS Dimethicone 5 ( DİMETİKON 5 ) compounds such as amoDimethicone 5, are effective conditioners when formulated to consist of small particles and be soluble in water or alcohol/act as surfactants[28][29] (especially for damaged hair[30]), and are even more conditioning to the hair than common Dimethicone 5 and/or Dimethicone 5 copolyols.[31] Dimethicone 5 ( DİMETİKON 5 ) Flea treatment for pets Dimethicone 5 Dimethicone 5 ( DİMETİKON 5 ) is the active ingredient in a liquid applied to the back of the neck of a cat or dog from a small one time use dose disposable pipette. The parasite becomes trapped and immoblised in the substance and thus breaks the life cycle of the insect. Dimethicone 5 ( DİMETİKON 5 ) Foods PDMS Dimethicone 5 ( DİMETİKON 5 ) is added to many cooking oils (as an antifoaming agent) to prevent oil splatter during the cooking process. As a result of this, PDMS can be found in trace quantities in many fast food items such as McDonald's Chicken McNuggets, french fries, hash browns, milkshakes and smoothies[32] and Wendy's french fries.[33] Under European food additive regulations, it is listed as E900. Dimethicone 5 ( DİMETİKON 5 ) Condom lubricant PDMS Dimethicone 5 ( DİMETİKON 5 ) is widely used as a condom lubricant.[34][35] Dimethicone 5 ( DİMETİKON 5 ) Domestic and niche uses Many people are indirectly familiar with PDMS Dimethicone 5 ( DİMETİKON 5 ) because it is an important component in Silly Putty, to which PDMS imparts its characteristic viscoelastic properties.[36] Another toy PDMS is used in is Kinetic Sand. The rubbery, vinegary-smelling silicone caulks, adhesives, and aquarium sealants are also well-known. PDMS is also used as a component in silicone grease and other silicone based lubricants, as well as in defoaming agents, mold release agents, damping fluids, heat transfer fluids, polishes, cosmetics, hair conditioners and other applications. PDMS has also been used as a filler fluid in breast implants. It can be used as a sorbent for the analysis of headspace (dissolved gas analysis) of food.[37] Dimethicone 5 ( DİMETİKON 5 ) Safety and environmental considerations According to Ullmann's Encyclopedia, no "marked harmful effects on organisms in the environment" have been noted for siloxanes. PDMS is nonbiodegradable, but is absorbed in waste water treatment facilities. Its degradation is catalyzed by various clays.[38] Polydimethylsiloxane PDMS Dimethicone 5 ( DİMETİKON 5 ) PDMS Dimethicone 5 ( DİMETİKON 5 ) Dimethicone 5 ( DİMETİKON 5 ) Names Dimethicone 5 ( DİMETİKON 5 ) IUPAC name poly(dimethylsiloxane) Dimethicone 5 ( DİMETİKON 5 ) Other names PDMS, Dimethicone 5, dimethylpolysiloxane, E900 Identifiers Dimethicone 5 ( DİMETİKON 5 ) CAS Number 63148-62-9 Dimethicone 5 ( DİMETİKON 5 ) 3D model (JSmol) n = 12: Interactive image Dimethicone 5 ( DİMETİKON 5 ) none Dimethicone 5 ( DİMETİKON 5 ) ECHA InfoCard 100.126.442 E number E900 (glazing agents, ...) Dimethicone 5 ( DİMETİKON 5 ) UNII 92RU3N3Y1O Dimethicone 5 ( DİMETİKON 5 ) CompTox Dashboard (EPA) DTXSID0049573 Dimethicone 5 ( DİMETİKON 5 ) Properties Dimethicone 5 ( DİMETİKON 5 ) Chemical formula (C2H6OSi)n Dimethicone 5 ( DİMETİKON 5 ) Density 965 kg/m3 Dimethicone 5 ( DİMETİKON 5 ) Melting point N/A (vitrifies) Dimethicone 5 ( DİMETİKON 5 ) Boiling point N/A (vitrifies) Dimethicone 5 ( DİMETİKON 5 ) is a silicone oil that is also known as polydimethylsiloxane (PDMS). It has viscoelastic properties. Dimethicone 5 is used as a surfactant, antifoaming agent, carminative in various products such as medical devices, food products, and lubricants. It is used in a number of health and beauty products including hair care products such as shampoo, conditioner, leave-in conditioner, and de-tangling products. On skin, it is also observed to have moisturizing actions 6,8. A study found that that the 100 % Dimethicone 5 ( DİMETİKON 5 ) product is a safe and highly effective head lice treatment for children and may serve as less toxic and less resistance-prone alternative to pesticide-containing products. Stearoxy Dimethicone 5, Dimethicone 5, Methicone, Amino Bispropyl Dimethicone 5,Aminopropyl Dimethicone 5, AmoDimethicone 5, AmoDimethicone 5 Hydroxystearate,Behenoxy Dimethicone 5, C24-28 Alkyl Methicone, C30-45 Alkyl Dimethicone 5, C30-45 Alkyl Methicone,Cetearyl Methicone, Cetyl Dimethicone 5, Dimethoxysilyl Ethylenediaminopropyl Dimethicone 5, Hexyl Methicone, HydroxypropylDimethicone 5,Stearamidopropyl Dimethicone 5, Stearyl Dimethicone 5, Stearyl Methicone,and VinylDimethicone 5 At Puracy, we take natural skincare seriously. Discover what Dimethicone 5 is, how it's used, and why it's more harmful than you might think.As an eco-friendly skincare brand, Puracy wants to set the record straight about what Dimethicone 5 is – and why we never use it in our products.If you've ever used a makeup primer with a silky or slippery feel, it probably had some version of Dimethicone 5 (polydimethylsiloxane) in it. Because molecules of this silicone-based polymer are too large for the skin and hair to absorb, these products leave behind a thin layer. As a result, you get shinier-looking and smoother-feeling skin and hair – a major reason for the popularity of Dimethicone 5 in cosmetics.Board-certified dermatologist Dr. Julie Jackson states that Dimethicone 5 “does not interact with the stratum corneum (the top layer of the skin). It works by forming a film that prevents the loss of water through the skin, thus keeping the skin moisturized. It also works as an emollient, filling the spaces between cracks in the skin.”There are hundreds of Dimethicone 5 uses in personal care products, with the most popular being diaper rash cream, moisturizer, hand lotion, and liquid foundation. This ingredient allows products to be applied seamlessly. In makeup primers, it prevents foundation from changing colors and cracking.Most hair care companies use Dimethicone 5 and silicone to coat the hair cuticle and make detangling easier. A lot of this comes down to these ingredients’ affordability and effectiveness. There are simply very few eco-friendly, Dimethicone 5-free products that can provide the same results.After years of research and development with expert chemists and testers, Puracy Natural Shampoo and Conditioner are rare examples of Dimethicone 5-free hair products that manage to leave all hair types moisturized, bouncy, and shiny.Puracy is proud to be one of the first companies to use this 100% sustainable and biodegradable emollient, which seamlessly replicates the effects of both Dimethicone 5 and silicone. When pressed on whether Dimethicone 5 can clog pores and lead to acne, Dr. Jackson concluded, “There is no evidence that Dimethicone 5 can cause acne.”Even though it’s an unnatural, man-made substance, Dr. Jackson agrees that Dimethicone 5 is a good chemically-inert moisturizer. But it isn’t biodegradable – and the current environmental research isn’t positive. As a result, we’ll never include it in any Puracy formulas.The first step to avoiding Dimethicone 5 is by carefully reading labels and looking for products that pledge to use biodegradable, renewable ingredients. Next, choose items that are Dimethicone 5, silicone-, and sulfate-free – like every Puracy personal care product.Dimethicone 5 (also known as polydimethylsiloxane) – a silicon-based polymer – is a man-made synthetic molecule comprised of repeating units called monomers. Silicon is the second most abundant element in the Earth's crust (after oxygen). Dimethicone 5 is one of the most widely used ingredients in cosmetics and personal care products and can also be found in many cooking oils, processed foods, and fast food items.According to 2019 data in U.S. FDA’s Voluntary Cosmetic Registration Program (VCRP), Dimethicone 5 was reported to be used in 12,934 products. This included products for use near the eye, shampoos and conditioners, hair dyes and colors, bath oils, skin care products, bath soaps and detergents, suntan preparations and baby products.Dimethicone 5 works as an anti-foaming agent, skin protectant, skin conditioning agent, and hair conditioning agent. It prevents water loss by forming a barrier on the skin. Like most silicone materials, Dimethicone 5 has a unique fluidity that makes it easily spreadable and, when applied to the skin, gives products a smooth and silky feel. It can also help fill in fine lines/wrinkles on the face, giving it a temporary “plump” look.Dimethicone 5 is an important component in several toys, including Silly Putty, to which it imparts its unique viscosity and elastic properties, and Kinetic Sand, which mimics the physical properties of wet sand and can be molded and shaped into any desired form. Dimethicone 5 is also a critical ingredient in rubbery silicone caulks, adhesives, and aquarium sealants, as well as water-repelling coatings, such as Rain-X.f you were to ask your friends, "What is Dimethicone 5?" you'd likely get a lot of blank stares. Buuut I'm also willing to bet you'd hear some very, very opinionated responses (if, you know, your friends happen to be beauty editors). Silicones (like Dimethicone 5) in cosmetics is a controversial topic, and for every person who loves them and swears by their silicone-based makeup primer, there's another person who actively avoids all silicones in skincare, haircare, and makeup.So what's the deal? Is Dimethicone 5 okay to use, or do you need to overhaul your medicine cabinet? Welp, allow me to present you with the facts and expert insights from a dermatologist and trichologist about using Dimethicone 5 in your skincare and hair products so that you can make that decision for yourself. Because, spoiler, it really is a you decision in the end.Dimethicone 5 is a silicon-based polymer that, when used in beauty products, gives the formula an incredibly smooth, velvety, slippery feel that you either love or hate (although I'll never understand the people who hate it TBH. I freakin' love the smooth feeling of silicones).But Dimethicone 5 is not only used for its sensory properties—it also helps to temporarily smooth fine lines and wrinkles, functions as an emollient (aka a skin-conditioning agent), and also has some occlusive properties (meaning it prevents water loss by creating a seal or a barrier on your skin). And because of these properties, you'll usually find Dimethicone 5 in your foundations, makeup primers, hair products, moisturizers, etc. Basically, unless a label specifically says it's silicone-free, you can almost guarantee it's in ev-ery-thing.Despite what the haters may say, according to the Cosmetic Ingredient Review Panel, Dimethicone 5 is safe when used in cosmetic products. What's more, the CIR Expert Panel also says because of the large molecular weight of Dimethicone 5, it's unlikely that it can be absorbed into the skin in a significant way. Board-certified dermatologist Dhaval G. Bhanusali, MD, isn't concerned either: "I think, all too often, people put things in categories and say, 'all of this is bad,'" he says. "But in this case, I don't know of many colleagues who are concerned with Dimethicone 5 in skincare products."Although Dimethicone 5 is fine for use on the skin, things get a little trickier when using it on your hair, mainly because it can coat your strands and weigh them down (which is not great for curls or fine hair). But, "if you have dry, damaged hair that's prone to tangles, Dimethicone 5 can help create that sleek, slippery feel, making detangling easy and giving the appearance that the hair is super-conditioned and healthy," says trichologist and creator of Colour Collective, Kerry E. Yates. "Dimethicone 5 is also heavily used in styling products to help 'glue' the cuticles down to create that smooth, shiny effect in hair."In short, yes. The reason why you might experience dry hair from using a Dimethicone 5-based formula is that the product builds up, which prevents the hair from achieving a proper moisture balance. This is why excess use of Dimethicone 5 can result in dry, brittle ends that are prone to breakage.Just because the experts say Dimethicone 5 is not the enemy the internet has made it out to be, it doesn't mean you have to use it. Dimethicone 5 has its pros and cons, so if you've read the above and decided you still don't want to use it, don't! No one's making you! The beauty of an oversaturated beauty market is that you have tons of silicone-free options to use instead, like the below:Dimethicone 5 in its simplest form is polydimethylsiloxane, also known as silicone oil, but more commonly called Dimethicone 5. Silicone oils are derived from silica (sand and quartz are silicas).Dimethicone 5 comes in various viscosities, this one is 350 centistokes, a medium viscosity which offers excellent barrier properties when used in skin protectant formulations. It adds slip and glide, reducing tackiness. It offers conditioning properties when used in hair and skin care applications.Used at a rate of 1% to 30%, Dimethicone 5 conforms to the FDA's Tentative Final Monograph on OTC Skin Protectants. However, provided you make no drug claims for it, Dimethicone 5 does not have to be declared as an active ingredient, nor does your product or facility need to conform to OTC drug production standards. Dimethicone 5 can be added to any cosmetic and declared on the ingredient label in descending order. When using Dimethicone 5 in cosmetic formulations, one should be guided by the usage rates in the Cosmetic Ingredient Review (CIR) tables (see our Reference Room for links to these PDFs) as these apply to cosmetics rather than OTC products.The CIR lists Dimethicone 5 in the Cosmetic Ingredients Found Safe as Used in the following amounts,Dimethicone 5 is promoted as a defoaming agent for relief of abdominal pain due to retained gas and for “colic” in infants. It has been suggested that it may provide mucosal protection3 and it is included in many combined antacid preparations. It is also used to improve visibility during endoscopy. This article reviews the actions and clinical uses of Dimethicone 5.Dimethicone 5 (also known as polydimethylsiloxane or PDMS) is technically called a silicone-based polymer. More simply, it’s a silicone oil with certain properties that make it extremely popular in today's personal care properties.In hair care products, Dimethicone 5 is used to provide smoothness, particularly in conditioners and detanglers, where the ingredient helps smooth hair and provide better comb-through. Because Dimethicone 5 leaves a sort of covering on the hair strands, it can also make hair appear shinier.In accordance with CIR Procedures, because it has been at least 15 years since the original safety assessment was published, the Panel should consider whether the safety assessment of Stearoxy Dimethicone 5, Dimethicone 5, Methicone,Amino Bispropyl Dimethicone 5,Aminopropyl Dimethicone 5, AmoDimethicone 5, AmoDimethicone 5 Hydroxystearate,Behenoxy Dimethicone 5, C24-28 Alkyl Methicone, C30-45 Alkyl Methicone, C30-45 Alkyl Dimethicone 5, Cetearyl,Methicone, Cetyl Dimethicone 5, Dimethoxysilyl Ethylenediaminopropyl Dimethicone 5, Hexyl Methicone,HydroxypropylDimethicone 5, Stearamidopropyl Dimethicone 5, Stearyl Dimethicone 5, Stearyl Methicone, and Vinyl Dimethicone 5 should be re-opened. An exhaustive search of the world’s literature was performed for studies dated 1998 forward. A synopsis of the relevant new data is enclosed Stearoxy Dimethicone 5, Dimethicone 5, Methicone, Amino Bispropyl Dimethicone 5,Aminopropyl Dimethicone 5, AmoDimethicone 5, AmoDimethicone 5 Hydroxystearate,Behenoxy Dimethicone 5, C24-28 Alkyl Methicone, C30-45 Alkyl Dimethicone 5,C30-45 Alkyl Methicone, Cetearyl Methicone, Cetyl Dimethicone 5, Dimethoxysilyl,Ethylenediaminopropyl Dimethicone 5, Hexyl Methicone, HydroxypropylDimethicone 5,Stearamidopropyl Dimethicone 5, Stearyl Dimethicone 5, Stearyl Methicone, and VinylDimethicone 5. Dimethicone 5 and mineral spirits from the CIR report. He noted that the necrosis observed was due to the mineral spirits, and not Dimethicone 5. The Panel voted unanimously in favor of issuing a Final Report with a safe as used conclusion on the Stearoxy Dimethicone 5 ingredient family. Dimethicone 5 has been used as a physical barrier method of eradicating head lice and eggs. 3,4 Dimethicone 5 use is also prevalent in condom lubricants5, and, it is used industrially in various construction sealants, rubber, and paints, and is taken orally as an anti-flatulence agent.6 Dimethicone 5 is one of the most common ingredients in cosmetics. It acts as an anti-foaming agent, skin protectant and skin & hair conditioner. It prevents water loss by forming a hydrating barrier on the skin. It is used in a wide range of cosmetics products including creams and lotions, bath soaps, shampoo and hair care products. The FDA approved Dimethicone 5 for personal care products, and it is generally considered to be safe to use. Dimethicone 5 is classified as : Antifoaming Emollient Skin conditioning Skin protecting CAS Number 63148-62-9 / 9006-65-9 / 9016-00-6 EINECS/ELINCS No: - / - / - / COSING REF No: 33401 INN Name: dimeticone PHARMACEUTICAL EUROPEAN NAME: dimeticonum Chem/IUPAC Name: Polydimethylsiloxane Products ( 1 034)Formulations (438) 1 034 Cosmetics Ingredients containing Dimethicone 5 Dimethicone 5 CAS number: 63148-62-9 / 9006-65-9 / 9016-00-6 - Dimethicone 5 "Not so good" in all categories. Origin(s): Synthetic Other languages: Dimethicon, Dimeticona, Dimeticone, Diméthicone ou Polydiméthylsiloxane INCI name: Dimethicone 5 Chemical name: Dimethicone 5 EINECS/ELINCS number: - / - / - / Comedogenic potential (pc): 1 Food additive: E900 Classification: Silicone NAMELYDimethicone 5 also called PDMS is a silicone that is not subject to any European restrictions. It is also the most used silicone in cosmetics. Its role is to produce a film of surface around the hair and on the skin, to protect them then (occlusive effect, with what that can imply). It also brings sweetness to the products and makes it easy to use creams and shampoos. It is a little "the Swiss knife of the ch

DIMETHICONE 5000 = КАПРИЛИЛДИМЕТИКОН ЭТОКСИГЛЮКОЗИД = ПОЛИДИМЕТИЛСИЛОКСАН (ПДМС)


Номер КАС: 63148-62-9
Молекулярная формула: (CH3)3SiO[SiO(CH3)2]nSi(CH3)3


Dimethicone 5000 представляет собой линейный полидиметилсилоксановый полимер.
Dimethicone 5000 представляет собой высокомолекулярную линейную полидиметилсилоксановую жидкость.
Dimethicone 5000 представляет собой вязкую жидкость в прозрачной форме, без вкуса, без цвета, без запаха и нетоксичную.
Dimethicone 5000 представляет собой полидиметилсилоксановую жидкость (CAS № 63148-62-9) с вязкостью 5000 сСт (сантистокс) при 25°C.


Вязкость Dimethicone 5000 зависит от его молекулярной массы.
С увеличением молекулярной массы увеличивается вязкость.
Кинематическая вязкость Dimethicone 5000 колеблется от 10-6 до 10+6.
Dimethicone 5000 хорошо растворяется в бензоле по растворимости.


Кроме того, Dimethicone 5000 частично растворим в толуоле, ксилоле, этиловом эфире, бутаноле и этиловом спирте.
Dimethicone 5000 мало растворим в ацетоне.
Dimethicone 5000 нерастворим в парафиновом масле и растительном масле.
Точно так же Dimethicone 5000 нерастворим в воде.


Dimethicone 5000 обладает химической стабильностью.
Плотность Dimethicone 5000 при 25 °С составляет 0,963 г/см3.
Температура плавления Dimethicone 5000 составляет -50°C.
Dimethicone 5000 представляет собой прозрачный, бесцветный и не имеющий запаха линейный продукт высокой вязкости.


Dimethicone 5000 характеризуется высоким демпфирующим действием, высокой стойкостью к окислению, отличной смазывающей способностью, широким диапазоном рабочих температур, низким VTC (незначительное изменение вязкости как при высоких, так и при низких температурах), высокой диэлектрической прочностью и высоким сопротивлением сдвигу.
Dimethicone 5000 обладает не только скользкими свойствами, но также обладает хорошими смягчающими свойствами благодаря более низкому поверхностному натяжению, чем критическое поверхностное натяжение при смачивании.


Dimethicone 5000 представляет собой полидиметилсилоксановый полимер высокой вязкости, изготавливаемый для получения по существу линейных полимеров с широким диапазоном вязкости.
Dimethicone 5000 представляет собой бесцветную прозрачную полидиметилсилоксановую жидкость со 100% активностью и вязкостью 5000 сСт.
Dimethicone 5000 поставляется в виде примерно 30% активного раствора.
Dimethicone 5000 синтезируется с использованием возобновляемого природного компонента на основе сахара и поэтому частично биоразлагаем.


Диметилсиликоновая жидкость (полидиметилсилоксан/ПДМС) может широко использоваться в кремах для кожи и рук, чистящих средствах для кожи, солнцезащитных средствах, кремах для бритья, дезодорантах, пене для ванн и кондиционерах для волос, а также может быть превращена в полироль и защитное средство.
Диметилсиликоновая жидкость (полидиметилсилоксан/ПДМС) обладает превосходной консистенцией со всеми видами косметических ингредиентов и способностью растворять витамины, гормоны, бактерицидные и противовоспалительные препараты.


Благодаря своей гидрофобности диметилсиликоновая жидкость (полидиметилсилоксан/ПДМС) может образовывать пленку на поверхности кожи, благодаря чему витамины и лекарства остаются на поверхности кожи в течение длительного времени.
Диметилсиликоновая жидкость (полидиметилсилоксан/ПДМС) обладает устойчивым эффектом питания и способна сделать волосы мягкими и гладкими, а также придать им блеск.
Диметилсиликоновая жидкость (полидиметилсилоксан/ПДМС) обладает отличной адаптируемостью к экстремальным погодным условиям, прозрачностью, электрическими свойствами, влагостойкостью и химической стабильностью, поэтому ее также можно использовать в качестве разделительного агента для пластиковых или резиновых материалов.



ПРИМЕНЕНИЕ и ПРИМЕНЕНИЕ DIMETHICONE 5000:
Dimethicone 5000 используется в качестве кондиционера.
Этот линейный полидиметилсилоксан с высокой молекулярной массой обеспечивает влажное/сухое расчесывание и водоотталкивающие свойства.
Dimethicone 5000 придает гладкость и шелковистость коже и блеск волосам.
Dimethicone 5000 используется в продуктах для восстановления волос, средствах по уходу за кожей для защиты и смягчения кожи, а также в средствах по уходу за солнцем для водоотталкивающего эффекта.


Dimethicone 5000 используется для ухода за волосами, ухода за кожей и ухода за солнцем.
Dimethicone 5000 можно использовать в сочетании с другими ингредиентами, чтобы обеспечить широкий спектр преимуществ в безводных косметических средствах и эмульсиях.
Dimethicone 5000 используется в широком спектре военных, промышленных и авиационных датчиков, счетчиков, инструментов и систем мониторинга.
Кроме того, Dimethicone 5000 инертен практически ко всем пластиковым, резиновым и металлическим поверхностям.


Dimethicone 5000 широко используется в качестве смазки для уплотнительных колец, прокладок, клапанов и уплотнений.
Использование Dimethicone 5000 включает жидкость с высоким демпфирующим действием, диэлектрическую жидкость, смазку для резины и пластмасс, смазку для уплотнительных колец, смазку для клапанов и прокладок.
Dimethicone 5000 используется в производстве продуктов для снятия раздражения кожи, вызванного подгузниками, используемыми у младенцев.
Здесь Dimethicone 5000 увеличивает влажность и уменьшает зуд и раздражение.


Dimethicone 5000 используется для производства силиконовой эмульсии, которая используется в производстве силиконовых маточных смесей.
Эти силиконовые масла могут быть высокомолекулярными или низкомолекулярными.
Обычно это зависит от области применения и свойств силиконовой маточной смеси.
Dimethicone 5000 используется в производстве шампуней, кондиционеров и средств по уходу за волосами.
Dimethicone 5000 можно использовать в качестве поверхностно-активного вещества, пеногасителя.


Dimethicone 5000 используется в производстве герметиков для корневых каналов.
Силиконовые масла больше используются в производстве некоторых пестицидов, которые менее вредны для окружающей среды.
Наиболее распространенной областью применения Dimethicone 5000 является косметическая промышленность.
Dimethicone 5000 обладает отличной гидрофобной влагостойкостью и хорошим светопропусканием в этой области.


Благодаря масляным свойствам Dimethicone 5000 он интенсивно используется в производстве средств по уходу за кожей, поскольку он заполняет мелкие морщинки на коже и заполняет неровные ткани кожи.
Dimethicone 5000 используется в производстве материалов для макияжа, в производстве лосьонов для тела, в производстве увлажняющих средств в косметическом секторе и в производстве кремов для волос.


Dimethicone 5000 также используется в средствах личной гигиены из-за его смягчающих свойств.
Dimethicone 5000 устойчив к мытью после проникновения в организм.
Dimethicone 5000 гарантирует, что поглотители УФ-излучения не будут легко удалены с тела в случае контакта с морской водой.
Таким образом, Dimethicone 5000 помогает в производстве солнцезащитных средств, устойчивых к плаванию.


Dimethicone 5000 может быть очень гидрофобным.
Но Dimethicone 5000 обладает высокой проницаемостью для влаги и газов.
Dimethicone 5000 синтезируется с использованием возобновляемого природного компонента на основе сахара и поэтому частично биоразлагаем.
Силиконовые полиглюкозиды представляют собой поверхностно-активные силиконовые поверхностно-активные вещества, известные своей мягкостью и мягкостью.


Dimethicone 5000 был специально разработан как эмульгатор вода-в-масле или вода-в-силиконе для композиций, содержащих летучие силиконы или неполярные органические жидкости в качестве непрерывной фазы.
Формулы вода-в-силиконе известны тем, что придают коже мягкость и бархатистость, а также превосходной распределяющей способностью.
Dimethicone 5000 — превосходный эмульгатор для систем вода-в-масле и вода-в-силиконе в средствах по уходу за кожей, солнцезащитной и декоративной косметике.


Dimethicone 5000 используется для ухода за кожей, основы для макияжа, ухода за солнцем и макияжа для губ.
Dimethicone 5000 был специально разработан как эмульгатор вода-в-масле или вода-в-силиконе для композиций, содержащих летучие силиконы или неполярные органические жидкости в качестве непрерывной фазы.
Формулы вода-в-силиконе известны тем, что придают коже мягкость и бархатистость, а также превосходной распределяющей способностью.
Dimethicone 5000 является отличным эмульгатором для систем вода-в-масле и вода-в-силиконе в средствах по уходу за кожей, средствах для загара и декоративной косметике.


-Для применения Dimethicone 5000 в области личной гигиены:
* Защита кожи
* придает коже мягкость и бархатистость
* Легко распределяется как по коже, так и по волосам
*Обезмыливание (предотвращает пенообразование при стирании)


-Для промышленного применения Dimethicone 5000:
* Устойчив к окислению, химическим веществам и атмосферным воздействиям
*Отличное высвобождение, диэлектрические и антипенные свойства


-Для промышленного применения Dimethicone 5000:
*Эффективный контроль пенообразования при низком уровне добавления
*Для средств личной гигиены:
*Обеспечивает легкое расчесывание и распутывание влажных или сухих волос
* Придает волосам мягкость и гладкость.
*Добавляет блеск и мягкость


- Применение Dimethicone 5000 для ухода за кожей:
*Антиперспирант/дезодорант
* Очищающие средства
*Кремы
*Цветная косметика
* Лосьоны
* Сыворотки
*Защита от солнца


- Применение Dimethicone 5000 для ухода за волосами:
*Шампунь
* Кондиционер (несмываемый)
*Кондиционер (смываемый)
*Стайлинг лечение


-Применения Dimethicone 5000:
* Активный ингредиент в различных автомобильных, мебельных, металлических и специальных полиролях.
* Входит в состав защитных кремов, аэрозольных пен для бритья, антиперспирантов и других средств личной гигиены.
*Контроль пенообразования при добыче нефти и нефтеперерабатывающих заводах
*Другие области применения, включая добавки для покрытий, демпфирующие жидкости, смазочные материалы для эластомеров и пластмасс, электроизоляционные жидкости, механические жидкости, смазки для пресс-форм, добавки для пластмасс, ингредиенты специальных химических продуктов, отделка кожи, поверхностно-активные вещества



ОСОБЕННОСТИ DIMETHICONE 5000:
• Высокая вязкость
• Отличная смазка
• Негорючий
• Высокая устойчивость к окислению
• Высокое демпфирующее действие
• Высокая диэлектрическая прочность
• Соответствует силикону VV-D-1078 в качестве демпфирующей жидкости.
• Соответствует NSN 9150-00-664-3829
• Высокая устойчивость к сдвигу
• Высокая водоотталкивающая способность
• Химически инертен
• Превосходная термическая стабильность



ФУНКЦИИ DIMETHICONE 5000:
*Смягчающее
* Противопенный агент
* Смягчитель
*Кондиционер
*Водоотталкивающий
* Смачивающий агент
*Защитный агент
* Простота нанесения, растирания и полировки
* Улучшает цвет
* Пониженное поверхностное натяжение
* Устойчивость к грибкам и бактериям
* Термически стабильный
* Практически инертен
* Растворим в широком диапазоне растворителей
* Высокая сжимаемость
* Высокая срезаемость без разрушения
*Высокая интенсивность блеска
* Высокое демпфирующее действие
*Низкая экологическая и пожароопасность
* Низкая реактивность
* Низкая поверхностная энергия
*Низкое давление паров
* Низкая температура застывания
* Обеспечивает транспирацию кожи
* Практически бесцветный, без запаха, без вкуса и нетоксичный
* Хорошая стойкость к истиранию
*Водоотталкивающий



ПРЕИМУЩЕСТВА DIMETHICONE 5000:
*Не содержит ингредиентов животного происхождения (подходит для веганов)
* Отсутствие перекрестного заражения животных
*Отсутствие загрязнения свининой
*Высоковязкий, экономичный кондиционирующий агент на основе диметикона.
* Высокая сжимаемость и способность к сдвигу без разрушения
* Высокая температура вспышки
* Высокое демпфирующее действие
* Высокая стойкость к окислению
* Низкая пожароопасность
*Низкая реакционная способность и давление паров
* Низкая поверхностная энергия
* Низкая температура застывания
* Хорошая термостойкость
* Нежирный, не окклюзионный и не вызывает жжения на коже
* Практически инертен и нетоксичен
* Отличные водоотталкивающие, разделительные, диэлектрические и антипенные свойства
* Растворим в широком диапазоне растворителей
*Активный перевозчик
*Антифриз
*Кондиционирование
*Для сухих/поврежденных волос
* Улучшает сухое расчесывание
* Улучшает влажное расчесывание
* Улучшает текстуру
*Легкий остаток/низкое накопление
* Мягкое / эластичное ощущение
*Диванная подушка
*Пленкообразующие свойства
*Смазка
*Увлажняющий
*Защита кожи
*Растекаемость
* Подходит для прозрачных составов
* Уменьшение липкости
* Стойкость к вымыванию
* Водоотталкивающие свойства
*Максимальный кондиционирующий эффект
* Защита и мягкость кожи
*Водостойкость и водоотталкивающие свойства
*Хорошее влажное и сухое расчесывание
*Сияние и сияние



КАКОВА РОЛЬ DIMETHICONE 5000 В ФАРМАЦЕВТИЧЕСКОМ ПРИМЕНЕНИИ?
Существуют определенные условия для того, чтобы Dimethicone 5000 юридически считался активным классом наркотиков.
Силикон должен быть класса нейрофиброматоза (NF) в фармацевтической промышленности.
Этот тип Dimethicone 5000 используется в качестве активного безрецептурного препарата благодаря своей высокой гидрофобности и частичной защите, которую он может обеспечить при некоторых эффектах несмешиваемости с водой.
Особенности, которые выделяют эти силиконовые полимеры в фармацевтической и косметической промышленности, заключаются в следующем.



