Aldehydes asymmetric hydrosilylations

Asymmetric hydrosilylation of 1,3-dienes provides convenient access to optically active a-chiral allylsilanes.107 1073 1071 The combination of 7r-allylpalladium chloride dimer with axially chiral monophosphine ligand 17 realizes high catalytic activity and enantioselectivity in the reaction of cyclic 1,3-dienes with HSiCl3.108,108a The allyltrichlorosilanes obtained react with aldehydes in a syn-Se mode to give homoallyl alcohols with high diastereo-and enantioselectivity (Scheme 9). 

The chiral ferrocenylselenium reagents were found to act as the effective ligands for Rh(I)-catalyzed asymmetric hydrosilylation and transfer hydrogenation (see Sects. 2.1 and 2.2, respectively). Fukuzawa and Tsudzuki have found that the chiral ferrocenylselenium-based amino alcohols (DASF), prepared by treatment of the chiral diferrocenyl diselenide with NaBH4 in ethanol followed by the addition of epoxides (Scheme 11), efficiently catalyzed the diethylzinc addition to aldehydes to provide the corresponding secondary alcohols with up to 99% ee... 

Rhodium-phosphine complexes are usually active and effective in the asymmetric hydrosilylation of olefins, ketones, and aldehydes, allowing for the virtual synthesis of optically active alkoxysilanes and organic compounds of high purity. Chiral rhodium-phosphine catalysts predominate in the hydrosilylation of pro-chiral ketones. This subject has been comprehensively reviewed by several authors who have made major contributions to this field [52-54]. A mechanism for the hydrosilylation of carbonyl groups involving the introduction of asymmetry is shown in Scheme 3 [55]. 

Palladium-catalyzed hydrosilylation of 1,3-dienes is one of the important synthetic methods for allylic silanes, and considerable attention has been directed to the asymmetric synthesis of the latter by catalytic methods [9]. Optically active allyhc silanes have been used as chiral allylating reagents in S reactions with electrophiles, typically aldehydes [38,39]. In the presence of Pd catalysts the reaction with hydrosilanes containing electron-withdrawing atoms or substituents on sihcon usually proceeds in a 1,4-fashion giving allyHc silanes [40,41]. Asymmetric hydrosilylation of cyclopentadiene (29) forming optically active 3-silylcyclopentene (30) has been most extensively studied (Scheme 13). In the first report, hydrosilylation of cyclopentadiene (29) with methyldichlorosilane in the presence of 0.01 mol % of palladium-(l )-(S)-PPFA (15a) as a catalyst gave... 

When prochiral silane and ketone are used, hydrosilylation, in the presence of a chiral catalyst, results in asymmetric induction at both the silicon and carbon centers. Treatment of the diastereomeric alkoxysilane by a Grignard reagent leads to recovery of an organosilane and an alcohol of different optical purity. Results obtained in the asymmetric hydrosilylation of ketones and aldehydes by prochiral silanes in the presence of an asymmetric catalyst are summarized in Tables 3 and 4. 

Asymmetric Hydrosilylation of Symmetric Ketones and Aldehydes by Prochiral Dihydrosilanes (68, 79, 80)... 

TABLE 4. Asymmetric hydrosilylation of symmetric ketones and aldehydes by prochiral dihydrosilanes (after References 50, 52 and 53)... 

Asymmetric hydrosilylation of ketones and ketoimines has been demonstrated in the absence of transition metal catalysts. Using catalytic amounts of chiral-alkoxide Lewis bases such as binaphthol (BINOL), Kagan was able to facilitate the asymmetric reduction of ketones (eq 19). This process is believed to arise from activation of the triethoxysilane by mono-alkoxide addition to give an activated pentavalent intermediate, which can undergo coordination of an aldehyde. This highly ordered hexacoordinate transition state directs reduction in an asymmetric manner, with subsequent catalyst regeneration. Brook was able to facilitate a similar tactic for asymmetric reduction by employing histidine as a bi-dentate Lewis base activator of triethoxysilane. A similar chiral lithium-alkoxide-catalyzed asymmetric reduction of imines was demonstrated by Hosomi with the di-lithio salt of BINOL and trimethoxysilane. ... 

Although there are now several catalysts useful for hydrogenation of saturated carbonyl compounds to alcohols (see Section XII), an alternative approach has involved initial hydrosilylation (Chapter 9 in this volume) followed by acid hydrolysis [Eq. (41)]. The area first developed using principally the RhCl(PPh3)3 catalyst (207-210), and has since proved particularly useful in asymmetric syntheses (see Section III,A,4). Besides simple aliphatic and aromatic aldehydes and ketones, the ter-pene-ketones camphor and menthone were stereoselectively reduced to mainly the less stable alcohols e.g., camphor gave 9 (209). 

Asymmetric reduction of ketones or aldehydes to chiral alcohols has received considerable attention. Methods to accomplish this include catalytic asymmetric hydrogenation, hydrosilylation, enzymatic reduction, reductions with biomimetic model systems, and chirally modified metal hydride and alkyl metal reagents. This chapter will be concerned with chiral aluminum-containing reducing re-... 

Suisse and co-workers have studied the asymmetric cyclization/silylformylation of enynes employing catalytic mixtures of a rhodium(i) carbonyl complex and a chiral, non-racemic phosphine ligand. Unfortunately, only modest enantioselectivities were realized.For example, reaction of diethyl allylpropargylmalonate with dimethylphenyl-silane (1.2 equiv.) catalyzed by a 1 1 mixture of Rh(acac)(GO)2 and (i )-BINAP in toluene at 70 °G for 15 h under GO (20 bar) led to 90% conversion to form a 15 1 mixture of cyclization/silylformylation product 67 and cyclization/ hydrosilylation product 68. Aldehyde 67 was formed with 27% ee (Equation (46)). 

The catalytic reduction of aldehydes and ketones when carried out via hydrosilylation, gave high optical yield (60%) (Dumont et aL, 1973). The mechanism of this reduction is thought to involve the intermediate formation of an asymmetric siloxane. 

Silver(I) salts are often utilized as catalysts for addition reactions. Kozmin and Sun have recently shown that AgNTf2 is a catalyst of choice for the hydroamination of siloxy alkynes with either secondary amides or carbamates to give silyl ketene am-inals [34]. The addition occurs in a syn selective manner, for instance, the reaction of siloxy alkyne (24) with carbamate (25) produces silyl ketene aminal (26) in 86% yield at room temperature under the influence of 1 mol% of AgNTf2 (Scheme 18.9). A six-membered chelated transition state is proposed to explain the high syn selectivity. Diastereoselective bromohydroxylation and bromomethoxylation reactions of cinnamoyl compounds possessing a chiral auxiliary are also effectively promoted by silver(I) salts such as AgNOs [35]. The asymmetric halohydrin reaction has been successfully applied into stereoselective syntheses of (-)-chloramphenicol and (+)-thiamphenicol. Csp-H iodination [36], hydrosilylation of aldehydes [37], and deprotection of TMS-alkynes [38] are also catalyzed by silver (I) salts. 

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