36377-33-0

Basic information

• Product Name: 12-HYDROXYSTEARIC ACID
• Synonyms: (+/-)-12-HYDROXYOCTADECANOIC ACID;12-HYDROXYOCTADECANOIC ACID;12-HYDROXYSTEARIC ACID;dl-12HSA;rac-(12R*)-12-Hydroxystearic acid;DL-12-HYDROXYOCTADECANOIC ACID;DL-12-HYDROXYSTEARIC ACID;LEMOSOL COAGULANT
• CAS NO: 36377-33-0
• Molecular Formula: C₁₈H₃₆O₃
• Molecular Weight: 300.48
• EINECS: 203-366-1
• Mol File: 36377-33-0.mol

Chemical Properties

• Melting Point: 74-76 °C(lit.)
• Appearance: /
• Storage Temp.: −20°C
• Stability: Stable. Combustible. Incompatible with strong oxidizing agents.
• CAS DataBase Reference: 12-HYDROXYSTEARIC ACID(CAS DataBase Reference)
• NIST Chemistry Reference: 12-HYDROXYSTEARIC ACID(36377-33-0)
• EPA Substance Registry System: 12-HYDROXYSTEARIC ACID(36377-33-0)

Safety Data

• Hazard Codes: Xi
• Statements: 36/37/38
• Safety Statements: 26-36
• WGK Germany: 3
• RTECS: WI3850000
• Hazardous Substances Data: 36377-33-0(Hazardous Substances Data)

Usage

Uses

Used in Chemical Production:
12-Hydroxystearic acid is used as an intermediate for the production of various chemicals and products, such as lubricants, cosmetics, and plasticizers. Its unique polar properties contribute to the performance and quality of these products.
Used in Emulsification and Stabilization:
Due to its hydroxyl group, 12-Hydroxystearic acid is used as an emulsifier and stabilizer in various formulations. This helps to maintain the consistency and stability of products in different industries.
Used in Surfactant and Ester Production:
12-Hydroxystearic acid is used as a raw material in the production of surfactants and esters. Its unique properties make it an essential component in creating these compounds, which are used in a wide range of applications.
Used in Pharmaceutical Industry:
12-Hydroxystearic acid has potential uses in the pharmaceutical industry, where it can be utilized in the development of new drugs or as a component in existing formulations.
Used in Material Science:
As a building block for new materials with specialized properties, 12-Hydroxystearic acid is used in material science to create innovative products with unique characteristics and applications.

Upstream product

• 141-22-0 Ricinoleic acid 
• 6114-39-2 methyl (R)-12-hydroxyoctadecanoate 
• 65883-63-8 (R)-13-Hexyl-oxacyclotridecan-2-one 
• 64-17-5 ethanol 
• 7803-57-8 hydrazine hydrate 
• 638-45-9 1-Iodohexane 
• 1242434-02-1 12(R)-(3,4-di-O-diacetyl-β-D-glucopyranosyloxy)octadecanoic acid 1,2'-cyclic ester 

Downstream Products

• 61800-40-6 (R)-12-acetoxy-octadecanoic acid-((Ξ)-2-ethyl-hexyl ester) 
• 40445-72-5 (R)-12-hydroxy-octadecanoic acid cholesteryl ester 
• 18417-00-0 (12S)-12-hydroxyoctadecanoic acid 
• 706-14-9 5-hexyldihydro-2(3H)-furanone 
• 17369-51-6 4-hydroxydecanoic acid 
• 4144-54-1 4-oxodecanoic acid 
• 35875-13-9 6-hydroxydodecanoic acid 
• 111-14-8 oenanthic acid 
• 1852-04-6 undecanedioic acid 
• 693-23-2 1,12-dodecanedioic acid 
• 142-62-1 hexanoic acid 
• 883972-93-8 (E,2S,3S,4R,7R,8S,9S,12'R)-2,3,4,7,8,9-hexa(benzyloxy)-10-hydroxydec-5-enyl 12-hydroxystearate 
• 887624-16-0 (R)-12-Hydroxy-octadecanoic acid bis-((2R,3R,4S,5R,6S)-3,4,5-tris-benzyloxy-6-methoxy-tetrahydro-pyran-2-ylmethyl)-amide 
• 106-14-9 12-Hydroxystearic acid 