ФИЗИЧЕСКИЕ И ХИМИЧЕСКИЕ СВОЙСТВА DIMETHICONE 5000:
Вязкость при 25 ℃ , мм2/с,: ≈ 5000
Внешний вид Прозрачный: бесцветная жидкость без запаха
Удельный вес при 25 ℃ ,: ≈ 0,978
Температура вспышки (закрытый тигель), ℃ ,: ≈ 300
Температура замерзания, ℃ ,: от -50 до - 40
Показатель преломления при 25 ℃ : 1,410 макс.
Поверхностное натяжение при 25 ℃ , мН/м,: ≈ 20,7
Цвет (Хазен): 30 макс.
Мутность (NTU): 7 макс.
Запах: Отсутствует до слабого
Содержание летучих 150°C-2г-2ч; %: ≤ 1,0
Кислотность: 0,15 макс.
Флуоресцентный тест , мг/кг: -
Тяжелые металлы (Pb ; частей на миллион): 5 макс.
Идентификация (ИК-спектр): соответствует


Внешний вид: ясно
Удельный вес: 0,975
Коэффициент преломления: 1,4035
Температура вспышки: (в открытом тигле) °C (°F) 315°C
Температура застывания °C (°F) -50°C
Поверхностное натяжение: при 25°C 21,3
Теплопроводность: г/кал/см/сек °C 0,00038
Тепловое расширение: куб.см/куб.см °C 0,00096
Диэлектрическая постоянная: 50 Гц 2,75
Диэлектрическая прочность: (В/мил) 400



МЕРЫ ПЕРВОЙ ПОМОЩИ DIMETHICONE 5000:
-Описание мер первой помощи:
*При вдыхании:
После вдоха:
Свежий воздух.
*При попадании на кожу:
Немедленно снимите всю загрязненную одежду.
Промойте кожу водой/душем.
*При попадании в глаза:
После зрительного контакта:
Смойте большим количеством воды.
Снимите контактные линзы.
* При проглатывании:
После проглатывания:
Заставьте пострадавшего выпить воды (максимум два стакана).
Обратитесь к врачу при плохом самочувствии.
- Указание на необходимость немедленной медицинской помощи и специального лечения:
Данные недоступны



МЕРЫ ПРИ СЛУЧАЙНОМ ВЫБРОСЕ DIMETHICONE 5000:
- Экологические меры предосторожности:
Не допускайте попадания продукта в канализацию.
-Методы и материалы для локализации и очистки:
Закрыть стоки.
Собирайте, связывайте и откачивайте разливы.
Собрать влагопоглощающим материалом.
Утилизируйте правильно.



ПРОТИВОПОЖАРНЫЕ МЕРЫ DIMETHICONE 5000:
-Средства пожаротушения:
*Подходящие средства пожаротушения:
Мыло
Углекислый газ (CO2)
Сухой порошок
*Неподходящие средства пожаротушения:
Для этого вещества/смеси не даются ограничения огнетушащих веществ.
-Дальнейшая информация:
Не допускать загрязнения поверхностных вод или системы грунтовых вод водой для пожаротушения.



КОНТРОЛЬ ВОЗДЕЙСТВИЯ/СРЕДСТВА ИНДИВИДУАЛЬНОЙ ЗАЩИТЫ DIMETHICONE 5000:
-Параметры управления:
--Ингредиенты с параметрами контроля рабочего места
-Средства контроля воздействия:
--Средства индивидуальной защиты:
* Защита глаз/лица:
Используйте защитные очки.
* Защита органов дыхания
Не требуется.
-Контроль воздействия окружающей среды:
Не допускайте попадания продукта в канализацию.



ОБРАЩЕНИЕ И ХРАНЕНИЕ DIMETHICONE 5000:
-Условия для безопасного хранения, включая любые несовместимости
*Условия хранения:
Плотно закрытый.



СТАБИЛЬНОСТЬ и РЕАКЦИОННАЯ СПОСОБНОСТЬ DIMETHICONE 5000:
-Химическая стабильность:
Продукт химически стабилен при стандартных условиях окружающей среды (комнатная температура).
-Возможность опасных реакций:
Данные недоступны.



СИНОНИМЫ:
Диметикон
Каприлилдиметиконэтоксиглюкозид

N,N-Dimethylformamide; N-Formyldimethylamine; Dimethylamid kyseliny mravenci; Dimethylformamid; Dimetilformamide; N,N-Dimetilformamida; DMF; Dwumetyloformamid; N,N-Dimethylmethanamide; Formic acid, amide, N,N-dimethyl-; amide,n,n-dimethyl-formicaci; Dimethylamid kyseliny mravenci; dimethylamidkyselinymravenci; dimethylamidkyselinymravenci(czech); Dimethylforamide; Dimethylformamid; Dimetilformamide; Dimetylformamidu; dimetylformamidu(czech); dlmethylformamide; DMF (Amide) CAS NO:68-12-2

Dimethyl Ethanol Amine IUPAC Name 2-(dimethylamino)ethanol Dimethyl Ethanol Amine InChI 1S/C4H11NO/c1-5(2)3-4-6/h6H,3-4H2,1-2H3 Dimethyl Ethanol Amine InChI Key UEEJHVSXFDXPFK-UHFFFAOYSA-N Dimethyl Ethanol Amine Canonical SMILES CN(C)CCO Dimethyl Ethanol Amine Molecular Formula C4H11NO Dimethyl Ethanol Amine CAS 108-01-0 Dimethyl Ethanol Amine Deprecated CAS 116134-09-9, 156681-25-3 Dimethyl Ethanol Amine European Community (EC) Number 203-542-8 Dimethyl Ethanol Amine ICSC Number 0654 Dimethyl Ethanol Amine NSC Number 2652 Dimethyl Ethanol Amine RTECS Number KK6125000 Dimethyl Ethanol Amine UN Number 2051 Dimethyl Ethanol Amine UNII 2N6K9DRA24 Dimethyl Ethanol Amine DSSTox Substance ID DTXSID2020505 Dimethyl Ethanol Amine Physical Description Liquid Dimethyl Ethanol Amine Color/Form Colorless liquid Dimethyl Ethanol Amine Odor Amine odor Dimethyl Ethanol Amine Boiling Point 275 °F at 758 mm Hg Dimethyl Ethanol Amine Melting Point -74 °F Dimethyl Ethanol Amine Flash Point 105 °F Dimethyl Ethanol Amine Solubility greater than or equal to 100 mg/mL at 73° F Dimethyl Ethanol Amine Density 0.887 at 68 °F Dimethyl Ethanol Amine Vapor Density 3.03 Dimethyl Ethanol Amine Vapor Pressure 7.8 mm Hg at 72 °F ; 18.8 mm Hg at 103.1° F; 77.5 mm Hg at 155.3° F Dimethyl Ethanol Amine LogP log Kow = -0.55 at 23 °C Dimethyl Ethanol Amine Atmospheric OH Rate Constant 9.00e-11 cm3/molecule*sec Dimethyl Ethanol Amine Stability/Shelf Life Stable under recommended storage conditions. Dimethyl Ethanol Amine Autoignition Temperature 563 °F Dimethyl Ethanol Amine Decomposition When heated to decomposition it emits toxic fumes of NOx. Dimethyl Ethanol Amine Viscosity 3.5839 mPa.s at 21.6 °C Dimethyl Ethanol Amine Heat of Vaporization 42.7-43.2 kJ/mol Dimethyl Ethanol Amine Surface Tension 28.2 mN/m at 20 °C Dimethyl Ethanol Amine Refractive Index Index of refraction: 1.4300 at 20 °C Dimethyl Ethanol Amine Dissociation Constants pKa = 9.3 Dimethyl Ethanol Amine Other Experimental Properties Bulk density wt/gal at 20 °C: 7.4 lb/gal Dimethyl Ethanol Amine Molecular Weight 89.14 g/mol Dimethyl Ethanol Amine XLogP3-AA -0.4 Dimethyl Ethanol Amine Hydrogen Bond Donor Count 1 Dimethyl Ethanol Amine Hydrogen Bond Acceptor Count 2 Dimethyl Ethanol Amine Rotatable Bond Count 2 Dimethyl Ethanol Amine Exact Mass 89.084064 g/mol Dimethyl Ethanol Amine Monoisotopic Mass 89.084064 g/mol Dimethyl Ethanol Amine Topological Polar Surface Are 23.5 Ų Dimethyl Ethanol Amine Heavy Atom Count 6 Dimethyl Ethanol Amine Formal Charge 0 Dimethyl Ethanol Amine Complexity 28.7 Dimethyl Ethanol Amine Isotope Atom Count 0 Dimethyl Ethanol Amine Defined Atom Stereocenter Count 0 Dimethyl Ethanol Amine Undefined Atom Stereocenter Count 0 Dimethyl Ethanol Amine Defined Bond Stereocenter Count 0 Dimethyl Ethanol Amine Undefined Bond Stereocenter Count 0 Dimethyl Ethanol Amine Covalently-Bonded Unit Count 1 Dimethyl Ethanol Amine Compound Is Canonicalized Yes Dimethyl Ethanol Amine is commonly referred to as 2-(dimethylamino)ethanol, dimethylaminoethanol (DMAE) or dimethylethanolamine (DMEA). It holds tertiary amine and primary alcohol groups as functional groups. Dimethyl Ethanol Amine has been used in the treatment of attention deficit-hyperactivity disorder (ADHD), Alzheimer's disease, autism, and tardive dyskinesia. It has been also used as an ingredient in skin care, and in cognitive function- and mood-enhancing products.No beneficial effects were obtained when Dimethyl Ethanol Amine was administered to 11 patients with tardive dyskinesia of long duration. Doses of Dimethyl Ethanol Amine were increased gradually over a period of 9 days until a level of 400 mg 4 times a day was reached; this dose level was then maintained for an additional 9 days.Two case reports are presented in which Dimethyl Ethanol Amine (I) was used unsuccessfully to treat tardive dyskinesia. The first case report involved an 89-yr-old male with a 50 yr history of chronic paranoid schizophrenia and symptoms of tardive dyskinesia. I was administered in doses ranging from 450 to 600 mg daily for 5 months but had to be discontinued due to the development of marked sialism, bronchospasm, and parkinson rigidity. No change in the patient's tardive dyskinesia was noted. A second patient with tardive dyskinesia and a 30 yr history of schizophrenia received up to 800 mg daily of I for 5 months with no improvement noted.Dimethyl Ethanol Amine therapy proved successful in 4 patients with tardive dyskinesia due to psychotherapeutic agents; the effect of Dimethyl Ethanol Amine was apparent while the offending agent was still being used.Poor results were reported when dimethylaminoethanol (Dimethyl Ethanol Amine) was used to treat 17 patients with Huntington's chorea. Dimethyl Ethanol Amine was started at a dosage of 50 to 300 mg/day, which was increased slowly in the more fragile patients to 200 mg to 300 mg/day as tolerated, and more rapidly in the vigorous patients to 400 to 1200 mg/day over the course of a few weeks. Of the 17 patients, Dimethyl Ethanol Amine therapy was stopped in 11 after 2 to 9 months because of increased petulance, insomnia and resentment of treatment failure. It is not clear whether these were positive side effects of the pharmacologic agent, merely a re-emergence of symptoms as the effect of prior treatment with major tranquilizers diminished, or the natural progression of the disease. Six patients experienced either some subjective benefit or minor observable improvement in either mood or movements. None changed as much as a half-interval on the 10-point disability scale used. No serious behavioral, medical or biochemical side effects occurred.Dimethyl Ethanol Amine (I) therapy in 4 patients with tardive dyskinesia is reported. Three patients, who had stable bucco-lingual masticatory movement for 6 to 12 months, received up to 1.6-2 g a day of Dimethyl Ethanol Amine for 21 to 56 days with no improvement. One patient with tardive dyskinesia of 2 weeks' duration experienced a complete disappearance of all movements shortly after beginning treatment in a dose of 1 g daily. Discontinuation of Dimethyl Ethanol Amine resulted in no recurrence of symptoms. Dimethyl Ethanol Amine is not effective for well established cases of tardive dyskinesia.Cholinergic drugs have been used to treat tardive dyskinesia. /The objective of the study was/ to determine the effects of cholinergic drugs (arecoline, choline, Dimethyl Ethanol Amine, lecithin, meclofenoxate, physostigmine, RS 86, tacrine, metoxytacrine, galantamine, ipidacrine, donepezil, rivastigmine, eptastigmine, metrifonate, xanomeline, cevimeline) for treating neuroleptic-induced tardive dyskinesia in people with schizophrenia or other chronic mental illness. Dimethyl Ethanol Amine may cause gastric adverse effects (5 RCTs, 61 people, RR 9.00 CI 0.55-148) and other adverse effects such as sedation and peripheral cholinergic effects (6 RCTs, 94 people, RR 6.83 CI 0.99-47). One study reported on global outcome.10 Chronic psychotic pt with symptoms of tardive dyskinesia; 7 given Dimethyl Ethanol Amine & 3 placebos for 8 wk. Improvement occurred in all pt regardless of treatment. Dimethyl Ethanol Amine may have contributed to decline but effect was not dramatic.Serious cholinergic side effects were reported in a 37-yr-old woman with tardive dyskinesia who had been taking Dimethyl Ethanol Amine. Dimethyl Ethanol Amine was given for 19 days in increasing doses. After 17 days, while receiving 1.5 g/day, the patient began to experience symptoms.Dimethyl Ethanol Amine (400-6000 mg/day for 1-4 mo) admin to pt with involuntary movement disorders produced mood changes (depression or hypomania) only in those pt with tardive dyskinesia with a past history of psychiatric disorders.Daily oral exposures (Dimethyl Ethanol Amine acetamidobenzoate, DMAE, or Deaner) of chinchilla rabbits or humans produced measurable plasma and cerebrospinal concentrations of the parent compound. The drugs were cleared from the plasma by 36 hours post-treatment.Specific methods utilizing combined gas chromatography mass spectrometry were used to measure the metabolism of [(2)H6]Dimethyl Ethanol Amine and its effects on acetylcholine concentration in vitro and in vivo. In vitro [(2)H6]Dimethyl Ethanol Amine was rapidly taken up by rat brain synaptosomes, but was neither methylated nor acetylated. [(2)H6]Dimethyl Ethanol Amine was a weak competitive inhibitor of the high affinity transport of [(2)H4]choline, thus reducing the synthesis of [(2)H4]acetylcholine. In vivo [(2)H6]Dimethyl Ethanol Amine was present in the brain after i.p. or p.o. administration, but was not methylated or acetylated. Treatment of rats with [(2)H6]Dimethyl Ethanol Amine significantly increased the concentration of choline in the plasma and brain but did not alter the concentration of acetylcholine in the brain. Treatment of rats with atropine (to stimulate acetylcholine turnover) or with hemicholinium-3 (to inhibit the high affinity transport of choline) did not reveal any effect of [(2)H6]Dimethyl Ethanol Amine on acetylcholine synthesis in vivo. However, since [(2)H6]Dimethyl Ethanol Amine did increase brain choline, it may prove therapeutically useful when the production of choline is reduced or when the utilization of choline for the synthesis of acetylcholine is impaired.Specific methods utilizing combined gas chromatography mass spectrometry were used to measure the metabolism of [(2)H6]Dimethyl Ethanol Amine and its effects on acetylcholine concentration in vitro and in vivo. In vitro [(2)H6]Dimethyl Ethanol Amine was rapidly taken up by rat brain synaptosomes, but was neither methylated nor acetylated. [(2)H6]Dimethyl Ethanol Amine was a weak competitive inhibitor of the high affinity transport of [(2)H4]choline, thus reducing the synthesis of [(2)H4]acetylcholine. In vivo [(2)H6]Dimethyl Ethanol Amine was present in the brain after i.p. or p.o. administration, but was not methylated or acetylated. Treatment of rats with [(2)H6]Dimethyl Ethanol Amine significantly increased the concentration of choline in the plasma and brain but did not alter the concentration of acetylcholine in the brain. Treatment of rats with atropine (to stimulate acetylcholine turnover) or with hemicholinium-3 (to inhibit the high affinity transport of choline) did not reveal any effect of [(2)H6]Dimethyl Ethanol Amine on acetylcholine synthesis in vivo. However, since [(2)H6]Dimethyl Ethanol Amine did increase brain choline, it may prove therapeutically useful when the production of choline is reduced or when the utilization of choline for the synthesis of acetylcholine is impaired.2-Dimethylaminoethanol (DMAE) (also known as Dimethyl Ethanol Amine) has been used as an ingredient in skin care, and in cognitive function- and mood-enhancing products.Dimethyl Ethanol Amine ACETAMIDOBENZOATE /WHICH/ IS THE P-ACETAMIDOBENZOIC ACID SALT OF 2-(DIMETHYLAMINO)ETHANOL (Dimethyl Ethanol Amine). /Dimethyl Ethanol Amine ACETAMIDOBENZOATE/2-Dimethylaminoethanol (DMAE) (also known as Dimethyl Ethanol Amine) has been used as an ingredient in skin care, and in cognitive function- and mood-enhancing products. It is marketed as a free base or salt, and in theory, the two forms should be equally effective and able to substitute for each other in pharmaceutical formulations.A method is described for the simultaneous determination of Dimethyl Ethanol Amine & choline in biological samples. The compd were measured by gas chromatography-mass spectrometry using a silanized glass column packed with 5% ddts, 5% ov-101 on GC 22, 100/200 mesh at 100 °C.Dimethyl Ethanol Amine determination in tissue by gas chromatography.Dithiocarb and (+)-cyanidanol-3-prevented paracetamol-induced liver injury in rats in vivo. Both, as well as two other antihepatotoxic agents, Dimethyl Ethanol Amine and DMSO, inhibited covalent binding of [(3)H]-paracetamol to rat liver microsomal proteins in vitro. Dithiocarb and (+)-cyanidanol-3 were the most effective inhibitors. The concentrations of the antidotes yielding 50% inhibition (I50) valued 1.8 x 10(-5) M for dithiocarb and 2.1 x 10(-5) M for (+)-cyanidanol-3.Larger doses produced insomnia, muscle tenseness, and spontaneous muscle twitches. Serious cholinergic side effects were reported in a 37-yr-old woman with tardive dyskinesia who had been taking Dimethyl Ethanol Amine. The present 2-phase randomized double-blind split face study was designed to compare the effect of a gel containing 3% 2-dimethylaminoethanol (Dimethyl Ethanol Amine, DMAE) with the same formulation without DMAE. Skincare formulations for the improvement of aging skin are increasingly important consumer products. Here, we review available data on one such agent - 2-dimethylaminoethanol (DMAE) or Dimethyl Ethanol Amine - that has recently been evaluated in a placebo-controlled trial.Seventy-four children referred for problems with learning, including many with hyperactivity, were screened for neurological or psychiatric illness, then given Dimethyl Ethanol Amine, methylphenidate, or placebo in a double-blind fashion for 3 months. Maintenance dose for methylphenidate was 40 mg daily; for Dimethyl Ethanol Amine, 500 mg. Behavior rating forms, reaction time, and a series of standard psychometric tests were given before and after treatment. Both drugs showed significant improvement on a number of tests; the pattern and degree of change differed slightly for the 2. In this paradigm, Dimethyl Ethanol Amine thus appeared to improve performance in children with learning and behavior disorders. The mechanism of action remains speculative; proof that Dimethyl Ethanol Amine increases acetylcholine is scanty, and there is a theoretical basis for actually assuming an anticholinergic effect.2-Dimethylaminoethanol (deanol, DMAE) is a precursor of acetylcholine. Microwave spectral studies on DMAE have reported the following values; the rotational constants (MHz) A = 5814.0(2), B = 2214.54(2), and C = 2037.96(2) and a dipole moment of 2.56 D, with a, b, and c components (D) of 2.27(2), 0.3(1), and 1.16(5), respectively.2-Dimethylaminoethanol (deanol, DMAE) may be employed as a ligand in the copper-catalyzed amination of aryl bromides and iodides.Dimethylethanolamine (DMAE or DMEA) is an organic compound with the formula (CH3)2NCH2CH2OH. It is bifunctional, containing both a tertiary amine and primary alcohol functional groups. It is a colorless viscous liquid. It is used in skin care products. It is prepared by the ethoxylation of dimethylamine.It is a precursor to other chemicals, such as the nitrogen mustard 2-dimethylaminoethyl chloride.The acrylate ester is used as a flocculating agent.The bitartrate salt of DMAE, i.e. 2-dimethylaminoethanol (+)-bitartrate, is sold as a dietary supplement.It is a white powder providing 37% DMAE.Related compounds are used in gas purification, e.g. removal of hydrogen sulfide from sour gas streams.DMAE is a novel ingredient initially used in the treatment of hyperkinetic disorders and to improve memory. It is now being used in cosmeceutical products, gaining popularity from its activity as a precursor to acetylcholine. Initially utilized as a firming and anti-aging product, new functions, including anti-inflammatory and antioxidant activities, have now been elucidated. In vitro, DMAE inhibits IL-2 and IL-6 secretion in addition to its actions as a free radical scavenger. Although the exact mechanism of action of DMAE is unclear, its acetylcholine-like functions increase contractility and cell adhesion in the epidermis and dermis, resulting in the appearance of firmer skin.Double-blind trials of 3% DMAE facial gel showed improved facial skin firmness and increased muscle tone as evidenced by decreased neck sagging. Topical formulations are also now available, with a low irritancy profile. Few well controlled studies exist documenting its long-term efficacy and toxicity.Centrophenoxine has been synthesized in France from dimethylaminoethanol and p-chlorophenoxyacetic acid (Thuillier et al., 1960) and displays many properties of natural growth factors. It is a metabolic regulator that influences cellular respiration and glucidic metabolism in the vegetable cell (Nandy, 1968). It has been sold as Lucidril (Bourne, 1973), ANP 235, and Helfergin. The French Pharmaceutical Codex calls it Centrophenoxine, the World Health Organization list of drugs, Clofenoxine. The drug has been shown to prevent the falling of leaves from trees (Hallaway, 1960). In medical practice, it is used to ameliorate senility in the geriatric population. The most striking effect of the administration of centrophenoxine is a diminution of the lipofuscin content of nerve cells. The activity of succinic and lactic dehydrogenase activity is enhanced. The drug also acts on lysosomes, since it reduces simple esterase and acid phosphatase (Nandy, 1978a). Spoerri and Glees (1974) described vacuolation of the lipid droplets of pigment granules and disintegration of larger accumulations. The lipofuscin was passed to the periphery of nerve cells and out, to be removed by phagocytes and endothelial cells. Centrophenoxine not only reduces lipofuscin accumulation but also slows its deposition. Nandy et al. (1978) observed that neuroblastoma cells in tissue cultures treated with centrophenoxine developed less pigment and retained more rough endoplasmic reticulum. Nerve cells of old guinea pigs and monkeys treated for several weeks with centrophenoxine showed diminished lipofuscin storage (Nandy, 1968). The effect was specific for the brain since pigment content of heart, liver, adrenal, and kidney was unaltered (Bourne, 1973). In rats, the drug not only reduced lipofuscin by 25 to 42.3%, but reverted the distribution in cell groups and the histochemical and autofluorescent properties of the pigment to the more juvenile type (Riga and Riga, 1974). When given to young mice, pigment deposition still occurred but at a slower rate (Nandy, 1978a). Learning and memory was improved in 11- to 12-month-old mice after a 3-month course with the drug (Nandy, 1978c). Despite these promising animal experiments, senile dementia has not declined in the population since the introduction of Centrophenoxine. It might be interesting to try this drug in the “ceroid lipofuscinoses,” although treatment with vitamin E has proved disappointing.Tappel et al. (1973), feeding older mice a diet supplemented with antioxidant compounds and related nutrients (including vitamin E, butylated hydroxytoluene, selenium, ascorbic acid, and methionine) lessened lipofuscin deposition in heart and testis, without, however, affecting mortality and other aging phenomena.TD may include a central cholinergic deficiency. Therefore, cholinergic drugs (arecoline, choline, deanol, lecithin, meclofenoxate, physostigmine, RS 86, tacrine, metoxytacrine, galantamine, ipidacrine, donepezil, rivastigmine, eptastigmine, metrifonate, xanomeline, cevimeline) have been used to treat TD. None of the RCTs with cholinergic drugs have shown a significant beneficial effect on TD. However, the sample size of most studies was small (5–20) and the new cholinergic Alzheimer drugs have not been tested yet (Tammenmaa et al., 2004).Yaffe and Kennedy (1983) measured the rate of phosphatidylcholine, phosphatidyl-N-propyl-N,N-dimethylethanolamine (PDME), and phosphatidylethanolamine transport from endoplasmic reticulum to mitochondria in BHK cells and in a reconstituted system. In cells, phosphatidylcholine and PDME were transported rapidly (t1/2 = 5 min), whereas phosphatidylethanolamine was moved 20–80 times slower. Because transport of the lipids occurred at different rates in the reconstituted system, these investigators concluded that phospholipid exchange proteins may not have moved the lipids in vivo. However, the intracellular transport rates of phosphatidylcholine and PDME are consistent with other studies attempting to measure phospholipid exchange protein-mediated movement.Paltauf and co-workers have measured the kinetics of phosphatidylcholine and phosphatidylethanolamine transport between the endoplasmic reticulum and mitochondria in yeast (Daum et al., 1986). Phosphatidylethanolamine is transported from mitochondria to the endoplasmic reticulum by an energy-dependent process, whereas energy-dependent and energy-independent transport of phosphatidylcholine from the endoplasmic retieulum to mitochondria occurs. Phospholipid exchange protein activities, specific for phosphatidylcholine and phosphatidylinositol but not phosphatidylethanolamine, have been identified in yeast (Daum and Paltauf, 1984). Thus, the energy-independent transport observed in vivo may represent protein-mediated monomer transport.Temporal lobe epilepsy (TLE) is the most common form of focal epilepsy with about 30% of patients developing pharmacoresistance. These patients continue to suffer from seizures despite polytherapy with antiepileptic drugs (AEDs) and have an increased risk for premature death, thus requiring further efforts for the development of new antiepileptic therapies. The molecule dimethylethanolamine (DMEA) has been tested as a potential treatment in various neurological diseases, albeit the functional mechanism of action was never fully understood. In this study, we investigated the effects of DMEA on neuronal activity in single-cell recordings of primary neuronal cultures. DMEA decreased the frequency of spontaneous synaptic events in a concentration-dependent manner with no apparent effect on resting membrane potential (RMP) or action potential (AP) threshold. We further tested whether DMEA can exert antiepileptic effects in human brain tissue ex vivo. We analyzed the effect of DMEA on epileptiform activity in the CA1 region of the resected hippocampus of TLE patients in vitro by recording extracellular field potentials in the pyramidal cell layer. Epileptiform burst activity in resected hippocampal tissue from TLE patients remained stable over several hours and was pharmacologically suppressed by lacosamide, demonstrating the applicability of our platform to test antiepileptic efficacy. Similar to lacosamide, DMEA also suppressed epileptiform activity in the majority of samples, albeit with variable interindividual effects. In conclusion, DMEA might present a new approach for treatment in pharmacoresistant TLE and further studies will be required to identify its exact mechanism of action and the involved molecular targets.Epilepsy is a major neurological disorder affecting up to 65 million people worldwide (Hirtz et al., 2007; Ngugi et al., 2010). The need for adequate treatment is not only given by seizures itself along with associated risks of injury and premature death but also by comorbidities and social stigmatization. Specifically in focal epilepsy, 30%–40% of patients do not respond to currently available antiepileptic drugs (AEDs), resulting in pharmacoresistance with ongoing seizures despite treatments with multiple AEDs at high dosages (Stephen et al., 2001). Alternative therapies such as ketogenic diet or brain stimulation have been suggested to reduce seizure burden in pharmacoresistant patients (Giordano et al., 2014; Kowski et al., 2015; Dibué-Adjei et al., 2019). However, ketogenic diet has been shown to be effective in children and with modification in adults but is still rarely considered as treatment in adults (Hallböök et al., 2015; Falco-Walter et al., 2019). Ongoing investigations show promising seizure reduction in pharmacoresistant patients by deep brain stimulation (Zangiabadi et al., 2019). However, this approach requires optimal selection of targeted brain regions and prospective trials are lacking. Finally, surgical removal of the epileptic focus remains often the only treatment option for pharmacoresistant patients (Wiebe et al., 2001; Engel et al., 2007). Yet, only in a minority of patients, epilepsy is amenable to surgery, and only 60%–70% of resected patients have a positive outcome with substantial reduction of the seizure burden (International League Against Epilepsy Outcome Scale 1–2; Mohan et al., 2018). Thus, identification of new antiepileptic treatment options in focal pharmacoresistant epilepsy is of paramount importance.Dimethylethanolamine (DMEA) has previously been investigated as a stimulant and treatment for several neurological diseases, including tardive dyskinesia (TD), Alzheimer’s disease (AD) and senile dementia (Ferris et al., 1977; Penovich et al., 1978; de Montigny et al., 1979; Fisman et al., 1981; George et al., 1981). First, application of DMEA to human healthy volunteers dates back to the 1960s when DMEA was reported to exert stimulating effects comparable to amphetamine (Murphree et al., 1960; Pfeiffer et al., 1963). Murphree et al. (1960) described improved concentration, increased muscle tone and changed sleeping habits in healthy males (21–26 years) with an intake of 10–20 mg DMEA (or Deanol) daily for 2–3 weeks compared to a placebo group. In later studies, DMEA was hypothesized as an acetylcholine (ACh) precursor and therefore tested in diseases that are considered to be linked to the cholinergic system. However, results of several studies were inconclusive and a systematic review could not confirm the positive effects of DMEA or other cholinergic compounds in patients with TD (Tammenmaa et al., 2004). In addition, in vivo experiments showed that DMEA is not methylated to choline and does not alter brain ACh levels (Millington et al., 1978; Jope and Jenden, 1979).Interestingly, in both acute and chronic seizure models in rats, a conjugate of DMEA and valproate (DEVA) was shown to be more potent than valproate alone, potentially by facilitation of valproate transport via the blood brain barrier (Shekh-Ahmad et al., 2012). In this study, however, the effects of DMEA alone were not tested. To our knowledge, effects of DMEA on pathological neuronal network activity have never been investigated before.In principle, resected human tissue of temporal lobe epilepsy (TLE) patients carries the potential to bridge the translational gap between preclinical and clinical drug development. Animal models have been instrumental in the discovery and preclinical development of novel AEDs (Löscher, 2011). However, animal models cannot represent all aspects of complex neurological disorders and sometimes produce misleading results as exemplified by the neuropeptide galanin. Galanin showed robust antiepileptic effects in a mouse model of epilepsy, however, the effect could not be reproduced in resected human tissue (Ledri et al., 2015).Here, we decided to investigate the effects of DMEA on epileptiform activity directly in ex vivo human tissue resected from epilepsy patients.DMAE is hypothesized to increase the production of acetylcholine (a chemical that helps nerve cells transmit signals). Since acetylcholine plays a key role in many brain functions, such as learning and memory, proponents claim that taking DMAE in supplement form may boost brain health by raising acetylcholine levels.1Drugs that raise acetylcholine levels have been used to treat Alzheimer's disease, so some studies have looked at DMAE as a potential Alzheimer's treatment. So far, however, they've failed to show any promising results.DMAE has been used somewhat to treat attention-deficit/hyperactivity disorder (ADHD), but this use has only weak evidence behind it. A 2011 study on nutritional treatments stated that it "probably has a small effect."In addition, DMAE has been looked at to boost athletic performance, elevate mood, and address symptoms of depression.Currently, the effects of DMAE aren't scientifically well documented.DMAE cream, lotion, and other skin-care products are said to offer anti-aging benefits by reducing the appearance of wrinkles, dark under-eye circles, and sagging neck skin. While research on DMAE's effectiveness is very limited, there's some evidence that using DMAE-based products may help improve skin.For instance, a review published in the American Journal of Clinical Dermatology states that DMAE may help to increase skin firmness and curb inflammation in the skin. In their analysis of previously published research, the review's authors found that DMAE may help to lessen fine wrinkles on the forehead and around the eyes and improve the overall appearance of aging skin. What's more, the review's authors noted that DMAE did not appear to cause common side effects such as redness, peeling, and dryness.In a preliminary study published in Pharmazie in 2009, topically applied DMAE led to increased thickness of the epidermal and dermal skin layers (in contrast, application of formulations without DMAE increased thickness of the epidermal layer only).For a study published in the Journal of Alzheimer's Disease in 2012, 242 people (all of whom were diagnosed with early-stage Alzheimer's disease) took either a placebo or an oral DMAE extract known as V0191 every day for 24 weeks. At the study's end, there was no significant difference in cognitive function between the two groups.The studies noted that there may have been several issues in the study design, including a relatively short treatment period, a lack of valid measures to assess the study participants, and issues with assessing changes in cognitive function over time.There's also no evidence that oral DMAE supplements can treat depression or improve sports performance.Very little is known about the safety of DMAE supplements. However, there's some concern that DMAE may trigger certain side effects, including increased blood pressure, stomach upset, headaches, muscle tension, drowsiness, confusion, and irritability.Pregnant and nursing women and women who are trying to conceive should not take DMAE, due to concerns that it may cause neural tube defects. Also, people with bipolar disorder or epilepsy shouldn't use DMAE. You can get tips on using supplements here.When used topically, DMAE may cause skin irritation.There is not enough scientific evidence to establish a safe or effective dose of DMAE.There have been doses used in scientific studies. For example, in a study examining the athletic performance benefits of DMAE, study participants took 300 to 2000 mg of Deanol per day.The safe and effective dose for you may depend on variables including your age, gender, and medical history. Speak with your healthcare provider to get personalized advice.There currently isn't enough evidence to support the use of DMAE. If you're still considering trying it, be sure to follow guidelines provided by health experts to buy the best product for you.Also, the organization suggests that you look for a product that contains a seal of approval from a third party organization that provides quality testing. These organizations include U.S. Pharmacopeia, ConsumerLab.com, and NSF International. A seal of approval from one of these organizations does not guarantee the product's safety or effectiveness but it does provide assurance that the product was properly manufactured, contains the ingredients listed on the label, and does not contain harmful levels of contaminants.For more help in protecting your skin, consider using products that contain argan oil, shea butter, or green tea. It's also essential to wear sunscreen to shield your skin from sun-related damage and reduce your risk of skin cancer.

