10075-09-9

Upstream product

• 112-62-9 Methyl oleate 
• 91363-65-4 methyl 9-oxo-octadec-trans-10-enoate 
• 186581-53-3 diazomethane 
• 110657-92-6 (10E)-9-hydroxy-10-octadecenoic acid 
• 112-80-1 cis-Octadecenoic acid 
• 110551-46-7 trans-9-hydroperoxyoctadec-10-enoic acid 
• 1931-63-1 methyl ester of azelaic acid aldehyde 
• 95080-10-7 methyl 9-hydroxyoctadec-10-ynoate 
• 95080-11-8 9-Acetoxy-octadec-10-ynoic acid methyl ester 
• 2777-65-3 undec-10-ynoic acid 
• 629-04-9 1-Bromoheptane 
• 19220-39-4 octadec-10-ynoic acid 
• 26543-36-2 methyl octadec-10-ynoate 
• 17257-43-1 (Z)-methyl octadec-10-enoate 

Relevant academic research and scientific papers

A gas-liquid chromatographic method for steric analysis of 2-hydroxy, 3-hydroxy, and 2,3-dihydroxy acids

A method was developed for assignment of the absolute configuration of oxylipin-derived 2-hydroxy acids, 3-hydroxy acids and 2,3-dihydroxy acids.The monohydroxy acids were converted into diastereomeric N-(propionoxyacyl)-L-phenylalanine-methyl ester (PAP) derivatives by coupling to the methyl ester of L-phenylalanine followed by propionylation, whereas 2,3-dihydroxy acids were derivatized by treatment with L-phenylalanine methyl ester followed by acetone and perchloric acid, to afford diastereomeric N-(2,3-isopropylidenedioxyacyl)-L-phenylalanine methyl ester (IAP) derivatives.The PAP and IAP derivatives were readily resolved by capillary gas-liquid chromatography.In addition, the method described allowed steric analysis of 3-hydroxy-3-methylheptanoic acid, a branched chain hydroxy acid derived from the prostaglandin analogue, misoprostol. - Keywords: Hydroxy acid; Phenylalanine; Steric analysis; Gas-liquid chromatography

Algicidal hydroxylated C18 unsaturated fatty acids from the red alga Tricleocarpa jejuensis: Identification, synthesis and biological activity

Bioassay-guided separation of a methanol extract of Tricleocarpa jejuensis by monitoring algicidal activity against the red tide phytoplankton Chattonella antiqua led to the isolation of an active fraction consisting of a mixture of four isomeric compounds. The active compounds were identified as (E)-9-hydroxyoctadec-10-enoic acid (1), (E)-10-hydroxyoctadec-8-enoic acid (2), (E)-11-hydroxyoctadec-12-enoic acid (3) and (E)-12-hydroxyoctadec-10-enoic acid (4) by NMR, IR and mass spectral data. The structures were confirmed by comparison of the NMR and MS data with those of authentic samples of 1–4 obtained by unambiguous syntheses. Synthesized hydroxy acids 1–4 and related compounds were assessed for algicidal activity against C. antiqua and it was found that all of 1–4 had high activity (>80% mortality at 24 h) at a concentration of 20 μg/mL. A structure–activity relationship study using 11 related compounds revealed that the presence of the hydroxyl group is important for the activity and the double bond may be replaced with a triple bond.

Identification of (E)-11-hydroxy-9-octadecenoic acid and (E)-9-hydroxy-10-octadecenoic acid by biotransformation of Oleic acid by pseudomonas sp. 32T3

Pseudomonas sp. 32T3, a newly identified strain originally isolated from a vegetable oil-contaminated soil, produces three monohydroxy acids-(E)-11-hydroxy-9-octadecenoic acid, (E)-10-hydroxy-8-octadecenoic acid, and (E)-9-hydroxy-10-octadecenoic acid-as

A mechanistic study of oleate autoxidation: Competing peroxyl H-atom abstraction and rearrangement

The mechanism of methyl oleate autoxidation was investigated. HPLC techniques were developed to analyze the products of autoxidation (hydroperoxides and the corresponding alcohols). The alcohols could be completely resolved by normal-phase chromatography, six products being characterized having oxygen substitution and double position as follows: 11-OOH-trans-△9-10, 11-OOH-cis-△9-10, 10-OOH-trans-△8-9, 9-OOH-trans-10-11, 8-OOH-trans-△9-10, 8-OOH-cis-△9-10 As the hydrogen atom donor concentration of the medium of autoxidation is increased, increased 11-cis, 8-cis, 9-trans, and 10-trans hydroperoxides and decreased 11-trans and 8-trans hydroperoxides were obtained, consistent with a mechanism in which peroxyl H-atom abstraction and [2,3] allylperoxyl rearrangement are in competition, An iterative computer kinetic analysis was developed which modeled the oleate autoxidation mechanism, and. rearrangement rate constants were determined. Allylperoxyl radicals undergo rearrangement with different rates depending on the geometry of the allylperoxyl.

Stereochemistry of Olefin and Fatty Acid Oxidation. Part 3. The Allylic Hydroperoxides from the Autoxidation of Methyl Oleate

Methods have been developed, using 13C n.m.r. spectroscopy and mass spectrometry, for the analysis of all eight cis and trans allylic 8-, 9-, 10-, and 11-hydroperoxides formed on autoxidation of methyl oleate.

Synthesis of Cyclic Peroxides from Methyl Oleate

A mixture of -9(10)-hydroxyoctadec-10(8)-enoates (3a) and (3b), produced by the photosensitised oxidation of methyl oleate, is a suitable substrate for the synthesis of substituted dioxolanes.Peroxymercuriation of (3) followed by hydrogenodemercuriation affords 3-(6-methoxycarbonylhexyl)-5-octyl- and 5-heptyl-3-(7-methoxycarbonylheptyl)-1,2-dioxolanes (5a) and(5b) in good yield (45-70percent).Peroxymercuriation followed by bromodemercuriation yields the corresponding bromo substituted cyclic peroxides (epidioxides) (9a) and (9b) in higher yield (95percent).Direct bromination of the allylic hydroperoxides (3a) and (3b) affords the same bromo substituted cyclic peroxides (9a) and (9b) in almost quantitative yield, presumably via a bromonium ion intermediate.