Enolsilane, Mukaiyama aldol reaction

The addition of an enolsilane to an aldehyde, commonly referred to as the Mukaiyama aldol reaction, is readily promoted by Lewis acids and has been the subject of intense interest in the field of chiral Lewis acid catalysis. Copper-based Lewis acids have been applied to this process in an attempt to generate polyacetate and polypropionate synthons for natural product synthesis. Although the considerable Lewis acidity of many of these complexes is more than sufficient to activate a broad range of aldehydes, high selectivities have been observed predominantly with substrates capable of two-point coordination to the metal. Of these, benzy-loxyacetaldehyde and pyruvate esters have been most successful. 

Aldol Addition. A catalyst generated upon treatment of Cu(OTf)2 with the (5,5)-r-Bu-box ligand has been shown to be an effective Lewis acid for the enantioselective Mukaiyama aldol reaction. The addition of substituted and unsubstituted enolsilanes at -78 °C in the presence of 5 mol % catalyst was reported to be very general for various nucleophiles, including silyl dienolates and enol silanes prepared from butyrolactone as well as acetate and propionate esters. 

LiC104 was shown to be a more compatible Lewis acid for chelation in an ethereal solvent—when TiCU, a typical chelation agent for a-alkoxyaldehydes, was used in EtaO for alkylation of 79, moderate diastereoselectivity (68 32) was obtained. Rapid injection NMR studies of the TiCU-promoted chelation-controlled Mukaiyama aldol reaction and the Sakurai reaction show that an acyclic transition state must be involved in which the silyl groups never reach the carbonyl oxygen atom. In LPDE-mediated enolsilane additions silylated products predominate. Obviously, the mechanism is different—it is a group-transfer aldol reaction [107]. 

Mukaiyama aldol reaction of glyoxal derivatives with enolsilanes in the presence of an in situ generated nickel catalyst derived from an JV,iV-dioxide ligand. 

SCHEME 8.21. The Mukaiyama aldol reaction using an enolsilane. 

The Mukaiyama variation of the aldol reaction also allows 1,3-induced chelation control. Thus, the reaction of the enolsilane or silylketene acetal with (5 )-3-benzyloxybutanal results in both cases in the predominant formation of the cwt/ -adduct (92 8 and 90 10), respectively14. 

The Mukaiyama version of the aldol reaction is well known a carbonyl-titanium tetrachloride complex reacts with a trimethylsilyl enol ether. Under these conditions there is no titanium enolate involved. Another procedure has been reported a trimethylsilyl enol ether reacts with titanium tetrachloride to give the titanium enolate addition of the carbonyl compound generates the aldol product (although with slightly lower diastereoselectivity than with Mukaiyama s procedure). (Z)-Enolsilanes from acyclic ketones react rapidly and stereospecifically with TiCU to form (Z)-configured CbTi enolates, while the ( )-isomers react slowly to afford low yields of mixtures of ( )- and (Z)-Cl3Ti enolates (Scheme 41). 

Other Lewis acid mediated C-C bond forming reactions of silylated C-nucleophiles include the Mukaiyama aldol and Michael additions of enolsilanes ), the related reaction of allylsilanes described by Sakurai ) as well as similar reactions of Me3SiCN ). Other "inert C-nucleophiles such as dialkylzinc compounds also react with carbonyl compounds in the presence of Lewis acids ). We ourselves have utilized many of these processes in performing stereoselective reactions, particularly in achieving diastereofacial selectivity in the reactions... 

C. Discovery of aldol reaction variants such as the Le vis acid catalyzed addition of enolsilanes to aldehydes (Mukaiyama aldol variant). 

Lewis acid, by enolsilane addition to chiral oxonium ions (cf. equation 40). Oxonium ions are also probably involved in the diastereoselective AlCb-mediated additions of enolsilanes to chiral 2-benzenesulfo-nyl cyclic ethers. In the diastereoselective additions to chiral acetals - (see Section 2.4.4.4), an extension of the methodology shown in Scheme 9 to the enantio differentiation of meso 1,2- and 1,4-diols was reported. An intramolecular Mukaiyama acetal-aldol reaction (see Section 2.4.4.S) was reported as the key step to construct the 11-memboed ring of hydroxyjatrophone A and B. "... 

An exceptionally mild procedure for the cross-condensation of aldimines and enolsilanes has been described (eq. [67]) (80). This titanium tetrachloride-mediated reaction is predicated on the previous analogies provided by Mukaiyama for related aldol condensations (73a). Depending on aldimine structure and reaction time, either -lactams or their penultimate amino esters may be isolated from the reaction. The authors postulate that these reactions are proceeding via titanium enolates derived from ligand exchange by... 

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