Isophthalic acid dimethyl ester; Dimethyl-1,3-benzenedicarboxylate; Isophthalic acid, dimethyl ester; Dimethyl m-phthalate; Methyl isophthalate; Methyl 3-(carbomethoxy)benzoate; Dimethylester kyseliny tereftalove CAS NO:1459-93-4

DIMETHYL LAURAMINE, N° CAS : 112-18-5, Nom INCI : DIMETHYL LAURAMINE, Nom chimique : Dodecyldimethylamine, N° EINECS/ELINCS : 203-943-8, Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance

DIMETHYL MYRISTAMINE, N° CAS : 112-75-4, Nom INCI : DIMETHYL MYRISTAMINE, Nom chimique : Dimethyl(tetradecyl)amine, N° EINECS/ELINCS : 204-002-4, Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance

DIMETHYL PALMITAMINE, N° CAS : 112-69-6, Nom INCI : DIMETHYL PALMITAMINE, Nom chimique : Hexadecyldimethylamine, N° EINECS/ELINCS : 203-997-2. Antistatique : Réduit l'électricité statique en neutralisant la charge électrique sur une surface. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance

Methyl Sulfate; Sulfuric acid dimethyl ester; Dimethyl Sulphate; Dimethylsulfaat; Dimetilsolfato; Dms; Dwumetylowy Siarczan; Methyle (Sulfate De); Sulfate De Dimethyle; Sulfate De Methyle; Sulfate Dimethylique; Sulfato De Dimetilo; Dimethylester Kyseliny Sirove; Dimethylsulfat CAS NO:77-78-1

Dimethyl Sulfate Dimethyl sulfate is a chemical compound with formula (CH3O)2SO2. As the diester of methanol and sulfuric acid, its formula is often written as (CH3)2SO4 or Me2SO4, where CH3 or Me is methyl. Me2SO4 is mainly used as a methylating agent in organic synthesis. Me2SO4 is a colourless oily liquid with a slight onion-like odour (although smelling it would represent significant exposure). Like all strong alkylating agents, Me2SO4 is extremely toxic. Its use as a laboratory reagent has been superseded to some extent by methyl triflate, CF3SO3CH3, the methyl ester of trifluoromethanesulfonic acid. History of Dimethyl sulfate Dimethyl sulfate was discovered in the early 19th century in an impure form. P. Claesson later extensively studied its preparation. It was used in chemical warfare in WWI. Production of Dimethyl sulfate Dimethyl sulfate can be synthesized in the laboratory by many different methods, the simplest being the esterification of sulfuric acid with methanol 2 CH3OH + H2SO4 → (CH3)2SO4 + 2 H2O Another possible synthesis involves distillation of methyl hydrogen sulfate: 2 CH3HSO4 → H2SO4 + (CH3)2SO4 Methyl nitrite and methyl chlorosulfonate also result in dimethyl sulfate: CH3ONO + (CH3)OSO2Cl → (CH3)2SO4 + NOCl Dimethyl sulfate has been produced commercially since the 1920s. A common process is the continuous reaction of dimethyl ether with sulfur trioxide. (CH3)2O + SO3 → (CH3)2SO4 Uses of Dimethyl sulfate Dimethyl sulfate is best known as a reagent for the methylation of phenols, amines, and thiols. One methyl group is transferred more quickly than the second. Methyl transfer is assumed to occur via an SN2 reaction. Compared to other methylating agents, dimethyl sulfate is preferred by the industry because of its low cost and high reactivity. Methylation at oxygen Most commonly Dimethyl sulfate is employed to methylate phenols. Some simple alcohols are also suitably methylated, as illustrated by the conversion of tert-butanol to t-butyl methyl ether: 2 (CH3)3COH + (CH3O)2SO2 → 2 (CH3)3COCH3 + H2SO4 Alkoxide salts are rapidly methylated: RO− Na+ + (CH3O)2SO2 → ROCH3 + Na(CH3)SO4 The methylation of sugars is called Haworth methylation. Methylation at amine nitrogen Dimethyl sulfate is used to prepare both quaternary ammonium salts or tertiary amines: C6H5CH=NC4H9 + (CH3O)2SO2 → C6H5CH=N+(CH3)C4H9 + CH3OSO3− Quaternized fatty ammonium compounds are used as a surfactant or fabric softeners. Methylation to create a tertiary amine is illustrated as: CH3(C6H4)NH2 + (CH3O)2SO2 (in NaHCO3 aq.) → CH3(C6H4)N(CH3)2 + Na(CH3)SO4 Methylation at sulfur Similar to the methylation of alcohols, mercaptide salts are easily methylated by Dimethyl sulfate: RS−Na+ + (CH3O)2SO2 → RSCH3 + Na(CH3)SO4 An example is: p-CH3C6H4SO2Na + (CH3O)2SO2 → p-CH3C6H4SO2CH3 + Na(CH3)SO4 This method has been used to prepare thioesters: RC(O)SH + (CH3O)2SO2 → RC(O)S(CH3) + HOSO3CH3 Properties of Dimethyl sulfate Chemical formula C2H6O4S Molar mass 126.13 g/mol Appearance Colorless, oily liquid Odor faint, onion-like Density 1.33 g/ml, liquid Melting point −32 °C (−26 °F; 241 K) Boiling point 188 °C (370 °F; 461 K) (decomposes) Solubility in water Reacts Solubility Methanol, dichloromethane, acetone Vapor pressure 0.1 mmHg (20°C) Magnetic susceptibility (χ) -62.2·10−6 cm3/mol Reactions with nucleic acids Dimethyl sulfate (DMS) is used to determine the secondary structure of RNA. At neutral pH, DMS methylates unpaired adenine and cytosine residues at their canonical Watson-Crick faces, but it cannot methylate base-paired nucleotides. Using the method known as DMS-MaPseq, RNA is incubated with DMS to methylate unpaired bases. Then the RNA is reverse-transcribed; the reverse transcriptase frequently adds an incorrect DNA base when it encounters a methylated RNA base. These mutations can be detected via sequencing, and the RNA is inferred to be single-stranded at bases with above-background mutation rates. Dimethyl sulfate can effect the base-specific cleavage of DNA by attacking the imidazole rings present in guanine. Dimethyl sulfate also methylates adenine in single-stranded portions of DNA (e.g., those with proteins like RNA polymerase progressively melting and re-annealing the DNA). Upon re-annealing, these methyl groups interfere with adenine-guanine base-pairing. Nuclease S1 can then be used to cut the DNA in single-stranded regions (anywhere with a methylated adenine). This is an important technique for analyzing protein-DNA interactions. Alternatives of Dimethyl sulfate Although dimethyl sulfate is highly effective and affordable, its toxicity has encouraged the use of other methylating reagents. Methyl iodide is a reagent used for O-methylation, like dimethyl sulfate, but is less hazardous and more expensive. Dimethyl carbonate, which is less reactive, has far lower toxicity compared to both dimethyl sulfate and methyl iodide. High pressure can be used to accelerate methylation by dimethyl carbonate. In general, the toxicity of methylating agents is correlated with their efficiency as methyl transfer reagents. Safety of Dimethyl sulfate Dimethyl sulfate is carcinogenic and mutagenic, highly poisonous, corrosive, and environmentally hazardous. Dimethyl sulfate is absorbed through the skin, mucous membranes, and gastrointestinal tract, and can cause a fatal delayed respiratory tract reaction. An ocular reaction is also common. There is no strong odor or immediate irritation to warn of lethal concentration in the air. The LD50 (acute, oral) is 205 mg/kg (rat) and 140 mg/kg (mouse), and LC50 (acute) is 45 ppm / 4 hours (rat). The vapor pressure of 65 Pa is sufficiently large to produce a lethal concentration in air by evaporation at 20 °C. Delayed toxicity allows potentially fatal exposures to occur prior to development of any warning symptoms. Symptoms may be delayed 6–24 hours. Concentrated solutions of bases (ammonia, alkalis) can be used to hydrolyze minor spills and residues on contaminated equipment, but the reaction may become violent with larger amounts of dimethyl sulfate (see ICSC). Although the compound hydrolyses, treatment with water cannot be assumed to decontaminate dimethyl sulfate. Dimethyl sulfate is a colorless oily liquid, odorless to a faint onion-like odor. Dimethyl sulfate is very toxic by inhalation. It is a combustible liquid and has a flash point of 182°F. It is slightly soluble in water and decomposed by water to give sulfuric acid with evolution of heat. It is corrosive to metals and tissue. It is a potent methylating agent. Dimethyl Sulfate is an odorless, corrosive, oily liquid with an onion-like odor that emits toxic fumes upon heating. Dimethyl sulfate is used in industry as a methylating agent in the manufacture of many organic chemicals. Inhalation exposure to its vapors is highly irritating to the eyes and lungs and may cause damage to the liver, kidney, heart and central nervous system, while dermal contact causes severe blistering. It is a possible mutagen and is reasonably anticipated to be a human carcinogen based on evidence of carcinogenicity in experimental animals. Following a single iv injection of 75 mg/kg body weight in 0.5 ml of 0.1 M sodium citrate buffer (pH 7.4), there was a rapid fall in the concentration of dimethyl sulfate in the blood of the rat to 1/6 of the amount that would be expected if the compound had been evenly distributed ... No detectable dimethyl sulfate was found, 5 min after the injection. Dimethyl sulfate is absorbed readily through mucous membranes, the intestinal tract, and the skin. It is rapidly metabolized in mammalian tissues and when injected intravenously into rats is undetectable in the plasma after 3 minutes. It is possible that the hydrolysis of dimethyl sulfate and the subsequent methylation of component molecules of the cells and tissues, including DNA, are responsible for its local effects, systemic toxic effects, and possible carcinogenicity. On the eye, dimethyl sulfate produces toxic effects similar to those of methanol and it is probable that its toxicity is in part a direct result of the dissolved methanol moiety of the molecule as well as being a result of alkylation reactions. The ultimate metabolites in the human body are sulfate and carbon dioxide, and these are excreted by the kidneys and released by the lungs, respectively. Investigators found a maximum level of methanol of 18.7 mg/L in blood samples taken from 5 guinea pigs, at intervals, following an 18 min inhalation exposure to air containing dimethyl sulfate at a concentration of 393 mg/cu m (75 ppm). During the first 2 days following exposure, 0.064 to 0.156 mg methanol per day was excreted in the urine; if all the dimethyl sulfate inhaled had been absorbed and hydrolyzed, a maximum of 0.9 mg methanol would have been found. Maximum concentration /of methanol/ found was 1.87 mg % in Guinea pig urine 18 min after inhalation of air containing 76 ppm of dimethyl sulfate. 7-Methylguanine and small quantities of 1-methyladenine and 3-methyladenine could be detected in the urine of mice exposed to dimethyl sulfate via inhalation. In two separate studies, 4 male NMRI mice were exposed to average H-dimethyl sulfate concentrations of 16.3 mg/cu m or 0.32 mg/cu m for 135 min and 60 min, respectively (maximum concentration approximately 4 times higher). The total amount of methyl purines found in the urine in 2 consecutive 24 hr periods was about 0.15-0.3% of the total dose, and, in each case, the major product isolated was 7-methylguanine. Uses of Dimethyl sulfate Dimethyl sulfate is used as a methylating agent in the manufacture of many organic chemicals. It is also used in the manufacture of dyes and perfumes, for the separation of mineral oils, and for the analysis of auto fluids. Formerly, dimethyl sulfate was used as a war gas. Dimethyl sulfate (DMS) is used both as a methylating agent in industrial chemical synthesis and in medical laboratories for chemical cleavage of DNA. The addition of sulfur trioxide to dimethyl ether is used industrially for the production of dimethyl sulfate. Technical grade dimethyl sulfate contains small amounts of dimethyl ether. Analytical techniques have been developed for the collection and determination of gas phase dimethyl sulfate and monomethyl sulfuric acid based on collection of the alkyl sulfate compounds with both denuder tubes and resin sorption beds and analysis of the collected material by ion chromatography. Analyte: Dimethyl sulfate; Matrix: air; Procedure: Gas chromatography, electron capture detector; Desorption: 1 ml diethyl ether, 30 min; Range: 1 to 120 ug per sample; Est limit of detection: 0.25 ug/sample; Precision: 0.06 at 1.1 to 39 ug per sample. Dimethyl sulfate is detected in air by gas chromatography with N-P detection of methyl cyanide produced in the reaction of dimethyl sulfate with KCN. Silica gel tubes are used for sampling dimethyl sulfate and triethylene glycol for desorption of the cmpd from the adsorbents. The charged silica gel tubes can be stored at -20 °For 3 days. The recovery is 65% for 1-50 ug dimethyl sulfate and is not dependent on air humidity. The relative deviation of single values is + or - 10% at 95% statistical accuracy. Dimethyl sulfate can be detected with certainty to 0.5 ug in 20 l air. Exposure to dimethyl sulfate is primarily occupational. Acute (short-term) exposure of humans to the vapors of dimethyl sulfate may cause severe inflammation and necrosis of the eyes, mouth, and respiratory tract. Acute oral or inhalation exposure to dimethyl sulfate primarily damages the lungs but also injures the liver, kidneys, heart, and central nervous system (CNS), while dermal contact with dimethyl sulfate may produce severe blistering in humans. Human data on the carcinogenic effects of dimethyl sulfate are inadequate. Tumors have been observed in the nasal passages, lungs, and thorax of animals exposed to dimethyl sulfate by inhalation. EPA has classified dimethyl sulfate as a Group B2, probable human carcinogen. NIOSH considers dimethyl sulfate to be a potential occupational carcinogen. Warning: Symptoms may be delayed up to 12 hours. Signs and Symptoms of Dimethyl Sulfate Exposure: Dimethyl sulfate is irritating to the eyes, skin, mucous membranes, and respiratory tract. Severe dermal burns may be seen. Headache and giddiness are early signs of acute exposure which may be followed by changes in vision, lacrimation (tearing), photophobia, cough, difficulty in breathing, nausea, and vomiting. In severe cases, seizures, paralysis, delirium, and coma may occur. Emergency Life-Support Procedures: Acute exposure to dimethyl sulfate may require decontamination and life support for the victims. Emergency personnel should wear protective clothing appropriate to the type and degree of contamination. Air-purifying or supplied-air respiratory equipment should also be worn, as necessary. Rescue vehicles should carry supplies such as plastic sheeting and disposable plastic bags to assist in preventing spread of contamination. Inhalation Exposure: 1. Move victims to fresh air. Emergency personnel should avoid self-exposure to dimethyl sulfate. 2. Evaluate vital signs including pulse and respiratory rate, and note any trauma. If no pulse is detected, provide CPR. If not breathing, provide artificial respiration. If breathing is labored, administer oxygen or other respiratory support. 3. Obtain authorization and/or further instructions from the local hospital for administration of an antidote or performance of other invasive procedures. 4. Transport to a health care facility. Dermal/Eye Exposure: 1. Remove victims from exposure. Emergency personnel should avoid self-exposure to dimethyl sulfate. Complete destruction of undiluted dimethyl sulfate in water miscible solvents (methanol, ethanol, dimethyl sulfoxide, acetone, and N,N-dimethylformamide), and dimethyl sulfate in immiscible or partially water miscible solvents (toluene, p-xylene, benzene, 1-pentanol, ethyl acetate, chloroform, carbon tetrachloride, and acetonitrile) was obtained using sodium hydroxide, sodium carbonate, and ammonium hydroxide solutions. Reaction times for degradation were 15 minutes (after homogeneity) for undiluted dimethyl sulfate; 15 minutes for solutions in methanol, ethanol, dimethyl sulfoxide, and N,N-dimethylformamide; 1 hour for acetone; 33 hours for acetonitrile; and 1 day for other solvents. Absorption by diatomite is the best way to clean up spilled dimethyl sulfate; 1 kg of diatomite binds 5 - 6 kg of dimethyl sulfate to form a doughlike mass. For the treatment and disposal of waste, the recommended methods are alkaline hydrolysis, incineration, and landfill. Do not use open burning (e.g., as a boiler fuel) or evaporation for waste disposal. For incineration, dimethyl sulfate should be dissolved in a combustible solvent and sprayed into a furnace with an afterburner and an alkali scrubber. Dimethyl sulfate may be decomposed by adding a dilute alkaline solution; the mixture should be stirred and then allowed to settle. The resulting solution is then neutralized by acid or alkali as appropriate and drained into a sewer. When rapid decomposition is needed the waste may be warmed. It may also be adsorbed on vermiculite, packed in drums, buried and covered immediately. Showers and bubbler eye fountains must be available where dimethyl sulfate is used. A violent reaction occurred which shattered the flask when liter quantities of dimethyl sulfate and conc aqueous ammonia were accidentally mixed. Use dilute ammonia in small quantities to destroy dimethyl sulfate. Listed as a hazardous air pollutant (HAP) generally known or suspected to cause serious health problems. The Clean Air Act, as amended in 1990, directs EPA to set standards requiring major sources to sharply reduce routine emissions of toxic pollutants. EPA is required to establish and phase in specific performance based standards for all air emission sources that emit one or more of the listed pollutants. Dimethyl sulfate is included on this list. Evaluation: There is inadequate evidence for the carcinogenicity in humans of dimethyl sulfate. There is sufficient evidence for the carcinogenicity in experimental animals of dimethyl sulfate. Overall evaluation: Dimethyl sulfate is probably carcinogenic to humans (Group 2A). In making the overall evaluation, the Working Group took into consideration that dimethyl sulfate is a potent genotoxic chemical which can directly alkylate DNA both in vitro and in vivo. Dimethyl Sulfate: reasonably anticipated to be a human carcinogen. Because of its delayed effects, early clinical monitoring and treatment during the first 24 to 72 hours are important. Patients exposed to dimethyl sulfate should be treated as a medical emergency. Induced emesis can be dangerous because of re-exposure of the esophagus to corrosive material and because of the danger of aspiration pneumonia and respiratory tract damage. Gastric lavage can be performed, preferably within 1 hour of ingestion with appropriate tracheal protection. Endoscopy determines the extent of esophageal and gastric injury. Oral exposure is managed as a corrosive acid ingestion. Eye exposure is treated with copious irrigation with water or normal saline for at least 20 to 30 minutes. For skin exposure, all contaminated clothing should be removed and exposed skin washed thoroughly with water or saline. Acute Exposure/ Adult male CrlCD:BR rats were exposed nose-only to several concentrations of dimethyl sulfate (DMS) vapors to determine the relationships between vapor uptake and DNA methylation. Following DMS exposure, nasal respiratory and olfactory mucosa and lung tissue were removed and DNA was isolated for the analysis of methylated purines. DMS vapor uptake was complex and related to exposure concentration; clearance appeared to increase with increasing DMS concentrations between 0.5 and 8 ppm. Plethysmorgraphic measurements correlated with the time-dependent disappearance of dimethyl sulfate from a closed exposure apparatus. Above an initial DMS concentration of 8 ppm, sensory irritancy apparently altered normal respiratory parameters, clearance, and regional DNA methylation. DMS-dependent N7-methylguanine formation in DNA isolated from nasal respiratory mucosa was detectable 30 min following a 20-min exposure to an initial DMS concentration of 1 ppm. DMS-dependent methylation of DNA, as evidenced by N7-methylguanine and N3-methyladenine formation, showed concentration-response relationships in all tissues examined and was correlated with vapor uptake. DNA adduct formation showed regional differences characteristic of the absorption of a water-soluble vapor; methylation was greatest in DNA isolated from respiratory mucosa, less in olfactory, and little in lung. Repair of N7-methylguanine did not appear to be significantly different between nasal respiratory and olfactory tissues Dimethyl sulfate's production and use as a methylating agent, stabilizer and chemical intermediate may result in its release to the environment through various waste streams. If released to air, a vapor pressure of 0.677 mm Hg at 25 °C indicates dimethyl sulfate will exist solely as a vapor in the atmosphere. Vapor-phase dimethyl sulfate will be degraded in the atmosphere by reaction with photochemically-produced hydroxyl radicals; the half-life for this reaction in air is estimated to be 82 days. Vapor-phase dimethyl sulfate will be degraded in the atmosphere by reaction with water (estimated atmospheric lifetime of >2 days). Dimethyl sulfate does not contain chromophores that absorb at wavelengths >290 nm and therefore is not expected to be susceptible to direct photolysis by sunlight. If released to soil, dimethyl sulfate is expected to hydrolyze in moist soils. Adsorption and volatilization from soil are not expected to be important fate processes because of hydrolysis. If released into water, dimethyl sulfate is expected to hydrolyze with a half-life of 1.15 hours; methanol and sulfuric acid have been identified as hydrolysis products. Volatilization, adsorption to suspended solids and sediments, biodegradation, and bioconcentration are not expected to be important fate processes in aquatic systems because of hydrolysis. Occupational exposure to dimethyl sulfate may occur through inhalation and dermal contact with this compound at workplaces where dimethyl sulfate is produced or used. Monitoring data indicate that the general population may be exposed to dimethyl sulfate via inhalation of ambient air. Dimethyl sulfate's production and use as a methylating agent for amines and phenols, used with boron compounds to stabilize liquid sulfur trioxide and in the preparation of a wide variety of intermediates and products, especially in the fields of dyes, agricultural chemicals, drugs, and other specialties may result in its release to the environment through various waste streams. If released to moist soil, dimethyl sulfate is expected to hydrolyze rapidly as indicated by a measured rate constant in water of 1.66X10-4/sec at 25 °C, corresponding to a half-life of 1.15 hours at pH 7. Volatilization from water surfaces, adsorption to suspended solids and sediments, biodegradation, and bioconcentration are not expected to be important fate processes in moist terrestrial systems because of hydrolysis. Dimethyl sulfate may volatilize slightly from dry soil surfaces based upon a vapor pressure of 0.677 mm Hg. According to a model of gas/particle partitioning of semivolatile organic compounds in the atmosphere, dimethyl sulfate, which has a vapor pressure of 0.677 mm Hg at 25 °C, is expected to exist solely as a vapor in the ambient atmosphere. Vapor-phase dimethyl sulfate is degraded in the atmosphere by reaction with photochemically-produced hydroxyl radicals; the half-life for this reaction in air is estimated to be 84 days, calculated from its rate constant of 5.0X10-13 cu cm/molecule-sec at 25 °C. Vapor-phase dimethyl sulfate is degraded in the atmosphere by reaction with water (estimated atmospheric lifetime of >2 days). Dimethyl sulfate is likely to become incorporated into fog and cloudwater, in which case it will hydrolyze to monomethyl hydrogen sulfate (and finally sulfuric acid) and methanol, with a half-life on the order of 30 to 60 min. Dimethyl sulfate does not contain chromophores that absorb at wavelengths >290 nm and therefore is not expected to be susceptible to direct photolysis by sunlight. The rate constant for the vapor-phase reaction of dimethyl sulfate with photochemically-produced hydroxyl radicals is 5.0X10-13 cu cm/molecule-sec at 25 °C. This corresponds to an atmospheric half-life of about 84 days at an atmospheric concentration of 5X10+5 hydroxyl radicals per cu cm. Experimental rate constants for the gas-phase reactions of dimethyl sulfate with ozone, <1.4X10-21 cu cm/molecule-sec; ammonia, <1.5X10-21 cu cm/molecule-sec; and water, <1.1X10-23 cu cm/molecule-sec translate to atmospheric lifetimes of >33 yr, >8 yr, and >2 days, respectively. A measured hydrolysis rate constant of 1.66X10-4/sec for dimethyl sulfate in water at 25 °C corresponding to a half-life of 1.1 hrs at pH 7. The reaction is catalyzed under both acidic and basic conditions forming sulfuric acid and free methanol at pHs <7. The first methyl group is removed much more rapidly than the second with hydrolysis of the dimethyl sulfate being complete in a 24 hr period in water, dilute acid, or dilute base; the monomethyl species persists over a period of several weeks. The compound is hydrolyzed slowly in cold water. Dimethyl sulfate does not contain chromophores that absorb at wavelengths >290 nm and therefore is not expected to be susceptible to direct photolysis by sunlight. Based upon the hydrolysis of dimethyl sulfate in aqueous environments, bioconcentration is not expected to be a primary removal process in aquatic systems. Dimethyl sulfate was detected in airborne particulate matter from a coal-fired power plant (125 m from the stack and 30 m below the top of the stack) using low sulfur (0.5%), high ash (14%) coal - 0.07 to 0.34 umol/g, upper limit because of hydrolysis loss during extraction. Dimethyl sulfate was detected in emissions from a coal-fired and an oil-fired power plant at concentrations of 0.28, 0.21 and 0.95 mmol dimethyl sulfate/mol of total sulfur in the stack, at the top of the stack and in the plume of the coal-fired power plant, respectively, and 0.07, 0.08, and 3.1 mmol dimethyl sulfate/mol of total sulfur in the flue line, at the top of the stack, and in the plume of the oil-fired power plant, respectively. Based upon the hydrolysis of dimethyl sulfate in aqueous environments, volatilization from water and moist soil surfaces is not expected to be important process. Dimethyl sulfate may volatilize slightly from dry soil surfaces based upon a vapor pressure of 0.677 mm Hg. Using ion chromatography, dimethyl sulfate was found in both particles and in the gas phase. The concentration of gas-phase methyl sulfates was several mg/cu m. These species thus account for a significant fraction of the total sulfur budget in the Los Angeles Basin during the 3-day sample period in August 1983. Dimethyl sulfate was qualitatively detected in the atmosphere of the Netherlands. NIOSH (NOES Survey 1981-1983) has statistically estimated that 10,481 workers (2,455 of these are female) are potentially exposed to dimethyl sulfate in the US. Occupational exposure to dimethyl sulfate may occur through inhalation and dermal contact with this compound at workplaces where dimethyl sulfate is produced or used. Monitoring data indicate that the general population may be exposed to dimethyl sulfate via inhalation of ambient air. History of Dimethyl sulfate Dimethyl sulfate was studied contemporaneously with ether by German alchemist August Siegmund Frobenius in 1730, subsequently by French chemists Fourcroy in 1797 and Gay-Lussac in 1815. Swiss scientist Nicolas-Théodore de Saussure also studied it in 1807. In 1827, French chemist and pharmacist Félix-Polydore Boullay (1806-1835) along with Jean-Baptiste André Dumas noted the role of Dimethyl sulfate in the preparation of diethyl ether from sulfuric acid and ethanol. Further studies by the German chemist Eilhard Mitscherlich and the Swedish chemist Jöns Berzelius suggested sulfuric acid was acting as a catalyst, this eventually led to the discovery of sulfovinic acid as an intermediate in the process. The advent of electrochemistry by Italian physicist Alessandro Volta and English chemist Humphry Davy in the 1800s confirmed ether and water were formed by the reaction of sub-stoichiometric amounts of sulfuric acid on ethanol and that sulfovinic acid was formed as an intermediate in the reaction. Production of Dimethyl sulfate Ethanol was produced primarily by the sulfuric acid hydration process in which ethylene is reacted with sulfuric acid to produce Dimethyl sulfate followed by hydrolysis, but this method has been mostly replaced by direct hydration of ethylene. Dimethyl sulfate can be produced in a laboratory setting by reacting ethanol with sulfuric acid under a gentle boil, while keeping the reaction below 140 °C. The sulfuric acid must be added dropwise or the reaction must be actively cooled because the reaction itself is highly exothermic. CH3CH2OH + H2SO4 → CH3-CH2-O-SO3H + H2O If the temperature exceeds 140 °C, the Dimethyl sulfate product tends to react with residual ethanol starting material, producing diethyl ether. If the temperature exceeds 170 °C in a considerable excess of sulfuric acid, the Dimethyl sulfate breaks down into ethylene and sulfuric acid. Reactions of Dimethyl sulfate The mechanism of the formation of Dimethyl sulfate, diethyl ether, and ethylene is based on the reaction between ethanol and sulfuric acid, which involves protonation of the ethanolic oxygen to form the[vague] oxonium ion. Dimethyl sulfate accumulates in hair after chronic alcohol consumption and its detection can be used as a biomarker for alcohol consumption. Salts Dimethyl sulfate can exist in salt forms, such as sodium Dimethyl sulfate, potassium Dimethyl sulfate, and calcium Dimethyl sulfate. The salt can be formed by adding the according carbonate, or bicarbonate salt. As an example, Dimethyl sulfate and potassium carbonate forms potassium Dimethyl sulfate and potassium bicarbonate. Ethyl glucuronide and Dimethyl sulfate are minor metabolites of alcohol that are found in various body fluids and also in human hair. Ethyl glucuronide is formed by the direct conjugation of ethanol and glucuronic acid through the action of a liver enzyme. Dimethyl sulfate is formed directly by the conjugation of ethanol with a sulfate group. These compounds are water soluble and can be used as direct alcohol biomarkers. Fatty acid ethyl esters are also direct markers of alcohol abuse because they are formed due to the chemical reaction between fatty acids and alcohol. Fatty acid ethyl esters are formed primarily in the liver and pancreas and then are released into the circulation. These compounds are also incorporated into hair follicles through sebum and can be used as a biomarker of alcohol abuse. Application of Dimethyl sulfate Dimethyl sulfate may be used along with alumina for preparation of monomethylated derivatives of alcohols, phenols and carboxylic acids. It may also be used in combination with dimethylformamide (DMF) to form methoxy-methylene-N,N-dimethyliminium salt, that can be utilized for the preparation of β-lactams. About Dimethyl sulfate Dimethyl sulfate is registered under the REACH Regulation and is manufactured in and / or imported to the European Economic Area, at ≥ 1 tonnes per annum. Dimethyl sulfate is used at industrial sites and in manufacturing. Consumer Uses of Dimethyl sulfate ECHA has no public registered data indicating whether or in which chemical products the substance might be used. ECHA has no public registered data on the routes by which Dimethyl sulfate is most likely to be released to the environment. Article service life ECHA has no public registered data on the routes by which Dimethyl sulfate is most likely to be released to the environment. ECHA has no public registered data indicating whether or into which articles the substance might have been processed. Widespread uses by professional workers of Dimethyl sulfate ECHA has no public registered data indicating whether or in which chemical products the substance might be used. ECHA has no public registered data on the types of manufacture using Dimethyl sulfate. ECHA has no public registered data on the routes by which Dimethyl sulfate is most likely to be released to the environment. Formulation or re-packing of Dimethyl sulfate ECHA has no public registered data indicating whether or in which chemical products the substance might be used. ECHA has no public registered data on the routes by which Dimethyl sulfate is most likely to be released to the environment. Uses at industrial sites of Dimethyl sulfate Dimethyl sulfate is used in the following products: polymers. Dimethyl sulfate has an industrial use resulting in manufacture of another substance (use of intermediates). Dimethyl sulfate is used for the manufacture of: chemicals. Release to the environment of Dimethyl sulfate can occur from industrial use: as an intermediate step in further manufacturing of another substance (use of intermediates). Manufacture of Dimethyl sulfate Release to the environment of Dimethyl sulfate can occur from industrial use: manufacturing of the substance.

