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Cyanosilylation catalytic asymmetric of aldehyde

For other catalytic asymmetric cyanosilylation of aldehydes, see C.-D. Hwang, D.-R, Hwang, B.-J. Uang, Enantioselective Addition of Trimethylsilyl Cyanide to Aldehydes Induced by a New Chiral TiflV) Complex, J. Org Chem 1998,63,6762-6763, and references tited therein. [Pg.122]

Y. Hamashima, D. Sawada, M. Kanai, M Shibasaki A New Bifunctional Asymmetric Catalysis An Effident Catalytic Asymmetric Cyanosilylation of Aldehydes, J. Am Chem Soc 1999,121, 2641-2642. [Pg.122]

Inoue et al. reported that a complex prepared from AlMes and peptide Schiff base 166 is available for asymmetric cyanosilylation of aldehydes (Scheme 10.239) [630]. The enantioselectivity observed is not as high, even with a stoichiometric amount of the complex (up to 71% ee). A more recent study by Snapper and Hoveyda has, however, revealed that a similar catalyst system using Al(()t-Pr) ), and peptide Schiff base 167 is quite effective in catalytic asymmetric cyanosilylation of both aromatic and aliphatic ketones (66->98%, 80-95% ee wifh 10-20 mol% of fhe catalyst) [631]. [Pg.554]

Asymmetric cyanosilylation of ketones and aldehydes is important because the cyanohydrin product can be easily converted into optically active aminoalcohols by reduction. Moberg, Haswell and coworkers reported on a microflow version of the catalytic cyanosilylation of aldehydes using Pybox [5]/lanthanoid triflates as the catalyst for chiral induction. A T-shaped borosilicate microreactor with channel dimensions of 100 pm X 50 pm was used in this study [6]. Electroosmotic flow (EOF) was employed to pump an acetonitrile solution of phenyl-Pybox, LnCl3 and benzal-dehyde (reservoir A) and an acetonitrile solution of TMSCN (reservoir B). LuC13-catalyzed microflow reactions gave similar enantioselectivity to that observed in analogous batch reactions. However, lower enantioselectivity was observed for the YbCl3-catalyzed microflow reactions than that observed for the batch reaction (Scheme 4.5). It is possible that the oxophilic Yb binds to the silicon oxide surface of the channels. [Pg.61]

In the presence of 168 a (9mol%) and a phosphine oxide (Bu),P(O) and Ph2P(O)Me for aromatic and ahphatic aldehydes, respectively, 36 mol%), slow addition of TMSCN achieves excellent enantioselectivity with a wide range of aldehydes (86-100%, 83-98% ee). The Al complex has been proposed to work as a bifunctional catalyst for dual activation of the two reactants - the Lewis acidic Al center enhances the electrophilicity of aldehydes and the Lewis basic phosphine oxide induces cyanide addition by nucleophihc activation (Scheme 10.240). This catalytic asymmetric cyanosilylation has been used for the total synthesis of epothilones [652]. [Pg.555]

A sugar-based catalyst for catalytic asymmetric cyanosilylation has been developed. This catalyst, 248, is derived from tri-O-acetyl-D-glucal via the intermediates shown in Scheme 39. It incorporates a Lewis acidic and a Lewis basic site within the molecule, and it was found that the conformational constraint induced by the phenyl group was necessary for good enantioselectivity. Treatment of benzaldehyde and TmsCN with catalytic quantities of 248 gave after acid hydrolysis the cyanohydrin 249 in 80% ee, and several other aldehydes behaved similarly. [Pg.363]

The asymmetric catalytic cyanosilylation of aldehydes229 and the alkylation of aldehydes with ZnEt2230 using the chiral cyano binaphthol complex Ti(CN)2(i )-BINOL have been developed. [Pg.368]

To avoid the intrinsic instability of cyanohydrins and their silyl ether, Saa and coworkers reported catalytic asymmetric cyanophosphonylation reaction of aldehydes with commercially available diethyl cyanophosphonate [58]. In these works, Lewis acid-Lewis base bifunctional catalyst (65) prepared by mixing BI-NOLAM ligand with amino arms as Lewis base and Et2AlCl was found to work nicely (Scheme 6.46). Since a strong positive nonlinear effect was observed in this reaction, actual catalyst is in equilibrium with some oligomeric species of the aluminum complexes. Bifunctional catalyst (65) could also catalyze cyanosilylation of... [Pg.267]


See other pages where Cyanosilylation catalytic asymmetric of aldehyde is mentioned: [Pg.118]    [Pg.553]    [Pg.166]    [Pg.143]    [Pg.118]    [Pg.553]    [Pg.166]    [Pg.143]    [Pg.398]    [Pg.354]    [Pg.934]    [Pg.133]    [Pg.98]    [Pg.556]    [Pg.159]    [Pg.246]    [Pg.275]    [Pg.169]   
See also in sourсe #XX -- [ Pg.2 , Pg.173 ]

See also in sourсe #XX -- [ Pg.2 , Pg.173 ]




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Aldehyde catalytic asymmetric

Aldehydes asymmetric

Asymmetric Cyanosilylation of Aldehydes

Asymmetric catalytic

Asymmetric cyanosilylation

Catalytic aldehyde

Cyanosilylation of aldehydes

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