Relevant articles and documents

Chirality-controlled syntheses of double-helical Au nanowires

The selective large-scale syntheses of noble metal nanocrystals with complex shapes using wet-chemical approaches remain exciting challenges. Here we report the chirality-controllable syntheses of double-helical Au nanowires (NWs) using chiral soft-templates composed of two organogelators with their own active functions; one organogelator serves to introduce helicity into the template and the other acts as a capping agent to control the Au shape. One-dimensional twisted-nanoribbon templates are prepared simply by mixing the two organogelators in water containing a small amount of toluene, followed by the addition of LiCl; template chirality is controlled through the selection of the handedness of the helicity-inducing organogelator. Double-helical Au NWs synthesized on these chiral templates have the same helical structure as the template because the Au NWs grow along both edges of the twisted nanoribbons with right- or left-handed helicities. Dispersions of the right- and left-handed double-helical Au NWs exhibit opposite CD signals.

Cyclic fatty acyl glycosides in the glandular trichome exudate of Silene gallica

Chemical investigation of the glandular trichome exudate from Silene gallica L. (Caryophyllaceae) resulted in isolation of 10 cyclic fatty acyl glycosides (gallicasides A-J). The cyclic structures were characterized by a glycosidic linkage of the glucose moiety to either the C-12 or the C-13 position of the octadecanoyl moiety, and by an ester linkage between the C-2 hydroxy group of the glucose moiety and the carboxyl group of the oxygenated octadecanoic acid. The structures of the cyclic fatty acyl glycosides were further distinguished from one another by acetylation and/or malonylation on the glucose moiety. Of these compounds, the 1,2′-cyclic ester of 12(R)-(6-O-acetyl-3-O-malonyl-β-d-glucopyranosyloxy)octadecanoic acid (gallicaside J) was the most abundant (30.7%). These secondary metabolites were found specifically in the glandular trichome exudate rather than in other aerial parts.

Electroorganic synthesis 65. Anodic homocoupling of carboxylic acids derived from fatty acids

Fatty acid derived carboxylic acids with double bonds, hydroxy-, amino-, keto-, ester- and epoxy groups are anodically coupled to dimers (Kolbe electrolysis) in 29 to 81% yield and up to a 2.5 mol scale. Problems due to the low conductivity of fatty acid salts were overcome by the use of a flow cell with a narrow electrode gap. Fatty acids with branched alkyl chains gave dimers with interesting emulsifying properties. Dimethyl hexadecanedioate, accessible from methyl azelate, could be cyclized and further converted into homomuscone and muscone in a few steps. A commercial mixture of dimeric fatty acids (C36-dicarboxylic acids) has been coupled to give C70-diesters. Acta Chemica Scandinavica 1998. Part 64: Nielsen, M. F., Batanero, B.,.

Properties of unusual phospholipids. III: Synthesis, monolayer investigations and DSC studies of hydroxy octadeca(e)noic acids and diacylglycerophosphocholines derived therefrom

Diacylglycerophosphocholines containing (R)-3-, (R)-12-, (R)-17-hydroxy octadeca(e)noic acids and the corresponding racemates were synthesized and purified to homogeneity. The influence of the position of the hydroxy group on the monolayer packing properties of these fatty acids and their phosphatidylcholines was studied by Langmuir techniques and 1,2-di-[(R)-12-hydroxy-octadec-cis-9-enyl]-sn-glycero-3-phosphocholine displayed the largest lift-off area (330 A2/molecule). This result was in line with the thermotropic phase behavior of these phospholipids, as measured by differential scanning calorimetry (DSC): the gel- to liquid-crystalline phase transition temperature (T(m))passed through a minimum of -15.1°C for 1,2-di-[(R)-12-hydroxy-octadec-cis-9-enyl]-sn-glycero-3-phosphocholine.

An Asymmetric Synthesis of Acyclic and Macrocyclic α-Alkyl Ketones. The Role of (E)- and (Z)-Lithioenamines

Metalation and alkylation of chiral imines derived from C10, C12, and C15 cyclic ketones gave, under kinetic metalation conditions, 2-alkylcycloalkanones of absolute configuration opposite to that formed from thermodynamic metalation.Thus, (S)-(-)-2-methylcyclododecanone is formed kinetically in 60percent ee, whereas (R)-(+)-methylcyclododecanone is reached in 80percent ee under thermodynamic conditions.In a similar fashion, acyclic ketones 20, via their chiral imines 17, are alkylated enantioselectively under both kinetic and thermodynamic modes.The kinetic metalation gives exclusively the (Z)-lithioenamines (19), while reflux of this lithio anion gives only the (E)-lithioenamine (19).Chiral α-substituted ketones are produced in 18-97percent ee.