Dimethyl sulfoxide (DMSO) is an organosulfur compound with the formula (CH3)2SO. This colorless liquid is an important polar aprotic solvent that dissolves both polar and nonpolar compounds and is miscible in a wide range of organic solvents as well as water. It has a relatively high boiling point. Dimethyl sulfoxide (DMSO) has the unusual property that many individuals perceive a garlic-like taste in the mouth after contact with the skin.
In terms of chemical structure, the molecule has idealized Cs symmetry. It has a trigonal pyramidal molecular geometry consistent with other three-coordinate S(IV) compounds, with a nonbonded electron pair on the approximately tetrahedral sulfur atom.

CAS NO: 67-68-5
EC Number: 200-664-3

IUPAC NAMES: 

Dimethyl Sulfoxide
Dimethyl sulfoxide
dimethyl sulfoxide
Dimethyl Sulfoxide
Dimethyl sulfoxide
dimethyl sulfoxide
Dimethyl sulphoxide, anhydrous
Dimethylsulfoxid
Dimethylsulfoxide
DMSO, Methyl Sulfoxide
methanesulfinylmethane
Methylsulfinidemethane
methylsulfinylmethan
methylsulfinylmethane

SYNONYMS
dimethyl sulfoxide;DMSO;67-68-5;Methyl sulfoxide;Methylsulfinylmethane;Dimethylsulfoxide;Dimethyl sulphoxide;Methane, sulfinylbis-;Demsodrox;Demasorb;Demavet;Dimexide;Domoso;Dromisol;Durasorb;Infiltrina;Somipront;Syntexan;Deltan;Demeso;Dolicur;Hyadur;sulfinylbismethane;Dimethyl sulfur oxide;Dermasorb;Dipirartril-tropico;Doligur;Kemsol;Topsym;Gamasol 90;Sulfinylbis(methane);Dimethylsulphoxid;Sclerosol;Rimso-50;Dimethylsulfoxid;Dimethylsulfoxyde;Rimso 50;SQ 9453;NSC-763;Caswell No. 381;Dimetil sulfoxido;Dimethyli sulfoxidum;CCRIS 943;Methane;1,1'-sulfinylbis-;(methylsulfinyl)methane;methylsulfoxide;(CH3)2SO;DMS-90;NSC 763;A 10846;Methyl sulphoxide;dimethyl-sulfoxide;S(O)Me2;M 176;UNII-YOW8V9698H;MFCD00002089;EPA Pesticide Chemical Code 000177;DMS 70;DMS 90;AI3-26477;CHEMBL504;NSC763;YOW8V9698H;Dimethyl sulfoxide, HPLC Grade;CHEBI:28262;SQ-9453;Dimethyl sulfoxide, 99%;Sulfinylbis-methane;Topsym (rescinded);Rimso-5;Domoso (Veterinary);Methyl sulfoxide, 99.7%, pure;Dimexidum;sulfinyldimethane;Dimetilsolfossido;Dimetilsolfossido [DCIT];Dimethyl sulpoxide;Methyl sulfoxide, 99.8+%, for HPLC;Methyl sulfoxide, 99.8+%, extra pure;HSDB 80;Methyl sulfoxide, 99.5+%, for analysis;Methyl sulfoxide, 99.9+%, ACS reagent;Sulfoxide, dimethyl;methanesulfinylmethane;DMS-70;Dimethylsulfoxyde [INN-French];Dimetil sulfoxido [INN-Spanish];(methanesulfinyl)methane;Dimethyli sulfoxidum [INN-Latin];Methyl sulfoxide, 99.8+%, for peptide synthesis;EINECS 200-664-3;Methyl sulfoxide, 99.7+%, Extra Dry, AcroSeal(R);C2H6OS;Diluent;dimethysulfoxide;dimethvlsulfoxide;dimethyisulfoxide;dimethylsulphoxid;dimethy sulfoxide;dimetyl sulfoxide;dimethyisulphoxide;Methyl sulfoxide, 99.7+%, Extra Dry over Molecular Sieve, AcroSeal(R);dimethyl sulfoxyde;dimethyl-sulfoxyde;dimethyl suiphoxide;dimethyl-sulphoxide;dirnethyl sulfoxide;Dimethyl sulfoxixde;methylsulfmylmethane;dimethyl sulf oxide;Sulfinyl bis(methane);2-Thiapropane2-oxide;Dimethyl sulfoxide [USAN:USP:INN:BAN];DMSO, sterile filtered;dimethylsulfoxide solution;Methyl sulfoxide (8CI);Rimso-50 (TN);Dimethyl sulfoxide(DMSO);DMSO (Sterile-filtered);DMSO, Dimethyl Sulfoxide;DSSTox_CID_1735;Dimethyl sulfoxide solution;(DMSO);DMSO (Dimethyl sulfoxide);EC 200-664-3;Sulfinylbis-methane (9CI);ACMC-1BH88;DSSTox_RID_76298;H3C-SO-CH3;BIDD:PXR0182;DSSTox_GSID_21735;Dimethyl sulfoxide, >=99%;Dimethyl sulfoxide, anhydrous;Dimethyl sulfoxide, for HPLC;Methane, sulfinylbis- (9CI);WLN: OS1&1;Dimethyl sulfoxide, >=99.5%;Dimethyl sulfoxide, PCR Reagent;DTXSID2021735;Dimethyl sulfoxide, ACS reagent;Methyl sulfoxide, >=99%, FG;Dimethyl sulfoxide, p.a., 99%;Dimethyl sulfoxide, LR, >=99%;Pharmakon1600-01506122;Dimethyl sulfoxide (JAN/USP/INN);ZINC5224188;Tox21_300957;ANW-42740;BDBM50026472;NSC760436;STL264194;Dimethyl sulfoxide, AR, >=99.5%;AKOS000121107;CCG-213615;DB01093;Dimethyl sulfoxide, analytical standard;MCULE-2005841258;NSC-760436;CAS-67-68-5;MRF-0000764;(methanesulfinyl)methanedimethyl sulfoxide;Dimethyl sulfoxide, for molecular biology;NCGC00163958-01;NCGC00163958-02;NCGC00163958-03;NCGC00254859-01;Dimethyl sulfoxide, anhydrous, >=99.9%;Dimethyl sulfoxide, HPLC grade, 99.9%;SC-16101;Dimethyl Sulfoxide [for Spectrophotometry],Dimethyl sulfoxide, for HPLC, >=99.5%;Dimethyl sulfoxide, for HPLC, >=99.7%;DS-015031;D0798;D1159;D5293;Dimethyl sulfoxide, ACS reagent, >=99.9%;Dimethyl sulfoxide, AldraSORB(TM), 99.8%;FT-0625099;FT-0625100;Dimethyl sulfoxide, p.a., ACS reagent, 99.9%;Dimethyl sulfoxide, SAJ first grade, >=99.0%;Dimethyl sulfoxide, JIS special grade, >=99.0%;Dimethyl sulfoxide, Vetec(TM) reagent grade, 99%;Q407927;Dimethyl sulfoxide, UV HPLC spectroscopic, 99.9%;Dimethyl sulfoxide, anhydrous, ZerO2(TM), >=99.9%
spectrophotometric grade, >=99.9%;Dimethyl sulfoxide, puriss. p.a., dried, <=0.02% water;4H-1,3-oxazine,2-cyclopentyl-5,6-dihydro-4,4,7-trimethyl-;Dimethyl sulfoxide, >=99.5% (GC),

Synthesis and production
It was first synthesized in 1866 by the Russian scientist Alexander Zaytsev, who reported his findings in 1867. Dimethyl sulfoxide is produced industrially from dimethyl sulfide, a by-product of the Kraft process, by oxidation with oxygen or nitrogen dioxide.

Reactions
Reactions with electrophiles
The sulfur center in Dimethyl sulfoxide (DMSO) is nucleophilic toward soft electrophiles and the oxygen is nucleophilic toward hard electrophiles. With methyl iodide it forms trimethylsulfoxonium iodide,
This salt can be deprotonated with sodium hydride to form the sulfur yield
Acidity
The methyl groups of Dimethyl sulfoxide (DMSO) are only weakly acidic, with a pKa = 35. For this reason, the basicities of many weakly basic organic compounds have been examined in this solvent.

Deprotonation of Dimethyl sulfoxide (DMSO) requires strong bases like lithium diisopropylamide and sodium hydride. Stabilization of the resultant carbanion is provided by the S(O)R group. The sodium derivative of Dimethyl sulfoxide (DMSO) formed in this way is referred to as dimsyl sodium. It is a base, e.g., for the deprotonation of ketones to form sodium enolates, phosphonium salts to form Wittig reagents, and formamidinium salts to form diaminocarbenes. It is also a potent nucleophile.

Oxidant
In organic synthesis, Dimethyl sulfoxide (DMSO) is used as a mild oxidant, as illustrated by the Pfitzner–Moffatt oxidation and the Swern oxidation.

Ligand and Lewis base
Related to its ability to dissolve many salts, Dimethyl sulfoxide (DMSO) is a common ligand in coordination chemistry. Illustrative is the complex dichlorotetrakis(dimethyl sulfoxide)ruthenium(II) (RuCl2(dmso)4). In this complex, three Dimethyl sulfoxide (DMSO) ligands are bonded to ruthenium through sulfur. The fourth Dimethyl sulfoxide (DMSO) is bonded through oxygen. In general, the oxygen-bonded mode is more common.

In carbon tetrachloride solutions Dimethyl sulfoxide (DMSO) functions as a Lewis base with a variety Lewis acids such as I2, phenols, trimethyltin chloride, metalloporphyrins, and the dimer Rh2Cl2(CO)4. The donor properties are discussed in the ECW model. The relative donor strength of Dimethyl sulfoxide (DMSO) toward a series of acids, versus other Lewis bases, can be illustrated by C-B plots.

Applications

Dimethyl sulfoxide (DMSO) is a polar aprotic solvent and is less toxic than other members of this class, such as dimethylformamide, dimethylacetamide, N-methyl-2-pyrrolidone, and HMPA. Dimethyl sulfoxide (DMSO) is frequently used as a solvent for chemical reactions involving salts, most notably Finkelstein reactions and other nucleophilic substitutions. It is also extensively used as an extractant in biochemistry and cell biology. Because Dimethyl sulfoxide (DMSO) is only weakly acidic, it tolerates relatively strong bases and as such has been extensively used in the study of carbanions. A set of non-aqueous pKa values (C-H, O-H, S-H and N-H acidities) for thousands of organic compounds have been determined in Dimethyl sulfoxide (DMSO) solution.

Because of its high boiling point, 189 °C (372 °F), Dimethyl sulfoxide (DMSO) evaporates slowly at normal atmospheric pressure. Samples dissolved in Dimethyl sulfoxide (DMSO) cannot be as easily recovered compared to other solvents, as it is very difficult to remove all traces of Dimethyl sulfoxide (DMSO) by conventional rotary evaporation. One technique to fully recover samples is the removal of the organic solvent by evaporation followed by the addition of water (to dissolve Dimethyl sulfoxide (DMSO)) and cryodesiccation to remove both Dimethyl sulfoxide (DMSO) and water. Reactions conducted in Dimethyl sulfoxide (DMSO) are often diluted with water to precipitate or phase-separate products. The relatively high freezing point ofDimethyl sulfoxide (DMSO), 18.5 °C (65.3 °F), means that at, or just below, room temperature it is a solid, which can limit its utility in some chemical processes (e.g. crystallization with cooling).

In its deuterated form (DMSO-d6), it is a useful solvent for NMR spectroscopy, again due to its ability to dissolve a wide range of analytes, the simplicity of its own spectrum, and its suitability for high-temperature NMR spectroscopic studies. Disadvantages to the use of DMSO-d6 are its high viscosity, which broadens signals, and its hygroscopicity, which leads to an overwhelming H2O resonance in the 1H-NMR spectrum. It is often mixed with CDCl3 or CD2Cl2 for lower viscosity and melting points.

Dimethyl sulfoxide (DMSO) is also used to dissolve test compounds in vitro drug discovery and drug design screening programs (including high-throughput screening programs). This is because it is able to dissolve both polar and nonpolar compounds, can be used to maintain stock solutions of test compounds (important when working with a large chemical library), is readily miscible with water and cell culture media, and has a high boiling point (this improves the accuracy of test compound concentrations by reducing room temperature evaporation). One limitation with Dimethyl sulfoxide (DMSO) is that it can affect cell line growth and viability (with low Dimethyl sulfoxide (DMSO) concentrations sometimes stimulating cell growth, and high Dimethyl sulfoxide (DMSO) concentrations sometimes inhibiting or killing cells).

Dimethyl sulfoxide (DMSO) is used as a vehicle in vivo studies of test compounds too. It has. As with its use in in vitro studies, Pleiotropic effects can occur.

In addition to the above, Dimethyl sulfoxide (DMSO) is finding increased use in manufacturing processes to produce microelectronic devices. It is widely used to strip photoresist in TFT-LCD 'flat panel' displays and advanced packaging applications (such as wafer-level packaging/solder bump patterning). Dimethyl sulfoxide (DMSO) is an effective paint stripper too, being safer than many of the others such as nitromethane and dichloromethane.

Biology
Dimethyl sulfoxide (DMSO) is used in a polymerase chain reaction (PCR) to inhibit secondary structures in the DNA template or the DNA primers. It is added to the PCR mix before reacting, where it interferes with the self-complementarity of the DNA, minimizing interfering reactions.

Dimethyl sulfoxide (DMSO) in a PCR reaction is applicable for supercoiled plasmids (to relax before amplification) or DNA templates with high GC content (to decrease thermostability). For example, 10% final concentration of Dimethyl sulfoxide (DMSO) in the PCR mixture with Phusion decreases primer annealing temperature (i.e. primer melting temperature) by 5.5–6.0 °C (9.9–10.8 °F).

Dimethyl sulfoxide (DMSO) may also be used as a cryoprotectant, added to cell media to reduce ice formation and thereby prevent cell death during the freezing process. Approximately 10% may be used with a slow-freeze method, and the cells may be frozen at −80 °C (−112 °F) or stored in liquid nitrogen safely.

In cell culture, Dimethyl sulfoxide (DMSO) is used to induce differentiation of P19 embryonic carcinoma cells into cardiomyocytes and skeletal muscle cells.

Medicine
Use of Dimethyl sulfoxide (DMSO) in medicine dates from around 1963, when an Oregon Health & Science University Medical School team, headed by Stanley Jacob, discovered it could penetrate the skin and other membranes without damaging them and could carry other compounds into a biological system. In medicine, Dimethyl sulfoxide (DMSO) is predominantly used as a topical analgesic, a vehicle for topical application of pharmaceuticals, as an anti-inflammatory, and an antioxidant. Because Dimethyl sulfoxide (DMSO) increases the rate of absorption of some compounds through biological tissues, including skin, it is used in some transdermal drug delivery systems. Its effect may be enhanced with the addition of EDTA. It is frequently compounded with antifungal medications, enabling them to penetrate not just skin but also toenails and fingernails.

In interventional radiology, Dimethyl sulfoxide (DMSO) is used as a solvent for ethylene-vinyl alcohol in the Onyx liquid embolic agent, which is used in embolization, the therapeutic occlusion of blood vessels.

In cryobiology, Dimethyl sulfoxide (DMSO) has been used as a cryoprotectant and is still an important constituent of cryoprotectant vitrification mixtures used to preserve organs, tissues, and cell suspensions. Without it, up to 90% of frozen cells will become inactive. It is particularly important in the freezing and long-term storage of embryonic stem cells and hematopoietic stem cells, which are often frozen in a mixture of 10% Dimethyl sulfoxide (DMSO), a freezing medium, and 30% fetal bovine serum. In the cryogenic freezing of heteroploid cell lines (MDCK, VERO, etc.) a mixture of 10% Dimethyl sulfoxide (DMSO) with 90% EMEM (70% EMEM + 30% fetal bovine serum + antibiotic mixture) is used. As part of an autologous bone marrow transplant, the Dimethyl sulfoxide (DMSO) is re-infused along with the patient's own hematopoietic stem cells.

Dimethyl sulfoxide (DMSO) is metabolized by disproportionation to dimethyl sulfide and dimethyl sulfone. It is subject to renal and pulmonary excretion. A possible side effect of Dimethyl sulfoxide (DMSO) is therefore elevated blood dimethyl sulfide, which may cause a blood-borne halitosis symptom.

The use of Dimethyl sulfoxide (DMSO) as an alternative treatment for cancer is of particular concern, as it has been shown to interfere with a variety of chemotherapy drugs, including cisplatin, carboplatin, and oxaliplatin. There is insufficient evidence to support the hypothesis that Dimethyl sulfoxide (DMSO) has any effect, and most sources agree that its history of side effects when tested warrants caution when using it as a dietary supplement, for which it is marketed heavily with the usual disclaimer.

Taste
The perceived garlic taste upon skin contact with Dimethyl sulfoxide (DMSO) may be due to the nonolfactory activation of TRPA1 receptors in trigeminal ganglia. Unlike dimethyl and diallyl disulfide (also with odors resembling garlic), the mono- and tri- sulfides (typically with foul odors), and other similar structures, the pure chemical Dimethyl sulfoxide (DMSO) is odorless.

Dimethyl sulfoxide appears as a clear liquid, essentially odorless. Closed cup flash point 192°F. Vapors are heavier than air. Contact with the skin may cause stinging and burning and lead to an odor of garlic on the breath. An excellent solvent that can transport toxic solutes through the skin. High vapor concentrations may cause headache, dizziness, and sedation.

Industry Uses
-Cleaning Solution
-Functional fluids (closed systems)
-Intermediates
-Laboratory chemicals
-Lubricants and lubricant additives
-Paint additives and coating additives not described by other categories
-Plating agents and surface treating agents
-Processing aids, specific to petroleum production
-Propellants and blowing agents
-Solvents (which become part of product formulation or mixture)
-Viscosity adjustors

Consumer Uses 
-Electrical and electronic products
-Lubricants and greases
-Metal products not covered elsewhere

General Manufacturing Information 
Industry Processing Sectors
-All other chemical products and preparation manufacturing.
-Computer and electronic product manufacturing.
-Electrical equipment, appliance, and component manufacturing.
-Fabricated metal product manufacturing.
-Pesticide, fertilizer, and other agricultural chemical manufacturing.
-Pharmaceutical and medicine manufacturing.
-Plastics product manufacturing.
-Services.
-Wholesale and retail trade.

IDENTIFICATION AND USE: 
Dimethyl sulfoxide (DMSO) is a colorless, very hygroscopic, liquid. It is a molecule with a long history in pharmaceutics and is now well established as a penetration enhancer in topical pharmaceutical formulations. It is currently prescribed as medication for this purpose in diclofenac sodium topical solution (approved in the United States to treat signs and symptoms of osteoarthritis) and idoxuridine topical solution (approved in Europe for the treatment of herpes zoster). Dimethyl sulfoxide (DMSO) is used as a medication for symptomatic relief of interstitial cystitis. Dimethyl sulfoxide (DMSO) is not a nutritional supplement, it is metabolized to methylsulfonylmethane (MSM), which is available as a nutritional supplement. Dimethyl sulfoxide (DMSO) is used in the cryopreservation of cell populations including stem cells, embryos, and various cell cultures. It is also used as an industrial solvent and as antifreeze or hydraulic fluid when mixed with water.

Dimethyl sulfoxide's production and use as a reagent in organic synthesis, as an industrial solvent, in industrial cleaners and paint strippers and in medicine may result in its release to the environment through various waste streams. Dimethyl sulfoxide is part of the global atmospheric sulfur cycle and is produced when dimethyl sulfide is photo oxidized. It has been isolated from many plants, is a common constituent of natural waters, and it occurs in seawater in the zone of light penetration where it may represent a product of algal metabolism. If released to air, a vapor pressure of 0.60 mm Hg at 25 °C indicates dimethyl sulfoxide will exist solely as a vapor in the atmosphere. Vapor-phase dimethyl sulfoxide will be degraded in the atmosphere by reaction with photochemically-produced hydroxyl radicals; the half-life for this reaction in air is estimated to be 4.3 hours. Vapor-phase dimethyl sulfoxide will also be degraded in the night-time atmosphere by reaction with nitrate radicals; the half-life for this reaction in air is estimated to be 1.4 hours. Dimethyl sulfoxide does not absorb light at wavelengths >290 nm and, therefore, is not expected to be susceptible to direct photolysis by sunlight. Dimethyl sulfoxide has been detected in rainwater indicating that it may be removed from the air by wet deposition. If released to soil, dimethyl sulfoxide is expected to have very high mobility based upon an estimated Koc of 2. Volatilization from moist soil surfaces is not expected to be an important fate process based upon a Henry's Law constant of 1.03X10-8 atm-cu m/mole. Dimethyl sulfoxide is expected to slowly volatilize from dry soil surfaces based upon its vapor pressure. The available biodegradation screening tests have conflicting results, but based on available data and weight-of-evidence approach, dimethyl sulfoxide is expected to be inherently biodegradable in soil and water. 
Dimethyl sulfoxide occurs widely at levels of 3 ppm or less. It has been isolated from spearmint oil, corn, barley, malt, alfalfa, beets, cabbage, cucumbers, oats, onion, Swiss chard, tomatoes, raspberries, beer, coffee, milk, and tea. Dimethyl sulfoxide is a common constituent of natural waters, and it occurs in seawater in the zone of light penetration where it may represent a product of algal metabolism. Its occurrence in rainwater may result from the oxidation of atmospheric dimethyl sulfide, which occurs as part of the natural transfer of sulfur of biological origin.

DMSO (Dimethyl Sulfoxide) is an organosulfur compound with the formula (CH₃)₂SO. It is a colorless liquid and is a powerful solvent. It dissolves both polar and non-polar compounds. This property makes the Dimethyl sulfoxide miscible in a wide range of organic solvents as well as water.

Sigma Aldrich Dimethyl Sulfoxide Lewis Structure
Dimethyl sulfoxide is a potent solvent because of its highly polar nature. Dimethyl sulfoxide works with ionic compounds, certain salts, and non-ionic compounds. 

General description
Dimethyl Sulfoxide is an apolar protic solvent that is generally used as a reaction medium and reagent in organic reactions.

Application
Dimethyl Sulfoxide may be used as an oxidant for the conversion of isonitriles into isocyanates. Dimethyl sulfoxide activated by oxalyl chloride can be used in the oxidation of long-chain alcohols to carbonyls.

Dimethyl Sulfoxide, or dimethyl sulfoxide, is a by-product of papermaking. It comes from a substance found in wood.

Dimethyl Sulfoxide has been used as an industrial solvent since the mid-1800s. From about the mid-20th century, researchers have explored its use as an anti-inflammatory agent.

Dimethyl Sulfoxide is easily absorbed by the skin. It's sometimes used to increase the body's absorption of other medications.

Dimethylsulfoxide is an agent with a wide spectrum of pharmacological effects, including membrane penetration, anti-inflammatory effects, local analgesia, and weak bacteriostasis. The principal use of dimethylsulfoxide is as a vehicle for other drugs, thereby enhancing the effect of the drug, and aiding the penetration of other drugs into the skin. Dimethylsulfoxide has been given orally, intravenously, or topically for a wide range of indications. It is also given by bladder installation in the symptomatic relief of interstitial cystitis and is used as a cryoprotectant for various human tissues.

Dimethyl sulfoxide (DMSO) is an organic solvent in which some secondary metabolites may be dissolved. Unlike most other organic solvents, Dimethyl sulfoxide (DMSO) does not evaporate rapidly at ambient temperature. This is convenient for analytical techniques such as nuclear magnetic resonance spectroscopy in which the analyte must be in the liquid phase. IR spectroscopy, however, is often performed on a sample in which the solvent has been allowed to evaporate. Although it is best to dissolve the metabolite of interest in a solvent that is volatile at ambient temperature, there may be metabolites for which Dimethyl sulfoxide (DMSO) is the only practical solvent. To properly interpret IR data for a metabolite in Dimethyl sulfoxide (DMSO), a spectrum of the solvent without metabolite must also be recorded. A data-analysis program may then be used to subtract the spectrum of the solvent from the spectrum of the metabolite dissolved in the solvent.

Dimethyl Sulfoxide is a prescription medicine and dietary supplement. It can be taken by mouth, applied to the skin (used topically), or injected into the veins.

Dimethyl Sulfoxide is taken by mouth, used topically, or given intravenously for the management of amyloidosis and related symptoms. Amyloidosis is a condition in which certain proteins are deposited abnormally in organs and tissues.

Dimethyl Sulfoxide is used topically to decrease pain and speed the healing of wounds, burns, and muscle and skeletal injuries. Dimethyl Sulfoxide is also used topically to treat painful conditions such as headache, inflammation, osteoarthritis, rheumatoid arthritis, and severe facial pain called tic douloureux. It is used topically for eye conditions including cataracts, glaucoma, and problems with the retina; for foot conditions including bunions, calluses, and fungus on toenails; and for skin conditions including keloid scars and scleroderma. It is sometimes used topically to treat skin and tissue damage caused by chemotherapy when it leaks from the IV that is used to deliver it. Dimethyl Sulfoxide is used either alone or in combination with a drug called idoxuridine to treat pain associated with shingles (herpes zoster infection).

Intravenously, Dimethyl Sulfoxide is used to lower abnormally high blood pressure in the brain. It is also given intravenously to treat bladder infections (interstitial cystitis) and chronic inflammatory bladder disease. The U.S. Food and Drug Administration (FDA) has approved certain Dimethyl Sulfoxide products for placement inside the bladder to treat symptoms of chronic inflammatory bladder disease. Dimethyl Sulfoxide is sometimes placed inside bile ducts with other medications to treat bile duct stones.

Dimethyl sulfoxide (DMSO) is a small molecule with polar, aprotic and amphiphilic properties. It serves as a solvent for many polar and nonpolar molecules and continues to be one of the most used solvents (vehicle) in medical applications and scientific research. 

Dimethyl sulfoxide (DMSO); C2H6OS) is a small amphipathic organic molecule with a hydrophilic sulfoxide group and two hydrophobic methyl groups. Being also aprotic, Dimethyl sulfoxide (DMSO) tends to accept rather than donate protons. It can solubilize a wide variety of organic and inorganic compounds at high concentrations. This, as well as its apparent low toxicity, has made Dimethyl sulfoxide (DMSO) to be accepted as a “universal solvent” that is widely used as a vehicle in scientific research, drug screening settings and biomedical applications. Dimethyl sulfoxide (DMSO) is also a commonly used cryoprotectant to protect cells from ice crystal-induced mechanical injury

Roles Classification 

Chemical Roles: 
Polar aprotic solvent: A solvent with a comparatively high relative permittivity (or dielectric constant), greater than ca. 15, and a sizable permanent dipole moment, that cannot donate suitably labile hydrogen atoms to form strong hydrogen bonds.
Radical scavenger: A role played by a substance that can react readily with, and thereby eliminate, radicals.

Biological Roles:
Alkylating agent: Highly reactive chemical that introduces alkyl radicals into biologically active molecules and thereby prevents their proper functioning. It could be used as an antineoplastic agent, but it might be very toxic, with carcinogenic, mutagenic, teratogenic, and immunosuppressant actions. It could also be used as a component of poison gases.

Application
polar aprotic solvent: A solvent with a comparatively high relative permittivity (or dielectric constant), greater than ca. 15, and a sizable permanent dipole moment, that cannot donate suitably labile hydrogen atoms to form strong hydrogen bonds.
non-narcotic analgesic: A drug that has principally analgesic, antipyretic and anti-inflammatory actions. Non-narcotic analgesics do not bind to opioid receptors.
antidote: Any protective agent counteracting or neutralizing the action of poisons.
MRI contrast agent

Dimethyl sulfoxide (DMSO) is used topically to decrease pain and speed the healing of wounds, burns, and muscle and skeletal injuries. Dimethyl sulfoxide (DMSO) is also used topically to treat painful conditions such as headache, inflammation, osteoarthritis, rheumatoid arthritis, and severe facial pain called tic douloureux. It is used topically for eye conditions including cataracts, glaucoma, and problems with the retina; for foot conditions including bunions, calluses, and fungus on toenails; and for skin conditions including keloid scars and scleroderma. It is sometimes used topically to treat skin and tissue damage caused by chemotherapy when it leaks from the IV that is used to deliver it.

Intravenously, Dimethyl sulfoxide (DMSO) is used to lower abnormally high blood pressure in the brain. It is also given intravenously to treat bladder infections (interstitial cystitis) and chronic inflammatory bladder disease. The U.S. Food and Drug Administration (FDA) has approved certain Dimethyl sulfoxide (DMSO) products for placement inside the bladder to treat symptoms of chronic inflammatory bladder disease. Dimethyl sulfoxide (DMSO) is sometimes placed inside bile ducts with other medications to treat bile duct stones.

