Borohydride reduction, ketones enantioselective

Optically active /3-ketoiminato cobalt(III) compounds based on chiral substituted ethylenedi-amine find use as efficient catalysts for the enatioselective hetero Diels Alder reaction of both aryl and alkyl aldehydes with l-methoxy-(3-(t-butyldimethylsilyl)oxy)-1,3-butadiene.1381 Cobalt(II) compounds of the same class of ligands promote enantioselective borohydride reduction of ketones, imines, and a,/3-unsaturated carboxylates.1382... 

Although similar efforts have been devoted to related polymer systems (Overberger and Cho, 1968 Overberger and Dixon, 1977 Okamoto, 1978), large enantioselectivity has not been observed. Goldberg et al. (1978) conducted borohydride reduction of phenyl ketones in micelles of the chiral surfactant [44]. The result was disappointing, since the maximal enantioselectivity was only 1.66% for phenyl propyl ketone. A much better optical yield was reported when this reaction was carried out under phase-transfer conditions (Masse and Parayre, 1976). The cholic acid micelle and bovine serum albumin exhibited the relatively high enantioselectivity in the reduction of trifluoroacetophenone (Baba ef al., 1978). 

High enantioselectivities (up to 94%) are obtained in the sodium borohydride reduction of aliphatic ketones using a tartaric acid-derived boronic ester (TarB-N02) as a chiral catalyst. A mechanism (Scheme 14) involving an acyloxyborohydride intermediate has been postulated.319... 

The boron atom dominates the reactivity of the boracyclic compounds because of its inherent Lewis acidity. Consequently, there have been very few reports on the reactivity of substituents attached to the ring carbon atoms in the five-membered boronated cyclic systems. Singaram and co-workers developed a novel catalyst 31 based on dicarboxylic acid derivative of 1,3,2-dioxaborolane for the asymmetric reduction of prochiral ketones 32. This catalyst reduces a wide variety of ketones enantioselectively in the presence of a co-reductant such as LiBH4. The mechanism involves the coordination of ketone 32 with the chiral boronate 31 and the conjugation of borohydride with carboxylic acid to furnish the chiral borohydride complex 34. Subsequent transfer of hydride from the least hindered face of the ketone yields the corresponding alcohol 35 in high ee (Scheme 3) <20060PD949>. 

A Special Case Enantioselective Borohydride Reduction of Ketones... 

Several novel catalysts in which borohydride is complexed with a difiinctional chiral ligand have been developed and used for the enantioselective reduction of prochiral ketones to chiral alcohols. Corey-Bakshi-Shibatareduction (CBS reduction) is an organic reaction which reduces ketones enantioselectively into alcohols by using chiral oxazaborolidines and BHs-THF or catecholborane as stoichiometric reductants (CBS reagent, 1.64) (also see Chapter 6, section 6.4.2). 

Our enantioselective approach to cleomeolide began by controlled dithioketalization [86] of optically pure Wieland-Miescher ketone [87] in order to distinguish between the two carbonyl groups. The best means uncovered for the homologation of 161 to the cis-dimethyl ketone 163 involved 162 as an intermediate (Scheme XIX). The action of (methoxymethylene)triphenylphos-phorane on 161 afforded a 7 1 cis/trans mixture of isomers, which were easily separated after sodium borohydride reduction to the primary carbinols. The major component underwent reductive conversion to 163 very smoothly. 

The hydride-donor class of reductants has not yet been successfully paired with enantioselective catalysts. However, a number of chiral reagents that are used in stoichiometric quantity can effect enantioselective reduction of acetophenone and other prochiral ketones. One class of reagents consists of derivatives of LiAlH4 in which some of die hydrides have been replaced by chiral ligands. Section C of Scheme 2.13 shows some examples where chiral diols or amino alcohols have been introduced. Another type of reagent represented in Scheme 2.13 is chiral trialkylborohydrides. Chiral boranes are quite readily available (see Section 4.9 in Part B) and easily converted to borohydrides. 

Asymmetric reduction of dialkyl ketones. The borohydride 1 reduces dialkyl ketones with low enantioselectivity. However, treatment of the lithium dihydri-doborate 2 with methanesulfonic acid provides Reagent I, which consists of 1 equiv. of R,R-1 and 0.2 equiv. of 2,5-dimethylborolanyl mesylate, which serves as a... 

The applications of sodium acyloxyborohydrides, formed from sodium borohydrides in carboxylic acid media, are reviewed. ° Useful reviews of the stereoselective reduction of endocyclic C=N compounds and of the enantioselective reduction of ketones have appeared. ... 

