Acetals silylacetals

Silylation using the silylacetate (3.1.14) [49] involves the initial formation of the acetate carbanion, which abstracts a proton from the carbonyl compound or alcohol (Scheme 3.2, Table 3.5). When the reaction with a ketone is conducted in the presence of an aldehyde, crossed aldol products are obtained (see Chapter 6). 

One of the earliest uses for rhodium(II)-catalyzed dipoles was demonstrated in Davies furan synthesis [22]. Isomiinchnones were also shown to produce substituted furans [115]. Additional furan syntheses have been described using silylacetates [116], unsaturated esters [117], and fluoroalkyl diazo acetates [118]. The synthesis of furofuranones and indenofuranones 35 from a-diazo ketones having pendant alkynes has also been reported (Eq. 6) [119]. Other fused heterocyclic systems include furo[3,4-c]furans [120, 121] furo[2,3-b]furans [122] as well as thiobenzofurans [123], and benzoxazoles[124] have also been synthesized with this methodology. 

Michael additions of ketene alkyl silylacetals. In the presence of TiCl, (1 equiv.) these acetals undergo Michael addition to ethyl propiolate via a titanate intermediate. 

Paternd-Biichi reactions [152] this competition has been investigated for electron-rich alkene substrates for several combinations of carbonyl compounds and electron-donors, e.g. a-diketones and ketene acetals [153], aromatic aldehydes and silyl ketene acetals, and enol ethers. In polar solvents, the assumption of a 1,4-zwitterion as decisive intermediate is reasonable. This situation then resembles the sequence observed for ET-induced thermal [2 -I- 2]-cycloaddition reactions [154]. Both regio- and diastereoselectivity are influenced by this mechanistic scenario. The regioselectivity is now a consequence of maximum charge stabilization and no longer a consequence of the primary interaction between excited carbonyl compound and alkene. Whereas 3-alkoxyoxetanes are preferentially formed from triplet excited aldehydes and enolethers, 2-alkoxyoxetanes result from the reaction of triplet excited ketones or aldehydes and highly electron-rich ketene silylacetals (Scheme 40) [155]. 

The reaction of a silylacetate derivative with an aldehyde or ketone was initially studied by Rathke and Yamamoto. Rathke and coworicers studied the addition of the lithium anion of r-butyl (trimethylsi-lyl)acetate (340) with a variety of aldehydes and ketones (equation 78). The anion can be formed directly from the silyl compound on treatment with LDA. The reaction proceeded to give the conjugated alkenes in excellent yields. Unsaturated compounds reacted via 1,2-addition. No discussion of alkene geometry was present. In the Yamamoto work, the ethyl (trimethylsilyl)acetate derivative (342) was used in a variety of reactions with aldehydes and ketones (equation 79). The anion was formed wiA dicyclohexyl-amide in THF. It was stated in the experimental section that the ( ) (Z) ratios of alkenes were dependent on the reaction conditions. In all the examples presented in this work, the ( )-isomer was predominantly formed. 

Most [3,3]-sigmatropic rearrangements take place thermally, and the Cope, oxy-Cope and Claisen rearrangements are among the most important rearrangements in this class. Important variants of the Claisen rearrangement include the Johnson modification via orthoesters, the Eschenmoser modification via ketene N,O-acetals, the Ireland modification via ketene silylacetals and the Corey modification via boron ester enolates [696], The aza-Claisen rearrangement has also seen... 

Si-transfer from oxygen to carbonIn the presence of a trialkylaluminum, particularly (CH3),AI, silyl ketene acetals rearrange at —78° to 20° to esters of trialkyl-silylacetic acid. This 1,3-rearrangemcnt of Si from oxygen to carbon is the reverse of the well-known Brook thermal rearrangement2 of Si from carbon to oxygen. But R AI does not rearrange trimethylsilyl enol ethers. 

Aminations which afford 6-aminocarboxylates are of interest in relation to monobactam antibiotics. A secondary aminomethyl group can be introduced at the -position of carboxylic esters by reaction of hexahydro-1,3,5-triazines with ketene silyl acetals in the presence of a catalytic quantity of trifluoromethanesulphonic acid (Scheme 25). The triazine (10) is considered to be converted into an N-silylated methyleneiminium salt which undergoes addition of the ketene silylacetal (11). 

Finally, the ability of the silylacetate, fluoromethacrylate-bearing template 69 to enforce oligoselectivity on the group transfer polymerization of MMA was examined. However, no fluoride-initiated polymerization conditions could be identified which led to template-bound oligomer. Typically, off-template initiation (F"-i-MMA ) furnished uncontrolled polymer. In these cases, the template 69 suffered simple desilylation to deliver the acetate 70. Perhaps a template-bound silyl ketene acetal initiator would have performed in a more desirable manner, but that species remained elusive. 

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