Dimethyl sulfoxide (abbreviated DMSO) is a sulfur-containing organic compound; molecule formula: (CH3) 2SO; It exhibits as colorless, odorless, hygroscopic, and flammable transparent liquid at room temperature. It has both high polarities as well as a high-boiling point. It also has aprotic and water-miscible characteristics. It has low toxicity, good thermal stability, and is not miscible with paraffin. It is soluble in water, ethanol, propanol, ether, benzene and chloroform and many other kinds of organic substance and is called the "universal solvent." It is a common organic solvent that has the strongest dissolving ability. It can dissolve most organic compounds including carbohydrates, polymers, peptides, as well as many inorganic salts and gases. It can dissolve a certain amount of solute whose weight equals to 50-60% of itself (other common solvents usually only dissolve 10-20%), so it is very important in the sample management as well as high-speed screening of drugs. Under certain conditions, contact between dimethyl sulfoxide and chloride can even lead to explosive reaction.
dimethyl sulfoxide is widely used as solvents and reagents, particularly as the processing reagent and spinning solvent at the reaction of acrylonitrile polymerization used for polyurethane synthesis and the spinning solvent. It can also be used as the synthetic solvent for polyamide, polyimide and polysulfone resin as well as the extraction solvents for aromatic hydrocarbon and butadiene extraction solvents and solvents for synthesizing chlorofluoroaniline. 

Uses
1. It can be used for the extraction of arene, also as the reaction medium used for resins and dyes, and applied to acrylic polymerization and spinning solvent.
2. It can be used as an organic solvent, reaction medium and the intermediates of organic synthesis. It is highly versatile. This product has a highly selective extraction capacity and can be used as the polymerization and condensation solvent of acrylic resin and polysulfone resin, as the polymerization and spinning solvent of polyacrylonitrile and cellulose acetate, as the extraction solvent for separating alkanes and arenes, and as the reaction medium for the arenes, butadiene extraction, acrylic fiber, plastic solvents, organic and synthetic dyes, and pharmaceuticals industries. In the field of medicine, dimethyl sulfoxide has anti-inflammatory and analgesic effects with a strong capability of penetration through the skin, and thus being able to dissolve certain drugs and boost their penetration into the human body to achieve therapeutic purposes. Taking this carrier property of dimethyl sulfoxide can make it be used as pesticide additives. Adding a small amount of dimethyl sulfoxide in some pesticides can facilitate the penetration of pesticides into the plant in order to improve the efficacy. dimethyl sulfoxide can also be used as the dye solvent, dye removing agent, and dye carrier for the synthetic fibers. It can also be used as the absorbent of recycling acetylene and sulfur dioxide and also the modifiers of synthetic fiber, antifreeze agent and the capacitor dielectric, brake oil, and extractant of the rare metals.
3. It can be used as analytic solvents and fixing agent of gas chromatography as well as the solvent for analyzing UV spectra.

Production method
Dimethyl sulfoxide is generally made by using the dimethyl sulfide oxidation method. They have different production processes due to the different oxidants and oxidation types. 
1. Methanol carbon disulfide method; take carbon disulfide and methanol as raw materials and use γ-Al2O3 as the catalyst; first synthesize the dimethyl sulfide, then have oxidation reaction with nitrogen dioxide (or nitrate) to obtain dimethyl sulfoxide. 
2. The hydrogen peroxide method: take acetone as the buffer medium to have dimethyl sulfide be reacted with hydrogen peroxide. This method of dimethyl sulfo

DIMETHYLAMINO METHYLPROPANOL, N° CAS : 7005-47-2, Nom INCI : DIMETHYLAMINO METHYLPROPANOL, Nom chimique : 2-(Dimethylamino)-2-methylpropan-1-ol, N° EINECS/ELINCS : 230-279-6, Ses fonctions (INCI). Anticorrosif : Empêche la corrosion de l'emballage

DIMETHYLAMINOETHANOL TARTRATE, N° CAS : 29870-28-8; 5988-51-2, Nom INCI : DIMETHYLAMINOETHANOL TARTRATE. Nom chimique : Ethanol, 2-(dimethylamino)-, (2R,3R)-2,3-dihydroxybutanedioate . Ses fonctions (INCI) : Emollient : Adoucit et assouplit la peau. Agent d'entretien de la peau : Maintient la peau en bon état

EC / List no.: 203-542-8
CAS no.: 108-01-0
Mol. formula: C4H11NO
Molar mass: 89.14 g·mol−1

Dimethylaminoethanol = Dimethylethanolamine = DMAE = DMEEA = N,N-DIMETHYLAMINOETHANOL = 2-DIMETHYLAMINOETHANOL = DMEOA
Chemical synonyms: N,N-Dimethylethanolamine; Dimethylethanolamine; Deanol; DMEA; N,N-Dimethyl-2-Hydroxyethylamine; N,N-Dimethyl-N-ethanolamine


2-DIMETHYLAMINO-ETHANOL
2-dimethylaminoethanol
2-DIMETHYLAMINOETHANOL
2-dimethylaminoethanol
2-dimethylaminoethanol
N,N-dimethylethanolamine
Deanol
dimethylaminoethanol
DMEA
DMAE
2-(Dimethylamino)ethanol


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Main Applications: flocculating agent, ion-exchange resin, urethane catalyst


Dimethylaminoethanol is a clear to pale-yellow liquid used as a curing agent for polyurethanes and epoxy resins, in water treatment, and in the synthesis of various products.
Dimethylethanolamine (DMAE or DMEA) is an organic compound with the formula (CH3)2NCH2CH2OH. It is bifunctional, containing both a tertiary amine and primary alcohol functional groups. It is a colorless viscous liquid. It is used in skin care products for improving skin tone and also taken orally as a nootropic. It is prepared by the ethoxylation of dimethylamine.

Dimethylaminoethanol, also known as dimethylethanolamine (DMAE and DMEA respectively), is a primary alcohol.
This compound also goes by the names of N,N-dimethyl-2-aminoethanol, beta-dimethylaminoethyl alcohol, beta-hydroxyethyldimethylamine and Deanol.
Dimethylaminoethanol is a transparent, pale-yellow liquid.

Dimethylaminoethanol is used as a curing agent for polyurethanes and epoxy resins; used as a chemical intermediate for pharmaceuticals, dyes, corrosion inhibitors, and emulsifiers; also used as an additive to boiler water, paint removers, and amino resins; [HSDB] Has been used therapeutically as a CNS stimulant; [Merck Index # 2843]
Dimethylethanolamine, also known as Dimethylaminoethanol (DMEA and DMAE respectively), is an organic compound which is industrially produced by the reaction of ethylene oxide with dimethylamine.
Dimethylaminoethanol contains both an amine group and a hydroxyl group, and can therefore react as as an amine or an alcohol. It is a transparent, pale-yellow liquid

Dimethylaminoethanol is used as a catalyst, corrosion inhibitor, additive to paint removers/boiler, water/amino resins and it is used in cosmetic and biomedical products.


N,N-dimethylethanolamine is a tertiary amine that is ethanolamine having two N-methyl substituents.
N,N-dimethylethanolamine has a role as a curing agent and a radical scavenger.
N,N-dimethylethanolamine is a tertiary amine and a member of ethanolamines.

Dimethylethanolamine (DMEA) is an amino alcohol, organic compound. It is obtained in industry by synthesis of ethylene oxide and dimethylamine.

Dimethylethanolamine is a transparent, slightly yellow liquid. It is miscible with water, acetone, ether, and benzene.

Dimethylethanolamine is used as a curing agent for epoxy resins and polyurethanes.
It is also used in the intermediate synthesis of dyestuffs, textiles, pharmaceuticals, and corrosion inhibitors. Another application is an emulsifier in paints and coatings.



The main areas for dimethylethanolamine application are: the production of initial monomers for water treatment, as a catalyst for polyurethane foam and ion exchange resins. In addition, DMEA is used in the chemical, paint and varnish, pharmaceutical and textile industries.



USES of Dimethylaminoethanol:
Dimethylaminoethanol (DMAE) is commonly used substance in the formulation of cosmetics related to skin care application.
Its chemical formula is (CH3)2NCH2CH2OH.
Dimethylaminoethanol is prepared by the ethoxylation of dimethylamine.
Rising population and urbanization has boosted the demand for cosmetics products, thus driving the dimethylaminoethanol (DMAE) market.
Dimethylethanolamine is a precursor to other chemicals, such as the nitrogen mustard 2-dimethylaminoethyl chloride.
It ranges from colorless to slightly yellow liquid with an amine-like odor.
Dimethylaminoethanol (DMEA) is extensively utilized in the water treatment industry.
Dimethylaminoethanol is also used as a polyurethane catalyst in coatings applications and as an intermediate in textile chemicals, ion exchange resins, and emulsifying agents.
DMEA is also employed in the pharmaceutical industry as a supplement form to boost brain health by raising acetylcholine levels.




INDUSTRIAL USES of Dimethylaminoethanol :
Dimethylaminoethanol is used as a curing agent for polyurethanes and epoxy resins.
Dimethylaminoethanol is also used in mass quantities for water treatment, and to some extent in the coatings industry.
Dimethylaminoethanol is used in the synthesis of dyestuffs, textile auxiliaries, pharmaceuticals, emulsifiers, and corrosion inhibitors.
Dimethylaminoethanol is also an additive to paint removers, boiler water and amino resins.
Dimethylaminoethanol forms a number of salts with melting points below room temperature (ionic liquids) such as N,N-dimethylethanolammonium acetate and N,N-dimethylethanolammonium octanoate, which have been used as alternatives to conventional solvents.



Dimethylaminoethanol in Water Treatment Industry:
Dimethylaminoethanol is a neutralizing amine.
Dimethylaminoethanol (DMAE) effectively neutralizes the condensate without resulting in appreciable deposit formation.
Organic amines are corrosion control agents that increase pH and scavenge corrosive contaminants.
Dimethylethanolamine (DMEA), for example, is a common corrosion inhibitor that eliminates dissolved CO2 and helps control pH in industrial boilers and nuclear power plants.
Amines are also effective as hydrogen sulfide scavengers in oil and gas production and processing.
On-site monitoring for amines can help maintain appropriate corrosion protection, extending system lifetime and avoiding costly corrosion-induced shutdowns and failures.


N,N-dimethylethanolamine has role curing agent
N,N-dimethylethanolamine has role radical scavenger
N,N-dimethylethanolamine is a ethanolamines
N,N-dimethylethanolamine is a tertiary amine


2-Dimethylaminoethyl chloride hydrochloride is an intermediate made from dimethylaminoethanol that is widely used for the manufacture of pharmaceuticals.

Flocculants: DMAE is a key intermediate in the production of dimethylaminoethyl-(meth)acrylate. The water-soluble polymers produced from this ester, mostly by copolymerisation with acrylamide, are useful as flocculents.
Pulp and paper chemicals: The dry strength or wet strength of paper is increased by adding a homopolymer of dimethylaminoethyl(meth)acrylate to the unbleached kraft paper.
Ion exchange resins: Anion exchange resins can be prepared by reacting tertiary amines like DMAE or trimethylamine with the chloromethylated vinyl or styrene resin.
Increased exchange capacity is obtained by reacting a cross-linked polymer, containing haloalkyl functions, with an amine.
The anion exchange membranes are aminated with DMAE.

Polyurethane: In the production of PU foam for insulating purposes, the use of DMAE is a practical and effective way of reducing the total formula cost.



Resins

Epoxy
DMAE is an effective and versatile curing agent for epoxy resins. It also acts as viscosity reducing agent for resinous polyamides and other viscous hardeners.
DMAE is also an extremely good wetting agent for various filters in epoxy formulations.
DMAE, also known as dimethylethanolamine (DMEA), is a curing agent for epoxy resins.

2-Dimethylaminoethanol is miscible with water, alcohols, ether, and aromatic solvents. It undergoes reactions typical of amines and alcohols. It is used in the preparation of waterborne (WB) coatings formulations.
Acrylic
DMAE improves the acid-dyeing properties of acrylonitrile polymers by copolymerisation of DMAE esters.



Water-soluble DMAE salts are used to improve the behaviour of coatings and films to make them water-resistant or provide specific desired sensitivity to water.
Textiles – leather: The acid-dyeing capability of polyacrylonitrile is improved by copolymerisation of the acrylonitrile with DMAE esters, such as dimethylaminoethyl acrylate.
Cellulose modified with the homopolymer of dimethylaminoethyl methacrylate can be dyed with ester salts of a leuco vat dye.
The impregnation of cellulose with polydimethylaminoethyl methacrylate also improves the gas-fading resistance of the fabric.
Long-chain alkylphosphates of DMAE form anti-static agents for non-cellulosic hydrophobic textile materials.

Paints, coatings and inks: DMAE is excellent for neutralising free acidity in water-soluble coating resins. The resin can be acrylic, alkyd or styrene-maleic. DMAE is often preferred to triethylamine when lower volatility is required, as in electrodeposition. It also improves pigment wettability.
Some synthetic enamels with a metallic appearance can be prepared from dimethylaminoethyl methacrylate polymers.
In flexographic inks DMAE can be used to solubilize resins and inoxes.
The adhesion of latex coatings can be improved by copolymerisation of the acrylic monomers with dimethylaminoethyl acrylate.

Surfactants – detergents: Alkylethanolamine salts of anionic surfactants are generally much more soluble than the corresponding sodium salts, both in water and oil systems. DMAE can be an excellent starting material in the production of shampoos from fatty acids. The fatty acid soaps are especially effective as wax emulsifiers for water-resistant floor polishes.
DMAE titanates, zirconates and other group IV-A metal esters are useful as dispersing agents for polymers, hydrocarbons and waxes in aqueous or organic solvent systems.

Applications/uses
Paints & coatings




Dimethylaminoethanol (DMAE): Application Segment
In terms of application, the global dimethylaminoethanol (DMAE) market can be segmented into cleansing agent, antibacterial agent, flocculating agent, urethane catalyst, ion-exchange resin, emulsifying agent, and others
The cleansing agent segment is expected to account for a significant share of the global dimethylaminoethanol (DMAE) market.
It is anticipated to be followed by the flocculating agent segment.
The ion-exchange resin segment is likely to expand at a rapid pace, due to the expansion of polymer industry around the globe

Dimethylaminoethanol (DMAE): End-use Segment
In terms of end-use, the global dimethylaminoethanol (DMAE) market can be segmented into pharmaceutical, chemical, cosmetics, and others
The cosmetics segment is estimated to expand at a rapid pace.
It is projected to be followed by the pharmaceutical industry segment.


Dimethylaminoethanol (DMAE)
DMAE is a novel ingredient initially used in the treatment of hyperkinetic disorders and to improve memory.
It is now being used in cosmeceutical products, gaining popularity from its activity as a precursor to acetylcholine.
Initially utilized as a firming and anti-aging product, new functions, including anti-inflammatory and antioxidant activities, have now been elucidated.
In vitro, DMAE inhibits IL-2 and IL-6 secretion in addition to its actions as a free radical scavenger.
Although the exact mechanism of action of DMAE is unclear, its acetylcholine-like functions increase contractility and cell adhesion in the epidermis and dermis, resulting in the appearance of firmer skin.




PHARMA USE OF DIMETHYLAMINOETHANOL:
DMAE is also known as Dimethylethanolamine, 2-Dimethylaminoethanol or Deanol, is an analog of the vitamin B choline (N,N,N-trimethylethanolamine) and is a precursor of acetylcholine 1).
DMAE was thought to be a precursor for acetylcholine, has been tested for its efficacy in treating a variety of diseases possibly related to deficiencies of acetylcholine, including tardive dyskinesia, Alzheimer’s disease, amnesic disorders, age-related cognitive impairment, attention deficit-hyperactivity disorder (ADHD), Tourette’s syndrome, autism and tardive dyskinesia with mixed results.
Three reported no benefit from DMAE treatment (tardive dyskinesia; cognitive dysfunction; Alzheimer’s disease).
Treatment with DMAE for tardive dyskinesia, a side effect of neuroleptic medications, was associated with serious cholinergic side effects: nasal and oral secretions, dyspnea, and respiratory failure 3).
DMAE was used in the treatment of one patient for a low-frequency action tremor.
This treatment was successful for ten years, until side effects of increasing neck pain and orofacial and respiratory dyskinesia occurred.
Treatment was discontinued, and it was concluded that the dyskinesia could be attributed to the effects of DMAE.
A meta-analysis of randomized controlled trials indicated that DMAE was no more effective than placebo in the treatment of tardive dyskinesia.
Rather, there was a significantly increased risk of adverse events associated with the DMAE treatment.
Benefits from DMAE treatment were found in other studies evaluating DMAE’s ability to increase theta power or concentration.
DMAE has been also used as an ingredient in skin care, and in cognitive function- and mood-enhancing products.
Riker Laboratories’ prescription drug Deaner (Deanol p-acetamidobenzoate) was a U.S. prescription drug for more than 20 years until 1983 when it was withdrawn from the market.
Deaner (deanol p-acetamidobenzoate) was used to treat children with learning and behavior problems.
However, evidence of efficacy was insufficient (Natural Medicines Comprehensive Database, 2002).

In 1959, an Italian article described the use of Deaner in 50 children.
The brief review by CVS Pharmacy (undated) listed the indications for use of Deaner while it was FDA-approved as possibly effective.
The Merck Index, 13th edition, deanol monograph states that Riker’s preparation was patented in 1957.
Remington’s Practice of Pharmacy, 1961 edition 7) listed Deaner as an unofficial (i.e., not listed in the U.S. Pharmacopoeia or the National Formulary) psychomotor stimulant.
Doses of up to 900 mg/day had not been associated with any serious side effects. Oral doses for children with behavior problems were 75 mg/day to start with 75- to 150-mg/day maintenance doses.
Twenty-five years ago, the suggested average daily dose of deanol for adults with Huntington’s chorea was 1.0 to 1.5 g (3.7 to 5.6 mmol) 8).
The anti-inflammatory, analgesic composition Diclofenac-deanol is apparently available in dosages of 75 mg diclofenac and 15 mg deanol (Gerot Pharmazeutica, undated).

DMAE is hypothesized to increase the production of acetylcholine (a chemical that helps nerve cells transmit signals).
Since acetylcholine plays a key role in many brain functions, such as learning and memory, proponents claim that taking DMAE in supplement form may boost brain health by raising acetylcholine levels.1


Recently, a number of synthetic drugs used in a variety of therapeutic indications have been reported to have antiaging effects.
Among them, Dimethylaminoethanol (DMAE), an anologue of dietylaminoethanol, is a precursor of choline, which in turn allows the brain to optimize the production of acetylcholine that is a primary neurotransmitter involved in learning and memory.


Biochemical significance
Dimethylaminoethanol is related to choline and may be a biochemical precursor to the neurotransmitter acetylcholine, although this conclusion has been disputed based on a 1977 rat experiment.
It is commonly believed that dimethylaminoethanol is methylated to produce choline in the brain, but this has been shown not to be the case (in a rat experiment).
It is known that dimethylaminoethanol is processed by the liver into choline; however, in a rat experiment the choline molecule is charged and cannot pass the blood–brain barrier.
In the brain, DMAE is instead bound to phospholipids in place of choline to produce phosphatidyl-dimethylaminoethanol.
This is then incorporated into nerve membranes, increasing fluidity and permeability, and acting as an antioxidant.


Biomedical research
Short-term studies have shown an increase in vigilance and alertness with a positive influence on mood following administration of DMAE, vitamins, and minerals in individuals suffering from borderline emotional disturbance.
Research for ADHD has been promising, though inconclusive.
A study showed dimethylaminoethanol to decrease the average life span of aged quail.
Three other studies showed an increase in lifespan of mice

The bitartrate salt of DMAE, i.e. 2-dimethylaminoethanol (+)-bitartrate, is sold as a dietary supplement.
It is a white powder providing 37% DMAE.

The dimethylaminoethanol (DMAE) market has been expanding significantly for the last few years. This can be primarily ascribed to a rise in the demand for ion exchange resins, emulsifying agents, and flocculating agent in end-use industries. DMAE acts as a good ingredient and plays an important role in addressing several issues associated with the cleansing and antibacterial properties in the cosmetic industry; hence, it is widely used in skin care products. Demand for urethane catalyst has been rising consistently for the last few years, which in turn is anticipated to boost the demand for DMAE.
Rise in demand for polyurethane is expected to create significant opportunities for urethane catalyst industries. Dimethylaminoethanol (DMAE) is an effective, economical amine catalyst for flexible and rigid polyurethane foams. Increase in demand for DMAE as a catalyst in the production of polyurethane foam is expected to create lucrative opportunities for the dimethylaminoethanol (DMAE) market



Translated names
2-(dimethylamino)ethan-1-ol (cs)
2-(dimetylamino)etanol (sk)
2-(dimetyloamino)etanol (pl)
2-dimethylaminoethanol (da)
2-Dimethylaminoethanol (de)
2-dimethylaminoethanol (nl)
2-dimetil-aminoetanol (hr)
2-dimetilaminoetanol (es)
2-dimetilaminoetanol (hu)
2-dimetilaminoetanol (pt)
2-dimetilaminoetanol (ro)
2-dimetilaminoetanol (sl)
2-dimetilaminoetanolis (lt)
2-dimetilaminoetanolo (it)
2-dimetilaminoetanols (lv)
2-dimetylaminoetanol (no)
2-dimetylaminoetanol (sv)
2-dimetyyliaminoetanoli (fi)
2-dimetüülaminoetanool (et)
2-diméthylaminoéthanol N,N-diméthyléthanolamine (fr)
2-διμεθυλαμινοαιθανόλ (el)
2-диметиламиноетанол (bg)
N,N-dimetil-etanolamin (hr)
N,N-dimethylethanolamin (cs)
N,N-Dimethylethanolamin (de)
N,N-dimetiletanolamin (hu)
N,N-dimetiletanolamin (sl)
N,N-dimetiletanolamina (ro)
N,N-dimetiletanolaminas (lt)
N,N-dimetiletanolamīns (lv)
N,N-dimetyletanolamín (sk)
N,N-dimetyloetanoloamina (pl)
N,N-dimetüületanoolamiin (et)
N,N-диметилетаноламин (bg)

CAS names
Ethanol, 2-(dimethylamino)-



IUPAC names
2- Dimethylaminoethanol
2-(Dimethylamino) ethanol
2-(dimethylamino)-ethanol
2-(dimethylamino)ethan-1-ol
2-(Dimethylamino)ethanol
2-(dimethylamino)ethanol
2-(dimethylamino)ethanol
2-Dimethylaminoethanol
2-dimethylaminoethanol
2-Dimethylaminoethanol
2-dimethylaminoethanol
2-dimethylaminoethanol, DMAE
2-dimethylaminoethanol;
2-dimethylaminoethanol; N,N-dimethylethanolamine
Dimethylaminoethanol
DIMETHYLAMINOETHANOL
Dimethylaminoethanol
Dimethylethanolamine
DMAE
DMAE - CM0564B
N,N-Dimethylethanolamine
N,N-dimethylethanolamine


Trade names
(2-Hydroxyethyl)dimethylamine
(Dimethylamino)ethanol
(N,N-Dimethylamino)ethanol
.beta.-(Dimethylamino)ethanol
.beta.-Dimethylaminoethyl alcohol
.beta.-Hydroxyethyldimethylamine
2-(Dimethylamino)-1-ethanol
2-(Dimethylamino)ethanol
2-(N,N-Dimethylamino)ethanol
2-Dimethylaminoethanol (DMAE)
Amietol M 21
Amietol M21
Bimanol
Deanol
Dimethol
Dimethyl(2-hydroxyethyl)amine
Dimethyl(hydroxyethyl)amine
Dimethylethanolamin
Dimethylethanolamine
Dimethylmonoethanolamine
DMAE
DMEA
Ethanol, 2-(dimethylamino)- (8CI, 9CI)
Kalpur P
Liparon
N,N-Dimethyl(2-hydroxyethyl)amine
N,N-Dimethyl-.beta.-hydroxyethylamine
N,N-Dimethyl-2-aminoethanol
N,N-Dimethyl-N-(.beta.-hydroxyethyl)amine
N,N-Dimethyl-N-(2-hydroxyethyl)amine
N,N-Dimethylethanolamine
N-(2-Hydroxyethyl)dimethylamine
Norcholine
Propamine A
Texacat DME



AMIETOL M 21
B-DIMETHYLAMINOETHYL ALCOHOL
BETA-(DIMETHYLAMINO)ETHANOL
BETA-DIMETHYLAMINOETHANOL
BETA-DIMETHYLAMINOETHYL ALCOHOL
BETA-HYDROXYETHYLDIMETHYLAMINE
BIMANOL
DEANOL
DIMETHOL
DIMETHYL(2-HYDROXYETHYL)AMINE
DIMETHYL(HYDROXYETHYL)AMINE
(DIMETHYLAMINO)ETHANOL
2-(DIMETHYLAMINO)ETHANOL
2-(DIMETHYLAMINO)ETHYL ALCOHOL
DIMETHYLAMINOETHANOL
DIMETHYLAMINOETHANOL, [CORROSIVE LIQUID]
2-DIMETHYLAMINOETHANOL
DIMETHYLETHANOLAMINE
DIMETHYLMONOETHANOLAMINE
DMAE
(2-HYDROXYETHYL)DIMETHYLAMINE
KALPUR P
LIPARON
N,N-DIMETHYL(2-HYDROXYETHYL)AMINE
N,N-DIMETHYL-2-AMINOETHANOL
N,N-DIMETHYL-2-HYDROXYETHYLAMINE
N,N-DIMETHYL-BETA-HYDROXYETHYLAMINE
N,N-DIMETHYL-N-(2-HYDROXYETHYL)AMINE
N,N-DIMETHYL-N-(BETA-HYDROXYETHYL)AMINE
(N,N-DIMETHYLAMINO)ETHANOL
2-(N,N-DIMETHYLAMINO)ETHANOL
N,N-DIMETHYLAMINOETHANOL
N,N-DIMETHYLETHANOLAMINE
N-(2-HYDROXYETHYL)DIMETHYLAMINE
N-DIMETHYLAMINOETHANOL
NORCHOLINE
PROPAMINE A
REXOLIN
TEXACAT DME
THANCAT DME


Global Dimethylaminoethanol (DMAE) Market, by Application

Cleansing Agent
Antibacterial Agent
Flocculating Agent
Emulsifying Agent
Ion-Exchange Resin
Epoxy Resin Hardener Ingredient



Global Dimethylaminoethanol (DMAE) Market, by End-use

Pharmaceutical
Chemical
Cosmetics
Construction


According to the Organization for Economic Co-operation and Development Screening Information Data Set estimates, 50% of the DMAE produced is used to make flocculants for wastewater treatment, 20% is used in the manufacture of flexible and rigid polyurethane foams and polyurethane lacquers, 20% is used in the manufacture of water-based paints and surface coatings, and the remaining 10% is used for ion exchange resins, pharmaceuticals, and corrosion inhibitor formulations.
DMAE is used for solubilization of water-insoluble resin components for water-based coatings, a process achieved by reaction of DMAE with the resins.
A 2001 article states that DMAE hemisuccinate is used with other chemicals to analyze blood for cholesterol and dehydrocholesterol

DMAE is released into water as a result of its use in the production of polyurethane, acrylates, ion exchange resins and flocculants, and pharmaceuticals.
Based on European estimates, approximately 75% of total DMAE is used in the production of polyurethane, acrylates, ion exchange resins and flocculants, and pharmaceuticals.
While DMAE is cross-linked in the production of polyurethane, resulting in minimal releases to water, up to 50% of the DMAE used in the preparation of ion exchange resins or flocculants may be released to water.
DMAE is also released into the environment as a component of corrosion inhibitor formulations, paints, and surface coatings.
Sealants, architectural coatings, coatings on furniture and cabinets, polyurethane foam cushions, and carpets may emit DMAE in homes, commercial buildings, and vehicles



Industrial uses
Coatings Dimethylaminoethanol is used for solubilization of water-insoluble resin components for water-based coatings (ATOFINA Chemicals, Inc., 2000), a process achieved by reaction of Dimethylaminoethanol with the resins (Huntsman Corp., 1997).
Water-based Dimethylaminoethanol coatings are used on aluminum cans (Dow, 2001a).
In an extensive survey of architectural coatings by the California Air Resources Board (CARB, 1999), Dimethylaminoethanol was ranked 77th by weight in a list of 88 ingredients commonly found in waterborne coatings.
It ranked 165th by weight among 186 ingredients used in waterborne or organic-solvent-based coatings.
A recent French study of about 30 water-based paint formulations available to vehiclemanufacturers all contained glycol ethers, N-methylpyrrolidone, [N-methylpyrrolidinone], andalkanolamines (Dimethylaminoethanol was mentioned as an example) (Jargot et al., 1999).
Dimethylaminoethanol hemisuccinate is named in a patent for organic polymers made from isocyanates to makecathodic electrocoating [Desoto, Inc., U.S.A.] (Lin, 1982), and Dimethylaminoethanol bitartrate was part of anaqueous cathodic coating composition to which maleic acid was added to reduce discoloration bymetal ions [PPG Industries, Inc., U.S.A.] (Lucas, 1983).
Dimethylaminoethanol is used to produce methacrylatemonomers for polymers as antistatic agents, electrically conducting materials (Huntsman Corp.,1997).


Emulsifying and dispersing agents
Dimethylaminoethanol is used as an amino resin stabilizer and as an intermediate in the synthesis of dyes,textiles, and auxiliaries (HSDB, 1996).
Dimethylaminoethanol fatty acid soaps are used as emulsifying and dispersing agents for waxes and polishes resistant to water that are used on metal, leather, glass, wood, ceramic ware, floors, furniture, and automobiles, and Dimethylaminoethanol esters are common emulsifying agents in the textile industry (Dow, 2001a).
Dimethylaminoethanol hydrochloride is used in manufacturing Procter & Gamble detergent compositions (Kandasamy et al., 2000).
Dimethylaminoethanol hemisuccinate has been used to make amphoteric surfactants (Nieh and Naylor, 1984).

Gas treating
Alkyl alkanolamines are used to eliminate hydrogen sulfide from natural gas and refinery off­gasses (Dow, 2001a). Two out of 73 titles resulting from a CAPLUS search linking Dimethylaminoethanol to environmental pollution indicated that Dimethylaminoethanol is used to remove hydrogen sulfide from gas mixtures.

Urethane catalysts
Dimethylaminoethanol is one of at least 60 amine compounds used as catalysts in the manufacture of polyurethane and polyisocyanurate foams.
Polyurethane formulations require about 0.1 to 5.0% amine catalyst (API, 2000).
Dimethylaminoethanol reacts with isocyanates, limiting the amount of Dimethylaminoethanol emissions during the foaming reaction (Dow, 2001a).
One study evaluated amine catalyst use in polyurethane production in the United Kingdom.
At afactory making polyether slabstock, the “typical total throughput” of chemicals was 300 kg perminute: 200 kg polyol per minute, 100 kg per minute 80:20 diisocyanates, and 0.6 kg/minuteamine.
At a typical factory for making polyester slabstock, with a throughput of 300 kg perminute, 0.5 to 1.5 kg per minute would be used.
At a typical factory for making a molding, theestimated throughput was 12 kg per minute and the rate of amine use was 0.02 kg per minute(Bugler et al., 1992).
Dimethylaminoethanol in vapor phase is also used to catalyze polyurethane-based inks(Huntsman Corp., 1997) to catalyze coatings (U.S. EPA ORD, 1994), and for curing epoxyresins (HSDB, 1996). API (2000) lists 55 other amine catalysts used in polyurethane manufacture.
The di-Dimethylaminoethanolether, that is, bis(2-dimethylaminoethyl) ether [CAS RN 3033-62-3] may be the most widelyused amine catalyst in polyurethane manufacture.

Water treatment
Dimethylaminoethanol is used to make flocculants for wastewater treatment (Dow, 2001a; Huntsman Corp.,1997), to inhibit corrosion in return-condensate boiler and steam systems by controlling pH (Dow, 2001a; HSDB, 1996), and to synthesize Type II resins for anion exchange (Dow, 2001a).