The reduction of an unsymmetrical ketone creates a new stereo center. Because of the importance of hydroxy groups both in synthesis and in relation to the properties of molecules, including biological activity, there has been a great deal of effort directed toward enantioselective reduction of ketones. One approach is to use chiral borohydride reagents.92 Boranes derived from chiral alkenes can be converted to borohydrides, and there has been much study of the enantioselectivity of these reagents. Several of the reagents are commercially available. 

A diphenylprolinol derivative, having hydrophobic perfluoroalkyl phase tags, has been synthesized and used as a pre-catalyst to generate in situ a fluorous oxaz-aborolidine catalyst for the reduction of prochiral ketones with borohydride. The system afforded high enantioselectivities and the pre-catalyst is easily separated and recycled.272 Reduction of enantiopure A-p-toluenesulfinyl ketimines derived from 2-pyridyl ketones with sodium borohydride affords A-p-toluenesulfinylamines with good yields and diastereoselectivities.273... 

Enantioselective reduction of ketones.1 Sodium borohydride aged with L-tar-taric acid can effect enantioselective reduction of ketones bearing an a-substitueut... 

In 1993, Bolm reported that these reactions could be performed using catalytic quantities (10 mol%) of the chiral P-hydroxy sulfoximine.132 The enantiomeric purities of the product alcohols ranged from 52% (1-indanone) to 93% (PhCOCHjOSiRj). In many cases the enantiomeric purities were enhanced using sodium borohydride as reductant in the presence of chlorotrimethylsilane.133 These methods have been extended to the asymmetric reductions of imines.134 /V-SPh-substituted imines gave the highest enantioselectivities and these reductions proceeded in the same stereochemical sense as the reductions of ketones. 

According to these, for purely aliphatic ketones the highest enantioselectivities are achieved for methyl ketones with a second, branched-chained alkyl substituent (84-94% ee). The value of 75 % ee obtained with the straight-chain hexan-2-one is, to the best of our knowledge, in any case better than anything achieved to date with nonenzymatic systems and homogeneous catalysis. Higher selectivities have been reported for reductions with stoichiometric amounts of chiral borohydrides (e.g. 80 % ee for the reduction of octan-2-one) [20]. 

B-Methoxydiisopinocampheylborohydrides. Treatment of IpC2BOMe with an excess of Potassium Hydride produces the corresponding potassium B-methoxydiisopinocampheyl-borohydride. The reduction of ketones with this reagent proceeds in high yield but with modest enantioselection (eq 5). 

A modestly enantioselective pyrrole carbinol formation has been investigated <05SL2420>. Treatment of lithium pyrrolate with a ketoaldehyde in the presence of a chiral ligand preferentially led to the formation of pyrrole carbinol 49 (50% ee). A hydroxy-directed reduction of the ketone in the side chain by the addition of zinc borohydride provided 50 (88% de). Pyrrole carbinols serve as convenient precursors to aldehydes. A subsequent deprotective Horner-Wadsworth-Emmons reaction involving 50 and phosphonate ester 51 gave unsaturated ester 52. 

Reductions can also be performed in water. Systems for reduction of ketones in water can be water-compatible sodium and lithium borohydrides, amino acid-based cationic surfactants to reduce aryl ketones [19], iridium hydrides used in transfer hydrogenations, such as [Cp Irm(bpy)H]+ (Cp — q5-C5Mes, bpy = 2,2 - bipyridine) [20], and IrHCI2(cod) 2 with a chiral diaminodiphosphine ligand to form secondary alcohols in high enantioselectivity and almost quantitative yield (Equation 4.12) [21]. 

One of the limitations of the Warren s adaptation of Homer-Wittig olefina-tion, the failure of the (Z)-selective route when the alkene has a branched chain substituent, has now been overcome. Reduction of the p-ketophosphonates carrying a-branches, e.g. (112) and (113), with sodium borohydride and cerium chloride gives excellent a / -stereoselectivity and hence (Z)-alkene on base-induced elimination. Enantioselective synthesis of both jy -(115) and anti- ll) P-hydroxy-phosphine oxides has been achieved with up to 90% e.e. through two separate approaches. The jyn-isomer was obtained by reduction of the corresponding ketone (114), while the anti-isomer is the product of the reaction of the oxazolidine substituted aldehyde (116) with lithiated diphenylmethyl-phosphine oxide (Scheme 10). A new, highly stereoselective approach to trisubstituted alkenes has been reported. Cerium(III) chloride-promoted... 

Reduction of Ketones Using Enantioselective Borohydride Reagents... 

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