PREPARATION OF ω-BROMOALKAN-1-OLS FROM α,ω-ALKANEDIOLS BY THE CONTINUOUS EXTRACTION METHOD

Novel chemoenzymatic strategy for the synthesis of enantiomerically pure secondary alcohols with sterically similar substituents

A novel chemoenzymatic strategy for the synthesis of enantiomerically pure secondary alcohols with sterically similar substituents is described. The key step is the kinetic lipase-catalyzed resolution of racemic mixtures of substituted propargylic alcohols. The efficiency of this new approach was tested in the preparation of the corresponding enantiomers of 1,11-hexadecandiol derivatives ((R)-5 and (S)-5). Two strategies were tested. In the first one, the racemic intermediate 1-octyn-3-ol (1) was resolved enzymatically and then elongated with 1-bromo-9,11-dioxadodecane. Alternatively, the racemic 1 can be elongated to the corresponding racemic 17,19-dioxa-7-eicosyn-6-ol (3) first and then resolved biocatalytically. Twelve commercially available lipases were screened for the kinetic resolution of these intermediates. Among them, Candida antarctica lipase (CAL-B) and Humicola lanuginosa lipase (HLL) were the best biocatalysts for the resolution of 1 (S enantiomer 90% ee, E = 35), and 3 (R enantiomer 90% ee, E = 34), respectively.

Synthesis of dideuterated and enantiomers of monodeuterated tridecanoic acids at C-9 and C-10 positions

We report a route for the preparation of mono and dideuterated tridecanoic acids: (R)-[9-(2)H(1)]-, (S)-[9-(2)H(1)]-, (R)-[10-(2)H(1)]-, (S)-[10-(2)H(1)]-, [9,9-(2)H(2)]-, and [10, 10-(2)H(2)]-tridecanoic acids required as probes for biochemical studies on desaturases. The key intermediates in the synthesis of all these probes are ketones 9, which give rise to the corresponding alcohols 10 and 13 by reduction with LiAlD(4) and LiAlH(4), respectively. Derivatization of nondeuterated racemic alcohols 13 with (S)-(+)-9-anthranylmethoxyacetic acid ((S)-(+)-9-AMA) and chromatographic resolution of both diastereoisomers allowed us to determine the absolute configuration of the stereogenic centers by (1)H NMR using an adaptation of the model proposed by Riguera and co-workers which was validated with alcohols of known absolute configuration. Both enantiomeric alcohols (R)- and (S)-13 were recovered by reduction of each diastereomeric ester with LiAlH(4). Mesylation of alcohols 10 and 13 followed by nucleophilic substitution by LiAlD(4) generated the saturated methoxymethyl derivatives 12 and 16, respectively. Final deprotection and Jones oxidation of the resulting alcohols afforded the above deuterated tridecanoic acids.