Other industrial uses
Other uses of Dimethylaminoethanol include as a chemical intermediate (HSDB, 1996), as a corrosion inhibitorin steel-reinforced concrete (CCIA, undated; FHWA DOT, 2000), and as “paper auxiliaries”(Huntsman Corp., 1997).


N,N-Dimethylethanolamine S
N,N-Dimethylethanolamine S (DMEOA, DMAE) belongs to the class of N-alkylated aminoalcohols.
DMEOA is a colorless to slightly yellow liquid with a amine-like odor.

Coatings

DMEOA is used as an intermediate + buffering agent in the synthesis of coatings.

Other

DMEOA is used as a building block for the synthesis of cationic flocculants and ion exchange resins.


Dimethylaminoethanol toxicology
Dimethylaminoethanol is absorbed and rapidly transported to the liver where much of it is metabolized 33).
Approximately 280 nmol (25.2 μg) Dimethylaminoethanol/gram plasma was observed in male mice about ten minutes after receiving 300 mg (3.30 mmol) Dimethylaminoethanol/kg, intraperitoneally. Approximately 2.41, 1.30, and 0.20% of an administered dose of 30 mg/kg (0.13 mmol/kg) (with 100 μCi) of 14C­cyprodenate was found in the liver, brain, and plasma, respectively, five minutes after intravenous dosing in male rats. After transport to the liver, a portion of centrophenoxine was converted to its constituent moieties, Dimethylaminoethanol and p-chlorophenoxyacetic acid, while the unmetabolized form was transported throughout the body by the circulatory system.

Daily Dimethylaminoethanol oral exposures of chinchilla rabbits or humans produced measurable plasma and cerebrospinal concentrations of the parent compound.
The drugs were cleared from the plasma by 36 hours post-treatment.
In male Wistar rats, Dimethylaminoethanol was oxidized rapidly to the N-oxide of Dimethylaminoethanol, representing the primary urinary metabolite.
However, only 13.5 % of the administered dose was eliminated by the 24 hour time point, suggesting that most of the Dimethylaminoethanol was routed toward phospholipid biosynthetic pathways.
In humans, 33% of an injected 1 g (10 mmol) dose of Dimethylaminoethanol was excreted unchanged.
It was suggested that the remaining dose might have been demethylated to ethanolamine directed toward normal metabolic pathways.
It is unclear to what extent Dimethylaminoethanol is methylated and substituted into acetylcholine.
Some reports indicated that the Dimethylaminoethanol that crossed the blood-brain barrier was methylated to form choline and then incorporated into acetylcholine.
Other investigators found that neither acute (in vitro) nor chronic (in vivo) treatments with [2H6] Dimethylaminoethanol had the capacity to alter levels of acetylcholine in the brain tissues.
Choline may be formed by methylation of Dimethylaminoethanol. De novo synthesis of choline typically involves conversion of phosphatidylethanolamine to phosphatidylcholine.
lthough small amounts may be synthesized, choline must be supplemented through the diet to maintain adequate physiological concentrations for optimal health.
Most of the body’s choline is found as a component of phospholipids.
Choline-containing phospholipids, especially phosphatidylcholine and sphingomyelin, are structural components of cell membranes and precursors for intracellular messenger molecules.
Phosphatidylcholine is a required component of very low-density lipoprotein (VLDL) particles, necessary for the transportation of cholestero

DMAPA; DMPDA; NSC 1067; U-CAT 2000; -Dimethylamino; FENTAMINE DMAPA; amino)-1-propyL; H2N(CH2)3N(CH3)2; RARECHEM AL BW 0072; imethylaminopropylamine; 1-(Dimethylamino)-3-aminopropane; 1,3-propanediamine,N,N-dimethyl-; 1-dimethylamino-3-aminopropane; 3-(Dimethylamino)-1-propanamine; 3-(n,n-dimethylamino)-propylamin; 3-Amino-1-(dimethylamino)propane; 3-Propanediamine,N,N-dimethyl-1; -Dimethylamino CAS NO:109-55-7

DIMETHYLOL GLYCOL, N° CAS : 3586-55-8, Nom INCI : DIMETHYLOL GLYCOL, Nom chimique : (ethylenedioxy)dimethanol, N° EINECS/ELINCS : 222-720-6, Classification : Glycol, Ses fonctions (INCI). Antimicrobien : Aide à ralentir la croissance de micro-organismes sur la peau et s'oppose au développement des microbes

DIMETHYLOL UREA, N° CAS : 140-95-4, Nom INCI : DIMETHYLOL UREA, Nom chimique : 1,3-bis(hydroxymethyl)urea, N° EINECS/ELINCS : 205-444-0. Ses fonctions (INCI): Antimicrobien : Aide à ralentir la croissance de micro-organismes sur la peau et s'oppose au développement des microbes

DIMETHYLTOLYLAMINE, N° CAS : 99-97-8. Nom INCI : DIMETHYLTOLYLAMINE. Nom chimique : N,N-Dimethyl-p-Tolylamine; N,N-dimethyl-p-toluidine; Dimethyl-4-toluidine; N,N-Dimethyl-4-methylaniline. N° EINECS/ELINCS : 202-805-4. Ses fonctions (INCI): Agent d'entretien des ongles : Améliore les caractéristiques esthétiques des ongles

CAS number: 9006-65-9
Chemical formula: CH3)3-Si-[O-Si(CH3)2]n-O-Si(CH3)3
Molecular weight: 6,800 to 30,000 (average and approximate)
E number: E900

Dimethylpolysiloxane, also known as polydimethylsiloxane (PDMS), is a form of silicone used as an antifoaming agent in food with the European food additive number E900.
Dimethylpolysiloxane is commonly used in frying oil due to its good defoaming effectiveness at high temperatures.

Dimethylpolysiloxane (PDMS), also known as dimethylpolysiloxane or dimethicone, belongs to a group of polymeric organosilicon compounds that are commonly referred to as silicones.
Dimethylpolysiloxane is the most widely used silicon-based organic polymer, as its versatility and properties lead to many applications.

Dimethylpolysiloxane is particularly known for its unusual rheological (or flow) properties.
Dimethylpolysiloxane is optically clear and, in general, inert, non-toxic, and non-flammable.
Dimethylpolysiloxane is one of several types of silicone oil (polymerized siloxane).
Dimethylpolysiloxane's applications range from contact lenses and medical devices to elastomers; Dimethylpolysiloxane is also present in shampoos (as it makes hair shiny and slippery), food (antifoaming agent), caulking, lubricants and heat-resistant tiles.

What is dimethylpolysiloxane?
Dimethylpolysiloxane also called E900, polymethylsiloxane or dimethicone, is a silicon-based polymer used as a lubricant and conditioning agent.
Dimethylpolysiloxane functions as an anti-foaming agent, skin conditioning agent, occlusive and skin protectant.
Dimethylpolysiloxane is found in many cosmetic and hygiene products like nail polish, conditioners, make-up, contact lens solutions, sunscreens, deodorants, and shampoo.
Examples of products that contain dimethicone include Lotion and Baby Cream.

Definition of Dimethylpolysiloxane:
Dimethylpolysiloxane is made of two parts:
(CH3)2 SiO: fully methylated linear siloxane polymers composed of repeating units of the formula (CH3)2 SiO
(CH3)3 SiO: end-blocking trimethylsiloxy (CH3)3 SiO, with the stabilization function.

What’s the Application of Dimethylpolysiloxane?
Dimethylpolysiloxane's applications are widely such as in aerospace, aviation, food, chemical, metallurgy, medical and healthcare fields as most of the silicone products (such as silicone oil, silicone rubber, silicone resin) are obtained by the reaction of polydimethylsiloxanes with regulators, cross-linking agents, capping agents, etc.
PDMS has many excellent physical and chemical properties, such as high and low-temperature resistance, radiation resistance, oxidation resistance, high air permeability, weather resistance, mold release, hydrophobicity, and physiological inertness.

Food applications of Dimethylpolysiloxane:
PDMS is commonly used as an antifoaming agent in cooking oils, processed foods, and fast food as it prevents the formation of foam on the surface of liquids by reducing the surface tension.
Usually, Dimethylpolysiloxane's applied viscosity varies from 300 to 1,050 centistokes at 25 ºC in food.

Cosmetics applications of Dimethylpolysiloxane:
Per the “European Commission database for information on cosmetic substances and ingredients”, Dimethylpolysiloxane functions as an antifoaming, emollient, skin conditioning and skin protecting agent in cosmetic and personal care products.
We can find Dimethylpolysiloxane in shampoos, conditioners and skin care products.
Dimethylpolysiloxanes common viscosity is 100 and 350 centistokes at 25 ºC.

What is Dimethylpolysiloxane Used for?
PDMS is a silicon-based organic polymer that can be used as an antifoaming agent in fruit and vegetable juices, also it is an anticaking agent in confectionery and flour products, and meanwhile an emulsifier in edible oils essentially free of water.
Dimethylpolysiloxane is a food-grade additive acts as an anti-foaming agent to protect their crew from excessive foaming, splashing or bubbling, which occurs when food is added to very hot oil.

Authorised Uses of Dimethylpolysiloxane:
The following foods may contain Dimethylpolysiloxane:
-Oils and fats for frying
-Chewing gum
-Batters
-Soups and broths
-Pineapple juice
-Flavoured drinks
-Cider and perry
-Fruit or vegetable spreads
-Decorations, coatings and fillings
-Canned or bottled fruit and vegetables
-Food supplements in effervescent tablet form
-Confectionery including breath freshening microsweets
-Jam, jellies and marmalades and sweetened chestnut purée

Also, Dimethylpolysiloxane can be used:
-as a carrier in glazing agents for fruit
-in all flavourings
-In preparations of beta-carotene and lycopene

Currently, dimethylpolysiloxane (E 900) is an authorized food additive, used as an antifoaming agent in foods:
-Fats and oils essentially free from water (excluding anhydrous milk fat)
-Other fat and oil emulsions including spreads and liquid emulsions
-Canned or bottled fruit and vegetables
-Jam, jellies and marmalades and sweetened chestnut purée.
-Other similar fruit or vegetable spreads
-Other confectionery including breath freshening microsweets
-Chewing gum
-Decorations, coatings and fillings, except fruit‐based fillings
-Batters
-Soups and broths
-Fruit juices and vegetable juices
-Flavored drinks
-Cider and perry

Structure of Dimethylpolysiloxane:
The chemical formula for Dimethylpolysiloxane is CH3[Si(CH3)2O]nSi(CH3)3, where n is the number of repeating monomer [SiO(CH3)2] units.

Branching and capping:
Hydrolysis of Si(CH3)2Cl2 generates a polymer that is terminated with silanol groups (−Si(CH3)2OH]).
These reactive centers are typically "capped" by reaction with trimethylsilyl chloride:

2 Si(CH3)3Cl + [Si(CH3)2O]n−2[Si(CH3)2OH]2 → [Si(CH3)2O]n−2[Si(CH3)2O Si(CH3)3]2 + 2 HCl
Silane precursors with more acid-forming groups and fewer methyl groups, such as methyltrichlorosilane, can be used to introduce branches or cross-links in the polymer chain.
Under ideal conditions, each molecule of such a compound becomes a branch point.
Dimethylpolysiloxane can be used to produce hard silicone resins.
In a similar manner, precursors with three methyl groups can be used to limit molecular weight, since each such molecule has only one reactive site and so forms the end of a siloxane chain.

Well-defined PDMS with a low polydispersity index and high homogeneity is produced by controlled anionic ring-opening polymerization of hexamethylcyclotrisiloxane.
Using this methodology it is possible to synthesize linear block copolymers, heteroarm star-shaped block copolymers and many other macromolecular architectures.

The polymer is manufactured in multiple viscosities, ranging from a thin pourable liquid (when n is very low), to a thick rubbery semi-solid (when n is very high).
Dimethylpolysiloxane molecules have quite flexible polymer backbones (or chains) due to their siloxane linkages, which are analogous to the ether linkages used to impart rubberiness to polyurethanes.
Such flexible chains become loosely entangled when molecular weight is high, which results in Dimethylpolysiloxane unusually high level of viscoelasticity.

Mechanical properties of Dimethylpolysiloxane:
PDMS is viscoelastic, meaning that at long flow times (or high temperatures), Dimethylpolysiloxane acts like a viscous liquid, similar to honey.
However, at short flow times (or low temperatures), Dimethylpolysiloxane acts like an elastic solid, similar to rubber.
Viscoelasticity is a form of nonlinear elasticity that is common amongst noncrystalline polymers.
The loading and unloading of a stress-strain curve for Dimethylpolysiloxane do not coincide; rather, the amount of stress will vary based on the degree of strain, and the general rule is that increasing strain will result in greater stiffness.

When the load itself is removed, the strain is slowly recovered (rather than instantaneously).
This time-dependent elastic deformation results from the long-chains of the polymer.
But the process that is described above is only relevant when cross-linking is present; when it is not, the polymer PDMS cannot shift back to the original state even when the load is removed, resulting in a permanent deformation.
However, permanent deformation is rarely seen in PDMS, since Dimethylpolysiloxane is almost always cured with a cross-linking agent.

If some PDMS is left on a surface overnight (long flow time), it will flow to cover the surface and mold to any surface imperfections.
However, if the same PDMS is poured into a spherical mold and allowed to cure (short flow time), it will bounce like a rubber ball.
The mechanical properties of PDMS enable this polymer to conform to a diverse variety of surfaces.
Since these properties are affected by a variety of factors, this unique polymer is relatively easy to tune.

This enables Dimethylpolysiloxane to become a good substrate that can easily be integrated into a variety of microfluidic and microelectromechanical systems.
Specifically, the determination of mechanical properties can be decided before PDMS is cured; the uncured version allows the user to capitalize on myriad opportunities for achieving a desirable elastomer.
Generally, the cross-linked cured version of Dimethylpolysiloxane resembles rubber in a solidified form.
Dimethylpolysiloxane is widely known to be easily stretched, bent, compressed in all directions.
Depending on the application and field, the user is able to tune the properties based on what is demanded.

Dimethylpolysiloxane has a low elastic modulus which enables it to be easily deformed and results in the behavior of a rubber.
Viscoelastic properties of Dimethylpolysiloxane can be more precisely measured using dynamic mechanical analysis.
This method requires determination of the material's flow characteristics over a wide range of temperatures, flow rates, and deformations.
Because of Dimethylpolysiloxane's chemical stability, it is often used as a calibration fluid for this type of experiment.

The shear modulus of Dimethylpolysiloxane varies with preparation conditions, and consequently dramatically varies in the range of 100 kPa to 3 MPa.
The loss tangent is very low (tan δ ≪ 0.001).

Chemical compatibility:
Dimethylpolysiloxane is hydrophobic.
Plasma oxidation can be used to alter the surface chemistry, adding silanol (SiOH) groups to the surface.
Atmospheric air plasma and argon plasma will work for this application.
This treatment renders the Dimethylpolysiloxane surface hydrophilic, allowing water to wet it.

The oxidized surface can be further functionalized by reaction with trichlorosilanes.
After a certain amount of time, recovery of the surface's hydrophobicity is inevitable, regardless of whether the surrounding medium is vacuum, air, or water; the oxidized surface is stable in air for about 30 minutes.
Alternatively, for applications where long-term hydrophilicity is a requirement, techniques such as hydrophilic polymer grafting, surface nanostructuring, and dynamic surface modification with embedded surfactants can be of use.

Solid Dimethylpolysiloxane samples (whether surface-oxidized or not) will not allow aqueous solvents to infiltrate and swell the material.
Thus Dimethylpolysiloxane structures can be used in combination with water and alcohol solvents without material deformation.
However most organic solvents will diffuse into the material and cause it to swell.
Despite this, some organic solvents lead to sufficiently small swelling that they can be used with Dimethylpolysiloxane, for instance within the channels of PDMS microfluidic devices.

The swelling ratio is roughly inversely related to the solubility parameter of the solvent.
Diisopropylamine swells Dimethylpolysiloxane to the greatest extent; solvents such as chloroform, ether, and THF swell the material to a large extent.
Solvents such as acetone, 1-propanol, and pyridine swell the material to a small extent.
Alcohols and polar solvents such as methanol, glycerol and water do not swell the material appreciably.

Applications of Dimethylpolysiloxane:
Dimethylpolysiloxane is a common surfactant and is a component of defoamers.
Dimethylpolysiloxane, in a modified form, is used as an herbicide penetrant and is a critical ingredient in water-repelling coatings, such as Rain-X.

Hydraulic fluids and related applications of Dimethylpolysiloxane:
Dimethicone is used in the active silicone fluid in automotive viscous limited slip differentials and couplings.

Soft lithography:
Dimethylpolysiloxane is commonly used as a stamp resin in the procedure of soft lithography, making it one of the most common materials used for flow delivery in microfluidics chips.
The process of soft lithography consists of creating an elastic stamp, which enables the transfer of patterns of only a few nanometers in size onto glass, silicon or polymer surfaces.
With this type of technique, it is possible to produce devices that can be used in the areas of optic telecommunications or biomedical research.
The stamp is produced from the normal techniques of photolithography or electron-beam lithography.
The resolution depends on the mask used and can reach 6 nm.

The popularity of Dimethylpolysiloxane in microfluidics area is due to its excellent mechanical properties.
Moreover, compared to other materials, it possesses superior optical properties, allowing for minimal background and autofluorescence during for fluorescent imaging.

In biomedical (or biological) microelectromechanical systems (bio-MEMS), soft lithography is used extensively for microfluidics in both organic and inorganic contexts.
Silicon wafers are used to design channels, and PDMS is then poured over these wafers and left to harden.
When removed, even the smallest of details is left imprinted in the Dimethylpolysiloxane.
With this particular Dimethylpolysiloxane block, hydrophilic surface modification is conducted using plasma etching techniques.

Plasma treatment disrupts surface silicon-oxygen bonds, and a plasma-treated glass slide is usually placed on the activated side of the Dimethylpolysiloxane (the plasma-treated, now hydrophilic side with imprints).
Once activation wears off and bonds begin to reform, silicon-oxygen bonds are formed between the surface atoms of the glass and the surface atoms of the PDMS, and the slide becomes permanently sealed to the PDMS, thus creating a waterproof channel.
With these devices, researchers can utilize various surface chemistry techniques for different functions creating unique lab-on-a-chip devices for rapid parallel testing.
Dimethylpolysiloxane can be cross-linked into networks and is a commonly used system for studying the elasticity of polymer networks.

Dimethylpolysiloxane can be directly patterned by surface-charge lithography.
Dimethylpolysiloxane is being used in the making of synthetic gecko adhesion dry adhesive materials, to date only in laboratory test quantities.

Some flexible electronics researchers use Dimethylpolysiloxane because of its low cost, easy fabrication, flexibility, and optical transparency.
Yet, for fluorescence imaging at different wavelengths, Dimethylpolysiloxane shows least autofluorescence and is comparable to BoroFloat glass.

In stereo lithography (SLA) 3D printing, light is projected onto photocuring resin to selectively cure it.
Some types of SLA printer are cured from the bottom of the tank of resin and therefore require the growing model to be peeled away from the base in order for each printed layer to be supplied with a fresh film of uncured resin.
A Dimethylpolysiloxane layer at the bottom of the tank assists this process by absorbing oxygen : the presence of oxygen adjacent to the resin prevents it adhering to the Dimethylpolysiloxane, and the optically clear PDMS permits the projected image to pass through to the resin undistorted.

Medicine and cosmetic applications of Dimethylpolysiloxane:
Activated dimethicone, a mixture of polydimethylsiloxanes and silicon dioxide (sometimes called simethicone), is often used in over-the-counter drugs as an antifoaming agent and carminative.
Dimethylpolysiloxane has also been at least proposed for use in contact lenses.

Silicone breast implants are made out of a Dimethylpolysiloxane elastomer shell, to which fumed amorphous silica is added, encasing PDMS gel or saline solution.
In addition, Dimethylpolysiloxane is useful as a lice or flea treatment because of its ability to trap insects.
Dimethylpolysiloxane also works as a moisturizer that is lighter and more breathable than typical oils.

Skin applications of Dimethylpolysiloxane:
Dimethylpolysiloxane is used variously in the cosmetic and consumer product industry as well.
For example, Dimethylpolysiloxane can be used in the treatment of head lice on the scalp and dimethicone is used widely in skin-moisturizing lotions where it is listed as an active ingredient whose purpose is "skin protection."
Some cosmetic formulations use dimethicone and related siloxane polymers in concentrations of use up to 15%.

Hair applications of Dimethylpolysiloxane:
Dimethylpolysiloxane compounds such as amodimethicone, are effective conditioners when formulated to consist of small particles and be soluble in water or alcohol/act as surfactants (especially for damaged hair), and are even more conditioning to the hair than common dimethicone and/or dimethicone copolyols.

A proposed use of Dimethylpolysiloxane is contact lens cleaning.
Dimethylpolysiloxanes physical properties of low elastic modulus and hydrophobicity have been used to clean micro and nano pollutants from contact lens surfaces more effectively than multipurpose solution and finger rubbing; the researchers involved call the technique PoPPR (polymer on polymer pollution removal) and note that it is highly effective at removing nanoplastic that has adhered to lenses.

Flea treatment for pets:
Dimethicone is the active ingredient in a liquid applied to the back of the neck of a cat or dog from a small one time use dose disposable pipette.
The parasite becomes trapped and immoblised in the substance and thus breaks the life cycle of the insect.

Foods:
Dimethylpolysiloxane is added to many cooking oils (as an antifoaming agent) to prevent oil splatter during the cooking process.
As a result of this, Dimethylpolysiloxane can be found in trace quantities in many fast food items such as McDonald's Chicken McNuggets, french fries, hash browns, milkshakes and smoothies and Wendy's french fries.
Under European food additive regulations, Dimethylpolysiloxane is listed as E900.

Dimethylpolysiloxane is an anti-foaming agent derived from silicone found in a variety of foods, including cooking oil, vinegar, chewing gum, and chocolate.
Dimethylpolysiloxane's added to oil to prevent it from bubbling up when frozen ingredients are added, so it improves the safety and life of the product.
While the risk of toxicity is considered low, Dimethylpolysiloxane's not a chemical you'd ordinarily consider to be "food."
Dimethylpolysiloxane's also found in putty, shampoo, and caulk, which are products you certainly wouldn't want to eat.

One ingredient that particularly caught my attention is dimethylpolysiloxane, also known as polydimethylsiloxane (PDMS).
Dimethylpolysiloxane is a compound known as a silicone.
Dimethylpolysiloxane’s a polymer – a large molecule made up of multiple smaller parts – that contains alternating silicon and oxygen atoms.
Dimethylpolysiloxane has a wide range of applications, such as skincare, shampoos, and lubricants.

Dimethylpolysiloxane is also found in food, where is it used an anti-foaming agent to prevent oil splatters during the cooking process.
Thus, Dimethylpolysiloxane is present in numerous fast food items, including those beloved McDonald’s French fries.
Dimethylpolysiloxane is more commonly known as a component of Silly Putty, a popular children’s toy with elastic properties.

Applications of Dimethylpolysiloxane:
Dimethylpolysiloxane is a clear, colorless fluid polymer useful as a stationary phase in gas chromatography and as an anti-foaming agent.
Dimethylpolysiloxane is used in protein chromatography and affininty chromatography.
Dimethylpolysiloxane was used to determine that postprandial inflammatory response after ingestion of heated oils in obese persons is reduced by the presence of phenol compounds.

Condom lubricant:
Dimethylpolysiloxane is widely used as a condom lubricant.

InChI key: SEUDSDUUJXTXSV-UHFFFAOYSA-N
viscosity: 500 cSt(25 °C)(lit.)
InChI: 1S/C2H6OSi/c1-4(2)3/h1-2H3
mol wt: ~17,250
Quality Level: 100

CAS Number: 9006-65-9
ECHA InfoCard: 100.126.442
E number: E900 (glazing agents, ...)
UNII: 92RU3N3Y1O
CompTox Dashboard (EPA): DTXSID0049573
Chemical formula: (C2H6OSi)n
Density: 965 kg/m3

Description of Dimethylpolysiloxane:
Polydimethylsiloxane belongs to a group of polymeric organosilicon compounds that are commonly referred to as silicones.
Dimethylpolysiloxane is the most widely used silicon-based organic polymer, and is particularly known for its unusual rheological properties.
Dimethylpolysiloxane is optically clear, and, in general, is considered to be inert, non-toxic and non-flammable.
Dimethylpolysiloxanes applications range from contact lenses and medical devices to elastomers.
Dimethylpolysiloxane is present, also, in shampoos, caulking, lubricating oils, and heat-resistant tiles.

Chemical Properties of Dimethylpolysiloxane:
Appearance : Colourless liquid
Boiling Point: 155-220°C
CAS Number: 9016-00-6
HS Code: 39100000
IUPAC Name: Poly(dimethylsiloxane)
Melting Point: -35°C
Molecular Formula: (C2H6OSi)n
RTECS Number: TQ2690000
Refractive: n20/D 1.4035
Solubility: Insoluble
Synonyms: Polydimethylsiloxane, Trimethylsiloxy Term;Polydimethylsiloxane, Trimethylsiloxy Terminated, Blend;Polydimethylsiloxanes, Trimethylsiloxy Terminated;Silicone Fluid;Silicone Fluid, 100;Silicone Fluid 1,000;Silicone Fluid 500;Aeropax; E900;PDMS;Dimethicone

What is Dimethylpolysiloxane made of?
Dimethylpolysiloxane is an anti-foaming agent derived from silicone found in a variety of foods, including cooking oil, vinegar, chewing gum, and chocolate.
Dimethylpolysiloxane’s added to oil to prevent it from bubbling up when frozen ingredients are added, so it improves the safety and life of the product.

What is Dimethylpolysiloxane used in?
Dimethylpolysiloxane functions as an anti-foaming agent, skin conditioning agent, occlusive and skin protectant.
Dimethylpolysiloxane is found in many cosmetic and hygiene products like nail polish, conditioners, make-up, contact lens solutions, sunscreens, deodorants, and shampoo.

Is Dimethylpolysiloxane natural?
More commonly known as Dimethylpolysiloxane, dimethylpolysiloxane is a silicon-based synthetic polymer (so plastic, basically) that’s used as an anti-foaming and anti-caking agent and emulsifier in processed foods.

What is polydimethylsiloxane in food?
Dimethylpolysiloxane, also known as polydimethylsiloxane (PDMS), is a form of silicone used as an antifoaming agent in food with the European food additive number E900.
Dimethylpolysiloxane is commonly used in frying oil due to its good defoaming effectiveness at high temperatures.

How do you make polysiloxane?
Linear polysiloxane can be synthesized by both anionic and cationic polymerizations of cyclic siloxanes such as hexamethylcyclotrisiloxane (n = 3) and octamethyl cyclotetrasiloxane (n = 4).
Anionic polymerization is initiated by hydroxide, alkoxides, phenolates, silanolates and siloxoanolates.

How is polysiloxane made?
Silicone synthesis typically involves the hydrolysis of chlorosilanes into linear or cyclic siloxane oligomers, which are then polymerized into polysiloxanes by polycondensation or polymerization, respectively.
The most common polysiloxane is linear poly(dimethylsiloxane).

What is polysiloxane paint?
The secret to the performance of polysiloxane coatings can be found in their chemistry — a string of powerful silicone-oxygen bonds.
When polysiloxane polymers are created, each silicone atom is bonded to two or three oxygen atoms, causing the silicone to be 50 to 75% oxidized when the coating is formulated.

What is the chemical formula for PDMS?
The chemical formula for Dimethylpolysiloxane is CH 3[Si(CH 3) 2O] nSi(CH 3) 3, where n is the number of repeating monomer [SiO(CH 3) 2] units.

What is dimethylpolysiloxane (E 900)?
Currently, dimethylpolysiloxane (E 900) is an authorized food additive, used as an antifoaming agent in foods: Fats and oils essentially free from water (excluding anhydrous milk fat) Other fat and oil emulsions including spreads and liquid emulsions

What is the chemical formula for Sugar Sugar?
C12H22O11 is the chemical or molecular formula for sucrose, meaning each sugar molecule contains 12 atoms of carbon, 22 atoms of hydrogen and 11 atoms of oxygen.
What are the 3 elements in the formula for sugar?
Therefore, all carbohydrates, including sugar, contain the same three elements: carbon, oxygen and hydrogen.

Domestic and niche uses of Dimethylpolysiloxane:
Many people are indirectly familiar with Dimethylpolysiloxane because it is an important component in Silly Putty, to which PDMS imparts its characteristic viscoelastic properties.
Another toy Dimethylpolysiloxane is used in is Kinetic Sand.
The rubbery, vinegary-smelling silicone caulks, adhesives, and aquarium sealants are also well-known.
Dimethylpolysiloxane is also used as a component in silicone grease and other silicone based lubricants, as well as in defoaming agents, mold release agents, damping fluids, heat transfer fluids, polishes, cosmetics, hair conditioners and other applications.
Dimethylpolysiloxane can be used as a sorbent for the analysis of headspace (dissolved gas analysis) of food.

Safety and environmental considerations:
According to Ullmann's Encyclopedia, no "marked harmful effects on organisms in the environment" have been noted for siloxanes.
Dimethylpolysiloxane is nonbiodegradable, but is absorbed in waste water treatment facilities.
Dimethylpolysiloxanes degradation is catalyzed by various clays.

How is Dimethylpolysiloxane Made?
Dimethylpolysiloxane is produced by hydrolysis of a mixture of dimethyldichlorosilane and a small quantity of trimethylchlorosilane.

Synonym(s): Polydimethylsiloxane
CAS Number: 9016-00-6
MDL number: MFCD00084411
PubChem Substance ID: 24894362
NACRES: NA.25

Applications of Dimethylpolysiloxane:
Dimethylpolysiloxane is used in protein chromatography and affininty chromatography.
Dimethylpolysiloxane was used to determine that postprandial inflammatory response after ingestion of heated oils in obese persons is reduced by the presence of phenol compounds.
Dimethylpolysiloxane is commonly used in vinegary-smelling silicone caulks, adhesives, and aquarium sealants, a component in silicone grease and other silicone based lubricants, as well as in defoaming agents, mold release agents, damping fluids, heat transfer fluids, polishes, cosmetics, hair conditioners and in food.

IUPAC name:
poly(dimethylsiloxane)

Other names:
PDMS
dimethicone
dimethylpolysiloxane
E900

Dimethylpolysiloxane can be used to treat inflammatory conditions of the esophagus as well as inflammatory and ulcerative conditions of the digestive tract.

Appearance:
Dimethylpolysiloxane is a clear, colourless, viscous liquid.

Solubility:
As Dimethylpolysiloxanes no polarity, it is insoluble in polar substances, such as water and in ethanol while soluble in non-polar materials, like in carbon tetrachloride, benzene, chloroform, diethyl ether, toluene and other organic solvents.

Is Dimethylpolysiloxane Halal?
Yes, Dimethylpolysiloxane is recognised as halal.

Is Dimethylpolysiloxane Kosher?
Yes, Dimethylpolysiloxane is kosher pareve. It has met all the “kashruth” requirements.

Is Dimethylpolysiloxane Gluten free?
Yes, Dimethylpolysiloxane is gluten free according to FDA that it does not contain wheat, rye, barley, or crossbreeds of these grains.

Is Dimethylpolysiloxane Vegan?
Generally, Dimethylpolysiloxane is vegan as the manufacturing process without the use of animal matter or products derived from animal origin.
So Dimethylpolysiloxane is considered vegan and vegetarians can eat the food with it.

