107797-27-3

Usage

Uses

Used in the Food and Beverage Industry:
(S)-γ-Decalactone is used as a flavoring agent for imparting peach, apricot, and coconut flavors to different products. Its fruity aroma makes it a popular choice in the creation of a wide range of food and beverage items.
Used in the Fragrance Industry:
(S)-γ-Decalactone is used as a key component in the production of perfumes and other scented products. Its versatile and appealing aroma contributes to the overall sensory experience of these products, making it a valuable addition to the fragrance industry.

Upstream product

• 706-14-9 5-hexyldihydro-2(3H)-furanone 
• 259675-58-6 4-hydroxy-decanoic acid benzylamide 
• 17369-51-6 4-hydroxydecanoic acid 
• 7011-82-7 methyl 4-oxodecanoate 
• 37810-94-9 decane-1,4-diol 
• 115352-51-7 (R_S)-t-butyl-5-(4-methylphenyl)sulphinyl-4-oxo-decanoate 
• 115405-24-8 (4R,5S,R_S)-t-butyl-5-(4-methylphenyl)sulphinyl decanoate 
• 115352-59-5 (4R,5S)-t-butyl 4-hydroxy-5-(4-methylphenyl)thio decanoate 
• 115352-50-6 (+)-(R)-n-hexyl-p-tolyl-sulphoxide 
• 638-45-9 1-Iodohexane 
• 107736-51-6 (E)-(S)-4-Acetoxy-dec-2-enoic acid ethyl ester 
• 107736-31-2 2-Diazo-1-((2S,3R)-3-hexyl-oxiranyl)-ethanone 
• 107797-23-9 (E)-(S)-4-Hydroxy-dec-2-enoic acid ethyl ester 
• 107796-93-0 [(2R,3R)-3-hexyloxiran-2-yl]methanol 

Relevant academic research and scientific papers

Stereoselective synthesis of chiral δ-lactonesviaan engineered carbonyl reductase

A carbonyl reductase variant,SmCRM5, fromSerratia marcescenswas obtained through structure-guided directed evolution. The variant showed improved specific activity (U mg?1) towards most of the 16 tested substrates and gave high stereoselectivities of up to 99% in the asymmetric synthesis of 13 γ-/δ-lactones. In particular, SmCRM5showed a 13.8-fold higher specific activity towards the model substrate,i.e., 5-oxodecanoic acid, and gave (R)-δ-decalactone in 99% ee with a space-time yield (STY) of 301 g L?1d?1. The preparative synthesis of six δ-lactones in high yields and with high enantiopurities showed the feasibility of the biocatalytic synthesis of these high-value-added chemicals, providing a cost-effective and green alternative to noble-metal catalysis.

MODIFIED AMINE LIPIDS

The disclosure provides ionizable amine lipids and salts thereof (e.g., pharmaceutically acceptable salts thereof) useful for the delivery of biologically active agents, for example delivering biologically active agents to cells to prepare engineered cells. The ionizable amine lipids disclosed herein are useful as ionizable lipids in the formulation of lipid nanoparticle-based compositions.

A synthetic method of chiral gamma-decalactone

A synthetic method of chiral gamma-decalactone is provided. The method includes steps of (1) adding concentrated sulfuric acid into an organic solvent, then adding a catalyst, a ligand and a phase-transfer catalyst into the mixture, finally adding methyl 4-carbonyldecanoate into the mixture, and reacting the mixture; (2) transferring a reaction product obtained in the step (1) into an autoclave, and filling the autoclave with hydrogen to pressurize the autoclave to 3-6 MPa, with the reaction temperature being 60-120 DEG C and reaction time being 4-8 h; and (3) subjecting a reaction product obtained in the step (2) to neutralization, filtration, solvent recovery and distillation to obtain the chiral gamma-decalactone. The reaction temperature and pressure of the method are proper, and production operation is easy so that the method can be used for industrial production. The ee value of the product can be 95% or above.

Simple Preparation of Rhodococcus erythropolis DSM 44534 as Biocatalyst to Oxidize Diols into the Optically Active Lactones

In the current study, we present a green toolbox to produce ecological compounds like lactone moiety. Rhodococcus erythropolis DSM 44534 cells have been used to oxidize both decane-1,4-diol (2a) and decane-1,5-diol (3a) into the corresponding γ- (2b) and δ-decalactones (3b) with yield of 80% and enantiomeric excess (ee)?=?75% and ee?=?90%, respectively. Among oxidation of meso diols, (?)-(1S,5R)-cis-3-oxabicyclo[4.3.0]non-7-en-2-one (5a) with 56% yield and ee?=?76% as well as (?)-(2R,3S)-cis-endo-3-oxabicyclo[2.2.1]dec-7-en-2-one (6a) with 100% yield and ee?=?90% were formed. It is worth mentioning that R. erythropolis DSM 44534 grew in a mineral medium containing ethanol as the sole source of energy and carbon Chirality 28:623–627, 2016.

Chemo-enzymatic synthesis of optically active γ- and δ-decalactones and their effect on aphid probing, feeding and settling behavior

The enantiomerically enriched γ- and δ-decalactones (4a and 4b) were prepared from corresponding racemic primary-secondary 1,4- and 1,5-diols (1a and 1b), as products of enzymatic oxidation catalyzed by different alcohol dehydrogenases. The results of biotransformations indicated that the oxidation processes catalyzed by alcohol dehydrogenase (HLADH), both isolated from horse liver and recombinant in Escherichia coli, were characterized by the highest degree of conversion with moderate enantioselectivity of the reaction. Useful, environmentally friendly extraction procedure of decalactones (4a and 4b) based on hydrodistillation using a Deryng apparatus was developed. Both racemic lactones (4a and 4b), as well as their enantiomerically enriched isomers, were tested for feeding deterrent activity against Myzus persicae. The effect of these compounds on probing, feeding and settling behavior of M. persicae was studied in vivo. The deterrent activity of decalactones (4a and 4b) against aphids depended on the size of the lactone ring and the enantiomeric purity of the compounds. δ-Decalactone (4b) appeared inactive againstM. persicae while γ-decalactone (4a) restrained aphid probing at ingestional phase. Only (-)-(S)-γ-decalactone (4a) had strong and durable (i.e. lasting for at least 24 hours) limiting effect, expressed at phloem level.