Conclusion:
Now you may have a knowledge of the antifoaming agent – Dimethylpolysiloxane (E900), from the following aspects:
-Manufacturing process
-Uses and functions in food
-Safety and possible side effects
-FAQs

Dimethylpolysiloxane Can Contain Formaldehyde
The FDA allows dimethylpolysiloxane to be preserved by several different chemicals that don’t have to be listed on the label either, including formaldehyde! Formaldehyde is one of the most highly toxic substances on earth.
Dimethylpolysiloxane is linked to allergies, brain damage, cancer, and auto-immune disorders.

Food Category and Maximum Level
Ready-for-consumption Food: 10 mg/kg
Milk: 0
dry gelatin dessert mixes: 110 mg/kg
ready-to-serve dessert: 16 mg/kg
salt for cooking purposes: 250 mg/kg
Cooked food: 10 mg/kg

Functions of Dimethylpolysiloxane:
1. Anti-caking Agent - Prevents lumps from forming in food due to excess water.
They usually function as a water repellent or by absorbing excess moisture.

2. Anti-foaming Agent / Defoamer - Reduces or hinders the formation of foam.

3. Drug / Medicine - Treats, alleviate, cure, or prevents sickness.
As officially declared by a governmental drug/medicine regulatory body

4. Emollient - Softens and soothes the skin.
Prevents water (moisture) loss from the skin.

5. Lubricant - Prevents or reduces friction

6. Surfactant - Reduces the surface tension to allow mixtures to be formed evenly.
Emulsifier is a specific type of surfactant which allows two liquids to mix together evenly

Dimethicone (also called polymethylsiloxane) is a silicon-based polymer used as a lubricant and conditioning agent.
Dimethylpolysiloxanes applications range from contact lenses and medical devices to elastomers; it is also present in shampoos (as dimethicone makes hair shiny and slippery), food (antifoaming agent), caulking, lubricants and heat-resistant tiles.
Activated dimethicone, a mixture of polydimethylsiloxanes (PDMS) and silicon dioxide (sometimes called simethicone), is often used in over-the-counter drugs as an antifoaming agent.
Dimethylpolysiloxane is used variously in the cosmetic and consumer product industry as well.

For example, Dimethylpolysiloxane can be used in the treatment of head lice on the scalp and dimethicone is used widely in skin-moisturizing lotions where it is listed as an active ingredient whose purpose is "skin protection."
Some cosmetic formulations use dimethicone and related siloxan

DIMYRISTYL PHOSPHATE, N° CAS : 6640-03-5, Nom INCI : DIMYRISTYL PHOSPHATE, Nom chimique : Ditetradecyl hydrogen phosphate, N° EINECS/ELINCS : 229-651-0, Ses fonctions (INCI), Agent nettoyant : Aide à garder une surface propre. Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile). Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation

DIMYRISTYL TARTRATE, N° CAS : 94237-18-0, Nom INCI : DIMYRISTYL TARTRATE, Nom chimique : 2,3-Dihydroxybutanedioic Acid, Ditetradecyl Ester, N° EINECS/ELINCS : 304-118-6, Ses fonctions (INCI): Emollient : Adoucit et assouplit la peau, Agent d'entretien de la peau : Maintient la peau en bon état

Di-sec-octyl phthalate; DOP; Bis(2-Etheylexyl) Phthalate; Bis(2-Ethylhexyl) Phthalate; Benzenedicarboxylic acid, bis(2-ethylhexyl) ester; 1,2-Benzenedicarboxylic acid bis(2-ethylhexyl) ester; Octoil; Ethyl hexyl phthalate; 2-Ethylhexyl phthalate; Di-sec-octyl phthalate; DEHP; Octyl phthalate; phthalic acid dioctyl ester; BEHP CAS NO:117-81-7

Dioctyl terephthalate; 1,4-Benzenedicarboxylic acid bis(2-ethylhexyl) ester; Bis(2-ethylhexyl) terephthalate; Di-(2-ethylhexyl) terephthalate; DOTP; Terephthalic acid bis(2-ethylhexyl) ester; 1,4-Benzenedicarboxylic acid 1,4-bis(2-ethylhexyl) ester; 1,4-Benzenedicarboxylic acid dioctyl ester CAS NO:6422-86-2, 4654-26-6

SYNONYMS AOT, Bis(2-ethylhexyl) sulfosuccinate sodium salt, DOSS, Docusate sodium;2,3-Bis(2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxanilide inner salt CAS NO:577-11-7

DIOLEYL PHOSPHATE, N° CAS : 14450-07-8, Nom INCI : DIOLEYL PHOSPHATE, Nom chimique : Di-(9-Octadecen-1-yl) hydrogen phosphate, (Z,Z)-, N° EINECS/ELINCS : 238-431-3, Ses fonctions (INCI): Régulateur de pH : Stabilise le pH des cosmétiques, Agent émulsifiant : Favorise la formation de mélanges intimes entre des liquides non miscibles en modifiant la tension interfaciale (eau et huile), Stabilisateur d'émulsion : Favorise le processus d'émulsification et améliore la stabilité et la durée de conservation de l'émulsion. Conditionneur capillaire : Laisse les cheveux faciles à coiffer, souples, doux et brillants et / ou confèrent volume, légèreté et brillance. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation

1-methyl-4-(1-methylethenyl)cyclohexene; Cajeputene; Cinene; Ciene; p-Mentha-1,8-diene; Cyclil decene; limonene; p-mentha-1,8-diene; 4-isopropenyl-1-methyl-Cyclohexene; Dipenten; DL-p-mentha-1,8-diene; 4-Isopropenyl-1-methyl-1-cyclohexene; Mentha-1,8-diene; Mentha-1,8-diene, DL; Menthadiene; Methyl-4-(1-methylethenyl)cyclohexene; Methyl-4-isopropenyl-1-cyclohexene; Methyl-4-isopropenylcyclohexene; Monocyclic terpene hydrocarbons; Terpodiene; 4-(1-methylethenyl)-1-methyl-cyclohexene CAS NO:138-86-3

dipentaerythrityl hexa C5-9 acid esters; Carboxylic Acids, C5-9, Hexaesters with Dipentaerythrol; HEXAESTERS WITH DIPENTAERYTHRITOL, CAS NO:67762-52-1

Ses fonctions (INCI) Agent d'entretien de la peau : Maintient la peau en bon état

DIPHENYL ETHER, N° CAS : 101-84-8. Nom INCI : DIPHENYL ETHER. Nom chimique : Benzene, 1,1'-Oxybis. N° EINECS/ELINCS : 202-981-2. Ses fonctions (INCI) : Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit

DIPOTASSIUM AZELATE, N° CAS : 52457-54-2, Nom INCI : DIPOTASSIUM AZELATE. Nom chimique : Dipotassium nonanedioate. N° EINECS/ELINCS : 257-931-2. Ses fonctions (INCI): Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques

DIPOTASSIUM EDTA, N° CAS : 2001-94-7, Nom INCI : DIPOTASSIUM EDTA. Nom chimique : Dipotassium dihydrogen ethylenediaminetetraacetate. N° EINECS/ELINCS : 217-895-0. Agent de chélation : Réagit et forme des complexes avec des ions métalliques qui pourraient affecter la stabilité et / ou l'apparence des produits cosmétiques

Phosphoric acid, dipotassium salt; Dipotassium hydrogen orthophosphate; Dipotassium hydrogenphosphate; Potassium phosphate, dibasic; Potassium hydrogen phosphate; DIBASIC POTASSIUM PHOSPHATE; DI-POTASSIUM HYDROGEN ORTHOPHOSPHATE; di-Potassium hydrogen orthophosphate anhydrous; DI-POTASSIUM HYDROGEN PHOSPHATE; DIPOTASSIUM PHOSPHATE; DI-POTASSIUM PHOSPHATE DIBASIC; DKP; MONOPOTASSIUM PHOSPHATE; POTASSIUM BIPHOSPHATE; POTASSIUM HYDROGEN PHOSPHATE; POTASSIUM HYDROGEN PHOSPHATE, DIBASIC; POTASSIUM MONOHYDROGEN PHOSPHATE; POTASSIUM MONOPHOSPHATE; POTASSIUM PHOSPHATE, DIBASIC; SEC-POTASSIUM PHOSPHATE; dikaliumphosphate; dipotassiummonohydrogenphosphate; dipotassiummonophosphate; dipotassium-o-phosphate; dipotassiumorthophosphate CAS NO:7758-11-4

DIPOTASSIUM PHOSPHATE, N° CAS : 7758-11-4, Nom INCI : DIPOTASSIUM PHOSPHATE, Nom chimique : Dipotassium hydrogenorthophosphate, N° EINECS/ELINCS : 231-834-5, Ses fonctions (INCI). Anticorrosif : Empêche la corrosion de l'emballage. Régulateur de pH : Stabilise le pH des cosmétiques

CAS number: 142-84-7
EC Number: 205-565-9
Chemical formula: C6H15N
Molar mass: 101.193 g·mol−1
IUPAC Name: N-propylpropan-1-amine

Dipropylamine is a flammable, highly toxic, corrosive amine.
Dipropylamine occurs naturally in tobacco leaves and artificially in industrial wastes.
Dipropylamine exposure can cause excitement followed by depression, internal bleeding, dystrophy, and severe irritation.

Dipropylamine (DPA; also called Di-N-Propylamine DNPA) is a secondary amine which belongs to the class of dialkylamines.
Dipropylamine is a versatile intermediate with a variety of applications.

Chemical Properties of Dipropylamine:
Dipropylamine is a colourless liquid.

Chemical Properties of Dipropylamine:
Dipropylamine, like the other short chain aliphatic amines, is a very strong base, its reactivity being governed by the unshared electron pair on the nitrogen atom.
Dipropylamine forms a hydrate with water.
The amine also can react with inorganic or organic nitrites under acidic conditions and possibly by reaction with nitrogen oxides from the air to form the highly mutagenic and carcinogenic N-nitrosodipropylamine.

Production Methods of Dipropylamine:
Dipropylamine is manufactured by reaction of propanol and ammonia over a dehydration catalyst at high temperature and pressure.
Alternatively, propanol and ammonia can be combined with hydrogen over a dehydrogenation catalyst.
In each instance, the resulting mixture of primary, secondary, and tertiary amines can be separated by continuous distillation and extraction.
Dipropylamine is a natural component of vegetables, fish, fruits, and other foods and of tobacco products.

Dipropylamine also is found in human urine, waste water lagoons and in workplace air.
The toxic compound, Dipropylamine, can be produced inadvertently by nitrosation of n-dipropylamine during various manufacturing processes that use the diamine.
Dipropylamine, therefore, occurs as an impurity in some dinitroaniline pesticides and rubber products.
Dipropylamine also is found in various foodstuffs including cheese, cured meats, cooked fish and alcoholic beverages, apparently by reaction of n-dipropylamine with the preservative sodium nitrite.

General Description of Dipropylamine:
Dipropylamine is a clear colorless liquid with an ammonia-like odor.
Dipropylamine' flash point is 30°F.
Dipropylamine is less dense than water.
Dipropylamine vapors heavier than air.
Toxic oxides of nitrogen produced during combustion.

Applications, intermediate used in the production of: crop protection agents, herbicides, pharmaceuticals. Packaging, available in bulk and drums.

Air & Water Reactions of Dipropylamine:
Dipropylamine is highly flammable.
Dipropylamine is soluble in water.

Product Description:
General:
Synonyms: di-n-propylamine, N,N-dipropylamine, N-propyl-1-
propanamine, N-dipropylamine
Use: synthetic intermediate
Molecular formula: C6H15N
CAS No: 142-84-7
EINECS No: 205-565-9
Annex I Index no: 612-048-00-5

Dipropylamine is used in the rubber industry and as a chemical intermediate in themanufacture of the herbicides S-ethyl-di-n-propylthiocarbamate and S-propyldi-n-propylthiocarbamate.
Dipropylamine also is employed in thepurification of perfluoro compounds to convert the incompletely fluorinatedimpurities to solids which are then removed by filtration.

Description of Dipropylamine:
Dipropylamine is a flammable, highly toxic, corrosive amine.
Dipropylamine occurs naturally in tobacco leaves and artificially in industrial wastes.
Exposure can cause excitement followed by depression, internal bleeding, dystrophy, and severe irritation.

Chemical Name: Dipropylamine
Synonyms: DPA;DNPA;ai3-24037;(n-C3H7)2NH;Di-n-propyL;DIPROPYLAMINE;Dipropanamine;AURORA KA-7671;N-Dipropylamine;Di-n-propylamin
CBNumber: CB1713802
Molecular Formula: C6H15N

IDENTIFICATION of Dipropylamine:
Dipropylamine is a colorless liquid with a strong ammonialike odor.
Dipropylamine is used as a chemical intermediate in the manufacture of herbicides.

Physical data:
Appearance: colorless liquid
Melting point: -40 C
Boiling point: 108 - 110 C
Vapor density:
Vapor pressure:
Density (g cm-3): 0.74
Flash point: 7 C (closed cup)
Explosion limits:
Autoignition temperature:
Water solubility: soluble, forming hydrates
Stability: Stable
Highly flammable. Incompatible with strong oxidizing agents.

Reactivity Profile of Dipropylamine:
Dipropylamine neutralizes acids in exothermic reactions to form salts plus water.
Dipropylamine may be incompatible with isocyanates, halogenated organics, peroxides, phenols (acidic), epoxides, anhydrides, and acid halides.
Flammable gaseous hydrogen may be generated in combination with strong reducing agents, such as hydrides.

Health Hazard of Dipropylamine:
Dipropylamine inhalation causes severe coughing and chest pain due to irritation of air passages; can-cause lung edema; may also cause headache, nausea, faintness, and anxiety.
Dipropylamine ingestion causes irritation and burning of mouth and stomach.
Dipropylamine contact with eyes causes severe irritation and edema of the cornea.
Dipropylamine contact with skin causes severe irritation.

Health Hazard of Dipropylamine:
Inhalation of dipropylamine vapors can result in severe coughing and chest pain due to irritation of airways.
Transient symptoms of exposure may include headache, nausea, faintness, and anxiety.
Prolonged breathing of vapors may result in lung edema.
Dipropylamine also can cause severe irritation and edema of the cornea.
A review of the toxicity of dipropylamine has been prepared.

Fire Hazard of Dipropylamine:
Special Hazards of Combustion Products: Toxic oxides of nitrogen may form in fires.

Preferred IUPAC name:
N-Propylpropan-1-amine

CAS Number: 142-84-7
Beilstein Reference: 505974
ChemSpider: 8562
ECHA InfoCard: 100.005.060
EC Number: 205-565-9
PubChem CID: 8902
RTECS number: JL9200000
UNII: 60P318IIRY
UN number: 2383
CompTox Dashboard (EPA): DTXSID2025185

The 2D chemical structure image of DIPROPYLAMINE is also called skeletal formula, which is the standard notation for organic molecules.
The carbon atoms in the chemical structure of DIPROPYLAMINE are implied to be located at the corner(s) and hydrogen atoms attached to carbon atoms are not indicated – each carbon atom is considered to be associated with enough hydrogen atoms to provide the carbon atom with four bonds.

The 3D chemical structure image of DIPROPYLAMINE is based on the ball-and-stick model which displays both the three-dimensional position of the atoms and the bonds between them.
The radius of the spheres is therefore smaller than the rod lengths in order to provide a clearer view of the atoms and bonds throughout the chemical structure model of DIPROPYLAMINE.

Chemical formula: C6H15N
Molar mass: 101.193 g·mol−1
Appearance : Colorless liquid
Odor: Ichtyal, ammoniacal
Density: 738 mg mL−1
Melting point: −63.00 °C; −81.40 °F; 210.15 K
Boiling point: 109 to 111 °C; 228 to 232 °F; 382 to 384 K
Solubility in diethyl ether: Miscible
Henry's law constant (kH): 190 μmol Pa−1 kg−1
Refractive index (nD): 1.4049

Other names:
(Dipropyl)amine

Industrial uses of Dipropylamine:
Dipropylamine is used in the rubber industry and as a chemical intermediate in the manufacture of the herbicides S-ethyl-di-n-propylthiocarbamate and S-propyl di-n-propylthiocarbamate.
Dipropylamine also is employed in the purification of perfluoro compounds to convert the incompletely fluorinated impurities to solids which are then removed by filtration.
In 1984, U.S. production of Dipropylamine was 41 million pounds.

Safety Profile:
Dipropylamine is moderately toxic by shin contact and inhalation.
Dipropylamine is a skin irritant.
Dipropylamine is a very dangerous fire hazard, when exposed to heat or flame.
Dipropylamine can react with oxidizers.
Dipropylamine explosion hazard is unknown.
Keep Dipropylamine away from heat and open flame.

Metabolism of Dipropylamine:
There is little information available on the metabolism and disposition of dipropylamine in biological systems.
The available evidence suggests that dipropylamine is not a substrate for monoamine oxidase, but rather is inhibitory.
Valiev administered dipropylamine intraperitoneally to rats and reported it to be moderately inhibitory to liver monoamine oxidase.

Previous work by this author demonstrated that lethal doses of dipropylamine and other secondary and tertiary amines significantly inhibited rat liver monoamine oxidase activity.
The carcinogenic N-nitrosodipropylamine has been detected in the stomach when dipropylamine (present in fish, vegetables and fruit juices) comes in contact with nitrite, which is often used as a food additive in meats and smoked fish.
Further metabolism of the carcinogen N-nitrosodipropylamine product formed upon nitrosation of dipropylamine is required to form a highly electrophilic carbonium ion capable of alkylating DNA, etc.

Di-n-propylamine is a member of the class of compounds known as dialkylamines.
Dialkylamines are organic compounds containing a dialkylamine group, characterized by two alkyl groups bonded to the amino nitrogen.
Di-n-propylamine is soluble (in water) and a very strong basic compound (based on its pKa).
Di-n-propylamine can be found in a number of food items such as wild celery, orange bell pepper, yellow bell pepper, and pepper (c. annuum), which makes di-n-propylamine a potential biomarker for the consumption of these food products.

Dipropylamine hydrochloride is the hydrochloride salt of Dipropylamine (D492150).
Dipropylamine hydrochloride is also used as a reagent to prepare derivatives of 4-(2-N,N-di-n-propylaminoethyl)-5-hydroxyindole, some of which are potent, active dopaminergic agonists.

Air & Water Reactions of Dipropylamine:
Dipropylamine is highly flammable.
Dipropylamine is soluble in water.

Propylamine, dipropylamine and triplopylamine were adsorbed on sepiolite specimens under reflux, at their normal boiling points.
The infrared spectra of the original and the amine adsorbed specimens were recorded before and after heat treatments between 50-400"C.
The examination of the spectra revealed that the adsorption of amines took place by the replacement of the zeolitic water in the pores of the sepiolite by the amines.

Fire Hazard:
Special Hazards of Combustion Products: Toxic oxides of nitrogen may form in fires.

The relative density was 0.7401.
Boiling point 109~110 deg C.
Melting Point -63.6 °c.
Flash point 7 ℃.
Refractive index 4042.
The vapor pressure at 20 °c was 2.80 kPa.
Slightly soluble in water, soluble in ethanol and ether, etc.
Hydrate formation with water.

Dipropylamine - Preparation Method:
The N-propanol amination method is obtained by catalytic dehydrogenation, amination, dehydration and hydrogenation of propanol as a raw material (see tripropylamine).
Acrylonitrile hydrogenation method using acrylonitrile as a raw material and a copper-nickel compound as a catalyst, the catalytic hydrogenation is carried out at a temperature of 40-250 ° C.
And a pressure of 0-4.9 MPa to obtain dipropylamine.

Density: 0.7±0.1 g/cm3
Boiling Point: 108.8±0.0 °C at 760 mmHg
Melting Point: -63 °C
Molecular Formula: C6H15N
Molecular Weight: 101.190
Flash Point: 3.9±0.0 °C
Exact Mass: 101.120445
PSA: 12.03000
LogP: 1.70
Vapour Pressure: 25.5±0.2 mmHg at 25°C
Index of Refraction: 1.405
Stability: Stable. Highly flammable. Incompatible with strong oxidizing agents.
Water Solubility: soluble

Use and emission sources:
Manufacture of organic products, manufacture of pesticides

In this work, a comprehensive study of the hydrothermal synthesis and catalytic performance of SAPO-34 templated by the isomeric dipropylamine (DPA) and diisopropylamine (DIPA) was carried out.
SAPO-34 with a faster crystallization rate and lower Si content could be obtained with DIPA as the template, suggesting the better templating efficacy of DIPA than DPA.
Theoretical calculations reveal that DIPA possesses more favourable non-bonding interactions with the CHA framework and the electronic configuration is of vital importance in determining the template efficacy.
SAPO-34-DIPA with low silicon contents exhibits excellent performance, over which a maximum selectivity of ethylene plus propylene (87.2%) is observed.

This value should be among the top ever reported.
The surface Si enrichment on the crystals, which is both template- and condition-dependent, is revealed to be of significant influence in the catalytic performance.
The relatively homogenous Si distribution in the crystals, lower acid concentration and weaker acid strength corporately make SAPO-34-DIPA an excellent MTO catalyst.

Reactivity Profile of Dipropylamine:
DIPROPYLAMINE neutralizes acids in exothermic reactions to form salts plus water.
Dipropylamine may be incompatible with isocyanates, halogenated organics, peroxides, phenols (acidic), epoxides, anhydrides, and acid halides.
Dipropylamine is flammable gaseous hydrogen may be generated in combination with strong reducing agents, such as hydrides.

Synonyms: N-propylpropan-1-amine, dipropylamine, N-dipropylamine, N-propyl-1-propanamine, N-propyl-propylamine

Molecular Weight: 101.19
XLogP3: 1.7
Hydrogen Bond Donor Count: 1
Hydrogen Bond Acceptor Count: 1
Rotatable Bond Count: 4
Exact Mass: 101.120449483
Monoisotopic Mass: 101.120449483
Topological Polar Surface Area: 12 Ų
Heavy Atom Count: 7
Formal Charge: 0
Complexity: 23.4
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

REASON FOR CITATION:
* Dipropylamine is on the Hazardous Substance List because it is cited by DOT, NFPA and EPA.
* Dipropylamine is on the Special Health Hazard Substance List because it is FLAMMABLE.

HAZARD SUMMARY:
-Dipropylamine can affect you when breathed in.
-Dipropylamine can severely irritate and burn the skin and eyes on contact.
-Breathing Dipropylamine can irritate the nose and throat causing coughing and wheezing.
-Breathing Dipropylamine can irritate the lungs causing coughing and/or shortness of breath. Higher exposures can cause a build-up of fluid in the lungs (pulmonary edema), a medical emergency, with severe shortness of breath.
-Exposure to Dipropylamine can cause headache, nausea, fainting, and anxiety.
-Dipropylamine is a FLAMMABLE LIQUID and a DANGEROUS FIRE HAZARD.

Density: 0.7400g/mL
Color: Undesignated
Melting Point: -63.0°C
Boiling Point: 105.0°C to 110.0°C
Flash Point: 7°C
Assay Percent Range: 98.5% min. (GC)
Infrared Spectrum: Authentic
Linear Formula: (CH3CH2CH2)2NH
Packaging: Glass bottle
Beilstein: 04, 138
Merck Index: 15, 3383
Refractive Index: 1.4030 to 1.4050
Quantity: 250mL
Solubility Information: Solubility in water: 46g/L (20°C). Other solubilities: freely soluble in alcohol
Specific Gravity: 0.74
Formula Weight: 101.19
Physical Form: Liquid
Percent Purity: 99%
Viscosity: 0.5 mPa.s (20°C)
Water : 0.2% max.
Chemical Name or Material: Dipropylamine, 99%

142-84-7 [RN]
1-Propanamine, N-propyl- [ACD/Index Name]
205-565-9 [EINECS]
DI-N-PROPYLAMINE
Dipropylamine [Wiki]
Dipropyl-amine
JL9200000
MFCD00009362 [MDL number]
n-Dipropylamine
n-propyl-1-propanamin [ACD/IUPAC Name]
N-Propyl-1-propanamin [German] [ACD/IUPAC Name]
N-Propyl-1-propanamine [ACD/IUPAC Name]
N-Propyl-1-propanamine [French] [ACD/IUPAC Name]
N-Propylpropan-1-amine
(n-C3H7)2NH [Formula]
3,3'-IMINODIPROPIONITRILE
345909-05-9 [RN]
63220-61-1 [RN]
92517-02-7 [RN]
DI(N-PROPYL)AMINE
DI(PROPYL-3,3,3-D3)AMINE
DI-N-PROPYL-1,1,2,2,3,3,3-D7-AMINE (MONO-PROPYL-D7)
Di-n-propylamin
Di-n-propyl-d14-amine
dipropilamina [Portuguese]
dipropyl amine
DiPropylamine Reagent Grade
dipropylammonium
EINECS 205-565-9
InChI=1/C6H15N/c1-3-5-7-6-4-2/h7H,3-6H2,1-2H
N,N-dipropylamine
N-Propyl-propylamine
STR03559
UN 2383
DIPROPYLAMINE
Di-n-propylamine
142-84-7
1-Propanamine, N-propyl-
N-propylpropan-1-amine
n-Dipropylamine
N-Propyl-1-propanamine
RCRA waste number U110
dipropyl amine
di(n-propyl)amine
UNII-60P318IIRY
DIPROPYL-AMINE
di-n-propylamin
60P318IIRY
RCRA waste no. U110
CCRIS 4805
HSDB 2644
EINECS 205-565-9
UN2383
BRN 0505974
di-propylamine
AI3-24037
di-n-propyl amine
N,N-Dipropylamine
N-propyl propylamine
N-propyl-propylamine
MFCD00009362
Dipropylamine, 99%
N,N-Dipropylamine #
N,N-di-n-propylamine
DSSTox_CID_5185
DiPropylamine Reagent Grade
EC 205-565-9
DSSTox_RID_77699
DSSTox_GSID_25185
SCHEMBL15445
(n-C3H7)2NH
CHEMBL3185961
DTXSID2025185
STR03559
ZINC1672989
Tox21_202085
BBL027756
STL194269
AKOS000118843
MCULE-6223802621
UN 2383
NCGC00249163-01
NCGC00259634-01
CAS-142-84-7
D0930
FT-0614098
FT-0625300
Dipropylamine [UN2383] [Flammable liquid]
104486-EP2292597A1
104486-EP2298761A1
104486-EP2301627A1
125304-EP2295424A1
Q410621
J-007705
J-520390
F2190-0303

Trade name
1-Propanamine, N-propyl- (9CI)
Di-n-propylamin
Di-n-propylamine
Di-n-propylamine (DnPA)
Dipropylamin
Dipropylamine
Dipropylamine (8CI)
N-Propyl-1-propanamine
n-Dipropylamine
sek. Alkylamin

Alternate Name(s)
N,N-Dipropylamine
(N-C3H7)2NH
Di-n-propyl amine
N-Dipropylamine
N-Propyl-1-propanamine
N-Propyl-propylamine
N-propylpropan-1-amine
AI3-24037
BRN 0505974
CCRIS 4805
EINECS 205-565-9
HSDB 2644
RCRA WASTE NO. U110
UN2383

Synonyms
N,N-Dipropylamine
N-Propyl-1-propanamine
Di-n-propylamine
2 propylamine
N-propylpropan-1-amine
N-propylpropan-1-aminium

DIPROPYLENE GLYCOL, N° CAS : 110-98-5 / 25265-71-8. Nom INCI : DIPROPYLENE GLYCOL. Nom chimique : 1,1'-Oxydipropan-2-ol; Oxydipropan-2-ol; Hydroxypropyloxypropanol, N° EINECS/ELINCS : 203-821-4 / 246-770-3, Classification : Glycol, Ses fonctions (INCI). Agent masquant : Réduit ou inhibe l'odeur ou le goût de base du produit. Solvant : Dissout d'autres substances. Agent de contrôle de la viscosité : Augmente ou diminue la viscosité des cosmétiques. Agent parfumant : Utilisé pour le parfum et les matières premières aromatiques. Noms français : 2,2'-Dihydroxydipropyl ether ANTROPYLENE GLYCOL DI-1,2-PROPYLENE GLYCOL Dipropylène glycol Ether di(hydroxy-2 prolylique) ETHER DIHYDROXY-2,2' ISOPROPYLIQUE Oxybis-1,1' propanol-2 OXYBISPROPANOL Noms anglais : 1,1'-Oxybis-2-propanol 1,1'-Oxydi-2-propanol Bis(2-hydroxypropyl) ether Ce produit peut aussi se trouver comme composant du dipropylène glycol (mélanges d'isomères) Utilisation et sources d'émission: Solvant de produits organiques, fabrication de polymères. 1,1'-Dimethyldiethylene glycol 1,1'-Oxybis(2-propanol) 1,1'-Oxydi(2-propanol) 1,1'-Oxydi(2-propanol) [German] 1,1'-Oxydi(2-propanol) [French] 1,1'-Oxydipropan-2-ol 1698372 [Beilstein] 203-821-4 [EINECS] 2-Propanol, 1,1'-oxybis- [ACD/Index Name] Di(propylene glycol) MFCD00004538 "1,1`-OXYDI-2-PROPANOL" [106-62-7] [110-98-5] 1-(2-hydroxypropoxy)propan-2-ol 1,1-oxybis(propan-2-ol) 1,1'-Oxybis(propan-2-ol) 1,1'-Oxybis-2-propanol 1,1'-Oxydi-2-propanol 1,1-Oxydi-2-Propanol 1,1prime-oxydipropan-2-ol 110-98-5 [RN] 2, 2'-Dihydroxyisopropyl ether 2,2'-Dihydroxydipropyl ether 25265-07-8 2-Propanol, 1,1'-oxydi- 4-Oxaheptane-2,6-diol Bis(2-hydroxypropyl) ether Bis(2-hydroxypropyl)ether Bis(hydroxypropyl) ether Di-(2-hydroxypropyl)-ether Di(propyleneglycol) Di-1,2-propylene glycol Dipropylene glycol Dipropylene glycol (mixture of isomers) Dipropylene Glycol Reagent Grade Dipropyleneglycol MFCD00051023 [MDL number] Oxybispropanol

Dimethoxy dipropyleneglycol; BIS(METHOXYPROPYL) ETHER; DIPROPYLENE GLYCOL DIMETHYL ETHER; PROGLYDE(TM) DMM; dipropyleneglycoldimethylether,mixtureofisomers; oxybis(methoxy-propan; DI(PROPYLENE GLYCOL) DIMETHYL ETHER, 99.1+%, MIXTURE OF ISOMERS; Propane, oxybismethoxy-; Dipropylenglykoldimethylether; Dimethoxy dipropyleneglycol; DPDME; DPGDME; Bis(methoxypropyl) ether, Proglyde(R) DMM CAS NO:111109-77-4

Dipropylene glycol methyl ether IUPAC Name 2-(2-methoxypropoxy)propan-1-ol Dipropylene glycol methyl ether InChI InChI=1S/C7H16O3/c1-6(4-8)10-5-7(2)9-3/h6-8H,4-5H2,1-3H3 Dipropylene glycol methyl ether InChI Key CUDYYMUUJHLCGZ-UHFFFAOYSA-N Dipropylene glycol methyl ether Canonical SMILES CC(CO)OCC(C)OC Dipropylene glycol methyl ether Molecular Formula C7H16O3 Dipropylene glycol methyl ether CAS 34590-94-8 Dipropylene glycol methyl ether ICSC Number 0884 Dipropylene glycol methyl ether DSSTox Substance ID DTXSID80864425 Dipropylene glycol methyl ether EC Number 252-104-2 Dipropylene glycol methyl ether Physical Description Dipropylene glycol methyl ether is a colorless liquid with a weak odor . Dipropylene glycol methyl ether Boiling Point 363.2 °F at 760 mm Hg Dipropylene glycol methyl ether Melting Point -117 °F Dipropylene glycol methyl ether Flash Point 166 °F Dipropylene glycol methyl ether Solubility Miscible Dipropylene glycol methyl ether Density 0.951 at 68 °F Dipropylene glycol methyl ether Vapor Density 5.11 Dipropylene glycol methyl ether Vapor Pressure 0.5 mm Hg Dipropylene glycol methyl ether Autoignition Temperature 270 °C Dipropylene glycol methyl ether Molecular Weight 148.2 g/mol Dipropylene glycol methyl ether XLogP3 -0.1 Dipropylene glycol methyl ether Hydrogen Bond Donor Count 1 Dipropylene glycol methyl ether Hydrogen Bond Acceptor Count 3 Dipropylene glycol methyl ether Rotatable Bond Count 5 Dipropylene glycol methyl ether Exact Mass 148.109944 g/mol Dipropylene glycol methyl ether Monoisotopic Mass 148.109944 g/mol Dipropylene glycol methyl ether Topological Polar Surface Area 38.7 Ų Dipropylene glycol methyl ether Heavy Atom Count 10 Dipropylene glycol methyl ether Formal Charge 0 Dipropylene glycol methyl ether Complexity 75.3 Dipropylene glycol methyl ether Isotope Atom Count 0 Dipropylene glycol methyl ether Defined Atom Stereocenter Count 0 Dipropylene glycol methyl ether Undefined Atom Stereocenter Count 2 Dipropylene glycol methyl ether Defined Bond Stereocenter Count 0 Dipropylene glycol methyl ether Undefined Bond Stereocenter Count 0 Dipropylene glycol methyl ether Covalently-Bonded Unit Count 1 Dipropylene glycol methyl ether Compound Is Canonicalized Yes Chemical: Dipropylene glycol methyl ether .Dipropylene glycol methyl ether is a colorless liquid with a weak odor .Dipropylene glycol methyl ether is an organic solvent with a variety of industrial and commercial uses.It finds use as a less volatile alternative to propylene glycol methyl ether and other glycol ethers. The commercial product is typically a mixture of four isomers.Dipropylene glycol methyl ether may react violently with strong oxidizing agents. May generate flammable and/or toxic gases with alkali metals, nitrides, and other strong reducing agents. May initiate the polymerization of isocyanates and epoxides.Dipropylene glycol methyl ether (mixture of isomeres) for synthesis. CAS 34590-94-8, chemical formula (CH₃O)C₃H₆OC₃H₆(OH).Dipropylene glycol methyl ether (DPGME) is one of the most commonly used propylene glycol ethers in industry and is discussed in a recently published NEG/NIOSH document.Dipropylene glycol methyl ether is a collective term describing a mixture of structural isomers. In the past, OSHA has determined airborne concentrations based on a method validated by NIOSH.An examination of the Backup Data Report for the NIOSH method (Ref. 5.3) revealed that the desorption efficiency was not constant, the desorption efficiency of the individual isomers of Dipropylene glycol methyl ether was not investigated, and the desorption efficiency from wet charcoal was not addressed.The reported desorption efficiency ranged from 60.4% at 2.954 mg to 89.1% at 12.01 mg of Dipropylene glycol methyl ether.For analytes such as Dipropylene glycol methyl ether, which are comprised as mixtures of related compounds, quantitation is accomplished by summing the peak areas of each component and treating the summed areas as one analyte.This is an accepted and convenient practice when using a flame ionization detector because the responses for all of the isomers of Dipropylene glycol methyl ether are identical.But if the desorption efficiencies are not the same for each isomer, they must be quantitated separately with individual desorption efficiency corrections, and then the resulting amounts are summed to determine the total amount of Dipropylene glycol methyl ether. This procedure is necessary for any method using charcoal collection and carbon disulfide desorption because the relative proportion of isomers in Dipropylene glycol methyl ether can vary by lot and manufacturer.Using this desorption solvent, the desorption efficiencies of all the isomers of Dipropylene glycol methyl ether were found to be essentially identical at approximately 100%, thus peak summations can be done.The desorption efficiencies from dry charcoal ranged from 76-93% for the isomers at a loading of 6.0 mg of Dipropylene glycol methyl ether.In the review presented in the previously mentioned NEG/NIOSH document, it was concluded that Dipropylene glycol methyl ether seems to lack reproductive toxicity, unlike some other chemically similar compounds.At very high air concentrations, Dipropylene glycol methyl ether causes narcosis in animals. It is expected that severe exposure would produce similar effects in humans, but high concentrations are disagreeable and not tolerated.Dipropylene glycol methyl ether at 300 ppm caused eye and nasal irritation to humans.ACGIH has established a TLV-TWA of 100 ppm and a TLV-STEL of 150 ppm for Dipropylene glycol methyl ether.Dipropylene glycol methyl ether is used as a solvent for paints, lacquers, resins, dyes, oil/greases, cleaners and cellulose and as a heat-transfer agent. It is frequently used as a substitute for the more toxic DEGME (diethylene glycol methyl ether).Dipropylene glycol methyl ether is a mixture of structural isomers. Also, each isomer has two asymmetrical carbon atoms, thus configurational isomers can exist. The numbers in parentheses are approximate percentages by weight of each isomer found in the Dipropylene glycol methyl ether used in this evaluation. The abbreviations in the brackets are used in chromatograms in this method.Dipropylene glycol methyl ether is a glycol ether based on propylene oxide and methanol. It is a speciality solvent having a bi-functional nature (ether-alcohol). It is a clear liquid with an ether-like odour. Dipropylene glycol methyl ether is not flammable, but a combustible liquid with a flashpoint of 1670 F/750C. Typically, the concentration of Dipropylene glycol methyl ether is 99%; 2-Methoxypropanol-1 can be present as an impurity at max. 0.1%. Dipropylene glycol methyl ether is not classified as a carcinogen or mutagen; it is not expected to cause cancer in humans, nor does it impair fertility or damage the developing fetus. Dipropylene glycol methyl ether is transported by tank truck, rail car and vessel, primarily in bulk quantities, but also as a packed product. It is not classified as hazardous for transport under transport regulations.Dipropylene glycol methyl ether at any exposure concentration in either male or female rats or rabbits. The highest concentration tested (200 ppm) was approximately 40% of a saturated Dipropylene glycol methyl ether atmosphere, Based on the low vapor pressure of Dipropylene glycol methyl ether, and results in this 13-week study, Dipropylene glycol methyl ether appears to have a low subchronic vapor inhalation toxicity hazard.Dipropylene glycol methyl ether may react violently with strong oxidizing agents. May generate flammable and/or toxic gases with alkali metals, nitrides, and other strong reducing agents. May initiate the polymerization of isocyanates and epoxides.The invention discloses a method for preparing Dipropylene glycol methyl ether. The method for preparing the Dipropylene glycol methyl ether is characterized by comprising the following steps of taking tower bottoms left after propylene glycol methyl ether is extracted as raw materials, performing a ring-opening addition reaction on the raw materials and epoxypropane in the presence of a strongly basic catalyst, recovering excessive 2-methoxy-1-propyl alcohol in the synthetic products by virtue of rectification and then separating to obtain the product Dipropylene glycol methyl ether. The method for preparing the Dipropylene glycol methyl ether has the advantages that as15-25% of Dipropylene glycol methyl ether continues reacting with the epoxypropane to generate tripropylene glycol methyl ether which is higher in boiling point in the process of synthesizing the Dipropylene glycol methyl ether by reacting the tower bottoms and the epoxypropane, enough output of the tripropylene glycol methyl ether is guaranteed by use of the synthesis method, and the tripropylene glycol methyl ether is capable of continuing dissolving catalysts such as sodium methylate and sodium hydroxide so that the sodium methylate can be prevented from being decomposed to generate methanol as being heated under the circumstance of a relatively high concentration, and therefore, the potential hazard that the methanol is possible to be in an explosion range after being mixed with air and explodes under high heat can be avoided.The present invention relates to a kind of method of preparing Dipropylene glycol methyl ether, belong to organic solvent preparation field.1. a method of preparing Dipropylene glycol methyl ether, it is characterized in that: the tower bottoms having extracted after propylene glycol monomethyl ether of take is raw material, under the effect of strong alkali catalyst, carry out opening with propylene oxide, by rectifying, reclaim out after 2-methoxy-1-propanol excessive in synthetic product, then separation obtains product Dipropylene glycol methyl ether.CALL FOR MEDICAL AID. LIQUID: Irritating to skin and eyes. Harmful if swallowed. Remove contaminated clothing and shoes. Flush affected areas with plenty of water. IF IN EYES, hold eyelids open and flush with plenty of water. May be harmful by inhalation, ingestion, or skin absorption. May cause irritation.Eye: If this chemical contacts the eyes, immediately wash the eyes with large amounts of water, occasionally lifting the lower and upper lids. Get medical attention immediately. Contact lenses should not be worn when working with this chemical. Skin: If this chemical contacts the skin, promptly wash the contaminated skin with water. If this chemical penetrates the clothing, promptly remove the clothing and wash the skin with water. If irritation persists after washing, get medical attention. Breathing: If a person breathes large amounts of this chemical, move the exposed person to fresh air at once. If breathing has stopped, perform mouth-to-mouth resuscitation. Keep the affected person warm and at rest. Get medical attention as soon as possible. Swallow: If this chemical has been swallowed, get medical attention immediately.Eye:Irrigate immediately - If this chemical contacts the eyes, immediately wash (irrigate) the eyes with large amounts of water, occasionally lifting the lower and upper lids. Get medical attention immediately.Skin:Water wash promptly - If this chemical contacts the skin, promptly wash the contaminated skin with water. If this chemical penetrates the clothing, promptly remove the clothing and wash the skin with water. If irritation persists after washing, get medical attention.Breathing:Respiratory support.Swallow:Medical attention immediately - If this chemical has been swallowed, get medical attention immediately.Stop discharge if possible. Call fire department. Avoid contact with liquid. Isolate and remove discharged material. Notify local health and pollution control agencies. Evacuate areas. Should be removed. Chemical and physical treatment. Effect of low concentrations on aquatic life is unknown. May be dangerous if it enters water intakes. Notify local health and wildlife officials. Notify operators of nearby water intakes. Skin: No recommendation is made specifying the need for personal protective equipment for the body. Eyes: No recommendation is made specifying the need for eye protection. Wash skin: No recommendation is made specifying the need for washing the substance from the skin (either immediately or at the end of the work shift). Remove: No recommendation is made specifying the need for removing clothing that becomes wet or contaminated. Change: No recommendation is made specifying the need for the worker to change clothing after the work shift.Oxidizes readily in air to form unstable peroxides that may explode spontaneously [Bretherick, 1979 p.151-154, 164]. Miscible with water.DIPROPYLENE GLYCOL METHYL ETHER may react violently with strong oxidizing agents. May generate flammable and/or toxic gases with alkali metals, nitrides, and other strong reducing agents. May initiate the polymerization of isocyanates and epoxides.inhalation, skin absorption, ingestion, skin and/or eye contactirritation eyes, nose, throat; lassitude (weakness, exhaustion), dizziness, headache.Dipropylene glycol methyl ether (DPGME) is one of the most commonly used propylene glycol ethers in industry and is discussed in a recently published NEG/NIOSH document. (Ref. 5.1) DPGME is a collective term describing a mixture of structural isomers. In the past, OSHA has determined airborne concentrations based on a method validated by NIOSH (Ref. 5.2). The method specifies collection of the vapors on activated charcoal, desorption of the charcoal with carbon disulfide, and analysis by GC using flame ionization detection.An examination of the Backup Data Report for the NIOSH method (Ref. 5.3) revealed that the desorption efficiency was not constant, the desorption efficiency of the individual isomers of DPGME was not investigated, and the desorption efficiency from wet charcoal was not addressed.The reported desorption efficiency ranged from 60.4% at 2.954 mg to 89.1% at 12.01 mg of DPGME. In cases where the desorption efficiency is not constant, calculations to determine analyte concentrations are complicated through the use of a desorption efficiency curve. Also, a desorption efficiency less than 75% does not meet one of the evaluation requirements used by the Organic Methods Evaluation Branch of the OSHA Salt Lake Technical Center (SLTC).For analytes such as DPGME, which are comprised as mixtures of related compounds, quantitation is accomplished by summing the peak areas of each component and treating the summed areas as one analyte. This is an accepted and convenient practice when using a flame ionization detector because the responses for all of the isomers of DPGME are identical. But if the desorption efficiencies are not the same for each isomer, they must be quantitated separately with individual desorption efficiency corrections, and then the resulting amounts are summed to determine the total amount of DPGME. This procedure is necessary for any method using charcoal collection and carbon disulfide desorption because the relative proportion of isomers in DPGME can vary by lot and manufacturer.Because charcoal will always collect some water from sampled air, the desorption of DPGME from wet charcoal is an important consideration as evidenced by evaluations done at SLTC for other chemically similar analytes. (Refs. 5.4-5.5) For those analytes, the recovery from wet charcoal is significantly lower unless a drying agent such as magnesium sulfate is used in the desorption step.The present evaluation was accomplished using a desorption solvent consisting of 95/5 (v/v) methylene chloride/methanol, which is used for other chemically similar compounds evaluated at SLTC. (Refs. 5.4-5.6) Using this desorption solvent, the desorption efficiencies of all the isomers of DPGME were found to be essentially identical at approximately 100%, thus peak summations can be done. The desorption efficiencies are constant with concentration and are not affected by the presence of water, so a drying agent is not needed for the desorption step.The use of 99/1 (v/v) carbon disulfide/N,N-dimethylformamide (CS2/DMF) was investigated as an alternative desorption solvent because it is used for the analysis of many solvent vapors collected on charcoal and analyzed at SLTC. The desorption efficiencies from dry charcoal ranged from 76-93% for the isomers at a loading of 6.0 mg of DPGME. When tests were repeated with charcoal that previously had 10 L of 80% relative humidity air drawn through it, the desorption efficiencies ranged from 52-86%. Reanalysis of these samples after addition of 125 mg of magnesium sulfate brought the efficiencies nearly up to that from dry charcoal. Thus this solvent system would be acceptable if each of the isomers was quantitated separately with its appropriate desorption efficiency correction, but it is clearly not the desorption solvent of choice.In the review presented in the previously mentioned NEG/NIOSH document, it was concluded that DPGME seems to lack reproductive toxicity, unlike some other chemically similar compounds. At very high air concentrations, DPGME causes narcosis in animals. It is expected that severe exposure would produce similar effects in humans, but high concentrations are disagreeable and not tolerated. Also, concentrations over 200 ppm (40% saturated atmosphere) are difficult to attain, which suggests these high concentrations would not likely be found in workplace air. DPGME at 300 ppm caused eye and nasal irritation to humans. There was no evidence of skin irritation from prolonged or repeated contact with the pure liquid. High vapor concentrations or direct contact of the eyes with the liquid causes transient irritation. (Ref. 5.7) The OSHA PEL-TWA is 100 ppm. (Ref. 5.8) ACGIH has established a TLV-TWA of 100 ppm and a TLV-STEL of 150 ppm for DPGME. (Ref. 5.9)DPGME is used as a solvent for paints, lacquers, resins, dyes, oil/greases, cleaners and cellulose and as a heat-transfer agent. It is frequently used as a substitute for the more toxic DEGME (diethylene glycol methyl ether).DPGME is a mixture of structural isomers. Also, each isomer has two asymmetrical carbon atoms, thus configurational isomers can exist. The numbers in parentheses are approximate percentages by weight of each isomer found in the DPGME used in this evaluation. The abbreviations in the brackets are used in chromatograms in this method.The analyte air concentrations throughout this method are based on the recommended sampling and analytical parameters. Air concentrations listed in ppm and ppb are referenced to 25°C and 101.3 kPa (760 mmHg).The DPGME concentration for samples is obtained from the appropriate calibration curve in terms of micrograms of analyte per sample, uncorrected for desorption efficiency. The air concentration is calculated using the following formulae. The back (50-mg) section is analyzed primarily to determine if there was any breakthrough from the front (100-mg) section during sampling. If a significant amount of analyte is found on the back section (e.g., greater than 25% of the amount found on the front section), this fact should be reported with sample results. If any analyte is found on the back section, it is added to the amount found on the front section. This total amount is then corrected by subtracting the total amount (if any) found on the blank.Dipropylene Glycol Methyl Ether (DPGME) is a mixture of four isomers. DPGME exhibits low acute toxicity by the oral, dermal, and inhalation routes. The oral LD50 ranges 5180-5400 mg/kg b.w. in rats to 7500 mg/kg b.w. in dogs. Dermal LD50 values were reported to range from 9500 to >19000 mg/kg b.w. in rabbits. Acute inhalation exposures to 500 ppm (3000 mg/m 3 , highest attainable concentration) DPGME produced no lethality and mild, but reversible narcosis in rats. In animal and human studies, DPGME is neither a skin sensitizer nor a skin irritant, and was only slightly irritating to the eye. In repeated dose inhalation studies, NOAELs of >50 ppm to 200 ppm (> 303 mg/m3 to 1212 mg/m3 ) have been observed using rats, mice, rabbits, guinea pigs, and monkeys. Effects observed at higher dose levels (1818 mg/m3 to 2424 mg/m3 ; 300 – 400 ppm) showed signs of central nervous system depression and adaptive liver changes. In rats exposed to up to 1000 mg/kg-day DPGME via gavage for 4 weeks, tentative salivation (immediately after dosing) and adaptive liver changes were observed in animals exposed to the highest dose. No effects were observed in rats exposed to 200 mg/kg-day. Studies in rats and rabbits showed that DPGME is not teratogenic (two inhalation studies with NOAELs of 1818 mg/m3 ; 300 ppm). It should be noted that the beta isomer of PGME is known developmental toxicant. This isomer is unlikely to be a metabolite of DPGME. The available data indicate that DPGME is not genotoxic. Information collected for a structurally similar chemical (PGME) suggests that DPGME is not a reproductive toxicant, and is not carcinogenic. Additionally, no effects were seen on the testes and ovaries in a 90-day repeat dose inhalation toxicity study on DPGME.DPGME is not persistent in the environment and is not expected to bioaccumulate in food webs. DPGME has a water solubility value of 1000 mg/L, a vapor pressure of 0.37 hPa and a log Kow of 0.0061. The half-life of DPGME in air was measured at 5.3 hours and is estimated to be 3.4 hours due to direct reactions with photochemically generated hydroxyl radicals. DPGME is readily biodegraded under aerobic conditions, but only slightly degraded under anaerobic conditions. Although environmental monitoring data are not available for DPGME, fugacity-based modelling indicates that DPGME is likely to partition to water compartments in the environment (surface water, groundwater). Acute toxicity testing in fish, invertebrates, and algae indicate a low order of toxicity with effect concentrations exceeding 1000 mg/L. Applying an uncertainty factor of 100 to the 48- hour LC50 value of 1919 mg/L for Daphnia, a PNEC of 19 mg/L was derived. DPGME is a mixture of four isomers. According to the manufacturers specification, (BUA Reports 173 and 174: Methoxypropanol (propylene glycol methyl ether), Dipropylene glycol ethyl ether. GDCh-Advisory Committee on Existing Chemicals of Environmental Relevance), the respective fractions of the structural isomers are 40-50% 1-(2-methoxypropoxy)propanol-2 (CASRN: 13429-07-7), 40-45% 1 -(2-methoxy-1-methylethoxy)propanol-2 (CASRN: 20324-32-7), 2-5% 2-(2-methoxypropoxy)propanol-1 (CASRN: 13588-28-8), and 3-5% 2-(2-methoxy-1- methylethoxy)propanol-1 (CASRN: 55956-21-3). Commercial DPGME is produced only as a four-isomer mixture and hence all testing was conducted on the commercial mixture. The four individual isomers are not separated nor produced as individual chemicals. DPGME is widely used in industrial, commercial, automotive, and household cleaners. As such, inhalation and dermal exposures are likely for worker and consumer populations. In addition, indirect exposures via the environment (i.e., ingestion of surface water) are also possible. Each of these exposure scenarios is discussed below.Products containing DPGME generally contain levels between 1 and 10%, although some products may have levels that are as high as 50% (BUA, 1995). Consumer exposure to DPGME occurs through application of products including cleaning products, paints, and cosmetic agents as well as their residues in packaging (e.g. in packaging). A temporary accumulation of DPGME can occur in closed rooms through the use of DPGME in water-based ceiling and wall paint. In one study, 15 workplace measurements conducted during painting, DPGME concentrations of 30-40 mg/m3 (5-7ppm) were measured in the air.Although tests on commercial PGME have indicated a low potential for toxicity the pure beta isomer of PGME (present at levels £ 0.5% in commerical PGME) has produced developmental effects in animals (BASF, 1988; Hellwig et al., 1994). Unlike the alpha PGME isomer, the beta PGME isomer is an excellent substrate for alcohol/aldehyde dehydrogenases and is oxidized primarily to 2-methoxypropionic acid (2- MPA) (Miller et al., 1986). It is this alkoxyacid metabolite that is the likely mediator of developmental toxicity (Carney et al., 2000). DPGME differs from PGME in that it does not contain beta isomer and hence the formation of the primary alcohol, beta PGME, from DPGME is dependent upon the potential to hydrolyze the central ether linkage in certain isomers of DPGME. Only two of the 4 DPGME isomers have the potential to be hydrolyzed to beta PGME. If one assumes that 100% cleavage of the ether bridge occurs, only 0.6 mmol of 2-MPA can be theoretically produced for every mmol of DPGME. Although DPGME has not been studied directly for the ability to produce beta PGME, a pharmacokinetic study with a structurally similar dipropylene glycol ether, dipropylene glycol dimethyl ether (DPGDME) showed a very low potential for cleavage of the glycol ether backbone with only 4.3% of the theoretical maximum of 2-MPA recovered at low doses and 13% of the theoretical maximum at higher doses (Mendrala et al., 1993). In an in vitro liver slice metabolism assay used to investigate the formation of 2-MPA from six propylene glycol ethers including beta PGME and DPGDME, none of the di- or triether substrates evaluated were metabolized to 2- MPA as effectively as beta-PGME. The in vitro formation of 2-MPA from beta PGME ranged from 3-170- fold higher than from any of the diethers tested (Pottenger et al., 1995). The in vivo metabolism study with DPGME taken together with the in vivo and in vitro studies with structurally analogous diglycol ethers indicate that hydrolysis of the central ether linkage to form the primary alcoholbeta PGME and subsequent hydrolysis to the alkoxyacid metabolite is a minor metabolic pathway for DPGME. This minor pathway is likely to result in levels of MPA that are well below the levels that produce toxicologically significant effects even at high doses of DPGME. Although tests on commercial DPGME and PGME have been negative in developmental studies the pure beta isomer of PGME (present at levels £ 0.5% in commerical PGME) has produced developmental effects in animals (BASF, 1988; Hellwig et al., 1994). Unlike the alpha PGME isomer, the beta PGME isomer is an excellent substrate for alcohol/aldehyde dehydrogenases and is oxidized primarily to 2-methoxypropionic acid (2-MPA) (Miller et al., 1986). It is this alkoxyacid metabolite that is the likely mediator of developmental toxicity (Carney et al., 2000). DPGME differs from PGME in that it does not contain beta isomer thus the formation of the primary alcohol, beta PGME, from DPGME is dependent upon the potential to hydrolyze the central ether linkage in certain isomers of DPGME. Only two of the 4 DPGME isomers have the potential be hydrolyzed to beta PGME. In vivo and in vitro studies provide support that significant cleavage of the dipropylene glycol backbone does not occur (Mendrala et al., 1993; Pottenger et al., 1995) precluding the formation of levels of beta PGME capable of producing toxicologically significant effects even at very high doses of DPGME. The low potential to generate the beta PGME isomer taken together with negative results in developmental toxicity studies in multiple species indicate it is unlikely that DPGME would be teratogenic of fetoxic by oral ingestion or inhalation.Commercial Dipropylene Glycol Methyl Ether (DPGME) is a mixture of four isomers. DPGME exhibits low acute toxicity by the oral, dermal, and inhalation routes. The oral LD50 ranges 5180-5400 mg/kg in rats to 7500 mg/kg in dogs. Dermal LD50 values were reported to range from 9500 to >19000 mg/kg in rabbits. Acute inhalation exposures to 500 ppm DPGME produced mild, but reversible narcosis in rats. DPGME is not a skin sensitizer or skin irritant, and was only slightly irritating to the eye. In repeated dose studies, NOAELs of >50 ppm to 3000 ppm have been observed in inhalation studies using rats, mice, rabbits, guinea pigs, and monkeys. Observations included central nervous system (CNS) effects, adaptive hepatic changes, and decreases in body weight gain. In rats exposed to either 0, 40, 200, or 1000 mg/kg-day DPGME via gavage for 4 weeks, tentative salivation (immediately after dosing) and liver effects (increased relative liver weight, centrilobular hypertrophy) was observed in animals exposed to the highest dose. No effects were observed in rats exposed to 200 mg/kg-day. Studies in rats and rabbits showed that DPGME is not teratogenic (two inhalation studies with NOAELs of 300 ppm). The weight of the evidence indicates that DPGME is not genotoxic. Information collected for a structurally similar chemical (PGME) suggests that DPGME is not a reproductive toxicant, and is not carcinogenic. Additionally, no effects were seen on the testes and ovaries in a 28-day repeat dose oral toxicity study on DPGME. In humans, concentrations of 35-75 ppm may be expected to produce irritation to the eyes, nose, throat, and respiratory tract. Therefore, human exposures to concentrations of DPGME greater than 75 ppm are expected to be self-limiting.DPGME is not persistent in the environment and is not expected to bioaccumulate in food webs. The half-life of DPGME in air was measured at 5.3 hours and is estimated to be 3.4 hours due to direct reactions with photochemically generated hydroxyl radicals. DPGME is readily biodegraded under aerobic conditions, but only slightly degraded under anaerobic conditions. Although environmental monitoring data are not available for DPGME, fugacity-based modeling indicates that PGME is likely to partition to water compartments in the environment (surface water, groundwater). Acute toxicity testing in fish, invertebrates and algae indicate a very low order of toxicity with effect concentrations exceeding 1000 mg/L. A PNEC of 19 mg/L was derived by applying an uncertainty factor of 100 to the 48-hour LC50 value of 1919 mg/L for daphnids.Approximately 38 million pounds (17 thousand tons) of DPGME were produced in the U.S. in 1999 (Appendix A). Approximately 12,000 tons of DPGME were consumed in the U.S. in 1995 (Staples and Davis, 2001). Production in the U.S. was estimated at 35 million pounds (16 thousand tons) for 2000 (Chemical Economics Handbook on Glycol Ethers (1996), SRI International). DPGME occurred in 123 products present on the Swedish market in July 1989. DPGME is used in the manufacture of a wide variety of industrial and commercial products, including paints, varnishes, inks, and cleaners. In the US in 1999, DPGME was used as follows: 58% paints/coatings/inks, 28% cleaners, 10% DPGME acetate production and 3% miscellaneous production. Exposures to DPGME are likely to occur for workers and consumers. Inhalation exposures to relatively high concentrations of DPGME are believed to be self-limiting due to the irritant effects of the chemical. Use of protective gloves to minimize absorption is recommended when prolonged dermal exposures to DPGME are anticipated.

Methoxy Propoxy Propanol; DPG; Dipropylene Glycol Methyl Ether; Methoxypropoxypropanol; Mixture of Methyldipropylene glycol; Oxybispropanol, Methyl Ether; Bis-(2-Methoxypropyl) ether cas no:34590-94-8

DIPROPYLENE GLYCOL; Oxybispropanol; Di-sec-alcohol; Bis(2-hydroxy-propyl)ether; CAS NO: 25265-71-8

dipropylene triamine 1,3-propanediamine, N1-(3-aminopropyl); imino-bis (3-propylamine); 1- propanamine, 3,3'-iminobis- cas no:56-18-8

DISODIUM 2-SULFOLAURATE, N° CAS : 38841-48-4, Nom INCI : DISODIUM 2-SULFOLAURATE, Nom chimique : Disodium 2-sulfododecanoate. Ses fonctions (INCI) : Agent nettoyant : Aide à garder une surface propre. Tensioactif : Réduit la tension superficielle des cosmétiques et contribue à la répartition uniforme du produit lors de son utilisation

Disflamoll 51036 — это огнестойкая смесь фосфатного эфира низкой вязкости со следующими преимуществами в гибком ПВХ: очень хорошая пластифицирующая эффективность, быстрое гелеобразование и хорошая гибкость при низких температурах.
Disflamoll 51036 рекомендуется для использования в гибких ПВХ-приложениях, особенно для искусственной кожи, когда требуется огнестойкость в сочетании с хорошими низкотемпературными характеристиками.

Disflamoll 51036 — это препарат фосфатного эфира.

CAS: 26444-49-5
MF: C19H17O4P
MW: 340,31
EINECS: 247-693-8

Синонимы
Крезилдифенилфосфат (так называемый) (смесь аналогов); Zinc02041271; Дифенилтолилфосфат - Смесь о-, м-, п-толиловых изомеров; Дифенилметилфенилфосфат, Смесь изомеров, 94%; 2-метилфенилдифенилфосфат; Крезилфенилфосфат; Крезилдифенилфосфат (смешанные изомеры cdp); Дифенилтолиловый эфир фосфорной кислоты

Действует как пластификатор фосфатного эфира с низкой вязкостью, быстро образующий гель в гибком ПВХ и обладающий хорошей гибкостью при низких температурах.
Disflamoll 51036 также действует как антипирен.
Совместим с ПВХ.
Disflamoll 51036 имеет минимальный срок хранения 1 год.
Вероятно, редко является чистым соединением, но представляет собой смесь о-, м- и п-крезил- и фенилфосфатов.
Прозрачная прозрачная жидкость с очень слабым запахом.
Нерастворим в воде.
Основная опасность — для окружающей среды.
Необходимо принять немедленные меры для ограничения распространения в окружающую среду.
Легко проникает в почву, загрязняя грунтовые воды и близлежащие водоемы.

Химические свойства Disflamoll 51036
Точка плавления: -38 °C
Точка кипения: 235-255 °C
Плотность: 1,20
Fp: 232 °C
Показатель преломления: 1,5630
Температура хранения: Запечатано в сухом месте, Комнатная температура
Форма: Жидкость
Удельный вес: 1,21
Цвет: Бледно-желтый
InChIKey: OJUZRFGUKHQNJX-UHFFFAOYSA-N
LogP: 4,510
Ссылка на базу данных CAS: 26444-49-5 (Ссылка на базу данных CAS)
Ссылка на химию NIST: Disflamoll 51036 (26444-49-5)
Система реестра веществ EPA: Disflamoll 51036 (26444-49-5)

Применение
Пластификатор, смазка для экстремальных давлений, гидравлические жидкости, присадка к бензину, пищевая упаковка.

Опасность для здоровья
Вдыхание материала может быть вредным.
Контакт может вызвать ожоги кожи и глаз.
Вдыхание асбестовой пыли может оказать вредное воздействие на легкие.
Пожар может выделять раздражающие, едкие и/или токсичные газы.
Некоторые жидкости выделяют пары, которые могут вызвать головокружение или удушье.
Стоки от пожаротушения могут вызвать загрязнение.