Cyclodextrin-based ionic liquids as enantioselective stationary phases in gas chromatography

New permethylated mono-6-deoxy-6-pyridin-1-ium and mono-6-deoxy-6-(1-vinyl- 1H-imidazol-3-ium)-α- and -β-cyclodextrin trifluoromethanesulfonate ionic liquids were synthesized from the corresponding permethylated mono-6-hydroxycyclodextrins in a one-pot reaction and solvent-free procedure. Regioselective transformation of native α- and β-cyclodextrins with the use of a bulky tert-butyldiphenylsilyl protecting group afforded the desired 6-monosubstituted permethylated cyclodextrin derivatives in moderate yields. The new ionic liquids were tested as stationary phases in capillary GC columns towards chiral discrimination in enantio-GC analysis of racemic mixtures. The permethylated 6-deoxy-6-pyridin-1-ium-α-cyclodextrin trifluoromethanesulfonate displayed good enantiomeric separations for some racemic esters and lactones, as well as epoxides. In particular, for both the racemic whiskey lactone and the high boiling point menthyl laurate, not successfully separated in a commercial cyclodextrin phase, the enantiomeric separations were achieved isothermally at 140 °C. In phase: Permethylated mono-6-hydroxy-α- and -β-cyclodextrins react with pyridine or 1-vinylimidazole in the presence of triflic anhydride in a solvent-free procedure to yield new roomerature ionic liquids (ILs). These ILs have been used as stationary phases in gas chromatography; enantiomeric separations are achieved (see figure for whiskey lactone) with permethylated mono-6-deoxy-6-(pyridin-1-ium)-α-cyclodextrin trifluoromethanesulfonate. Copyright

Biocatalytic oxidation of 1,4-diols and γ-lactols into γ-lactones: Application to chemoenzymatic synthesis of drospirenone

Oxidation of 1-alkyl-1,4-butanediols with Acetobacter aceti MIM 2000/28 gave the corresponding γ-lactones in good yields. The biotransformation occurred with intermediate formation of γ-lactols, which are also substrates for oxidation with Acetobacter aceti MIM 2000/28, as validated by selective biotransformation of 6β,7β;15β,16β-dimethylene-3- oxo-17α-pregn-4-en-21,17-carbolactol to drospirenone.

Combination of novozym 435-catalyzed hydrolysis and mitsunobu reaction for production of (r)γ-lactones

Chiral-lactones of both enantiomers were synthesized with more than 90% optical purities. The key step was Novozym 435-catalyzed hydrolysis of racemic N-benzyl-4-acetoxyalkylamides. Additionally, because (R)-γ-lactones are predominant in apricot, mango, peach, passion fruit, and strawberry, synthesis was attempted using only one enantiomer selectively. The (R)-enantimer was synthesized with more than 80% total yield and more than 90% optical purity by a combination of Novozym 435-catalyzed hydrolysis and the Mitsunobu reaction. Copyright

Synthesis of (S)-γ- lactones with a combination of lipase-catalyzed resolution and mitsunobu reaction

Six kinds of (S) - lactones [e.g., (S) - decalactone, (S) - undecalactone, and (S) - jasmolactone] were synthesized with 71-88% yields and 97% optical purities by combining lipase-catalyzed resolution with the Mitsunobu reaction. Copyright Taylor & Francis Group, LLC.

Enantiomeric specificity in a pheromone-kairomone system of two threatened saproxylic beetles, Osmoderma eremita and Elater ferrugineus

The scarab beetle Osmoderma eremita and its larval predator, the click beetle Elater ferrugineus, are threatened saproxylic beetles regarded as indicators of the species-richness of insect fauna of hollow deciduous trees. Male O. eremita produce the pheromone (R)-(+)-γ-decalactone to attract conspecific females, and this compound is also utilized by E. ferrugineus as a kairomone, presumably for detection of tree hollows containing prey. We have investigated enantiomeric specificity to γ-decalactone in this pheromone-kairomone system by electrophysiological and field trapping experiments. In single-sensillum recordings from male and female O. eremita, which used the (R)-enantiomer and the racemic mixture of γ-decalactone as odor stimuli, numerous olfactory receptor neurons (ORNs) responding to both stimuli were found. No neurons responded preferentially to the racemic mixture, showing that these beetles seem to lack receptors specific for the (S)-enantiomer. The enantiomeric specificity of ORNs was confirmed by gas chromatography-linked single-sensillum recordings where the two enantiomers in a racemic mixture were separated on a chiral column. Furthermore, in field experiments that used the (R)-enantiomer and the racemic mixture as lures, the attraction of O. eremita females corresponded to the amount of (R)-enantiomer released from lures with the (S)-enantiomer displaying no antagonistic effects. Trap catch data also suggested that the (S)-enantiomer is not a behavioral antagonist for E. ferrugineus. The odor-based system can be highly efficient in attracting the larval predator where trap catch in 1 yr almost equaled the total number of specimens collected in Sweden until 1993. Our study shows that racemic γ-decalactone could be used for cost-effective monitoring of both beetles.