Rearrangements ketone-silyl ether

In a formal synthesis of fasicularin, the critical spirocyclic ketone intermediate 183 was obtained by use of the rearrangement reaction of the silyloxy epoxide 182, derived from the unsaturated alcohol 180. Alkene 180 was epoxidized with DMDO to produce epoxy alcohol 181 as a single diastereoisomer, which was transformed into the trimethyl silyl ether derivative 182. Treatment of 182 with HCU resulted in smooth ring-expansion to produce spiro compound 183, which was subsequently elaborated to the desired natural product (Scheme 8.46) [88]. 

In order to establish the correct absolute stereochemistry in cyclopentanoid 123 (Scheme 10.11), a chirality transfer strategy was employed with aldehyde 117, obtained from (S)-(-)-limonene (Scheme 10.11). A modified procedure for the conversion of (S)-(-)-limonene to cyclopentene 117 (58 % from limonene) was used [58], and aldehyde 117 was reduced with diisobutylaluminium hydride (DIBAL) (quant.) and alkylated to provide tributylstannane ether 118. This compound underwent a Still-Wittig rearrangement upon treatment with n-butyl lithium (n-BuLi) to yield 119 (75 %, two steps) [59]. The extent to which the chirality transfer was successful was deemed quantitative on the basis of conversion of alcohol 119 to its (+)-(9-methyI mande I ic acid ester and subsequent analysis of optical purity. The ozonolysis (70 %) of 119, protection of the free alcohol as the silyl ether (85 %), and reduction of the ketone with DIBAL (quant.) gave alcohol 120. Elimination of the alcohol in 120 with phosphorus oxychloride-pyridine... 

The cyclization of y -hydroxy ketones is useful for the formation of pyrans,306,403 both directly and via rearrangement, as illustrated in Eq. 231.153 As with their acyclic counterparts, these cyclizations also occur with the silyl ethers of the hydroxy ketones where Et3SiH/BiBr3 is used with the TBS and TES ethers.342,404 A methyl thiomethyl ether is also capable of undergoing the reductive cyclization 405 In like manner, 1,4-diols and e-hydroxy ketones provide oxepanes, with I ds Si H or PhMe2SiH/TMSOTf being especially effective (Eqs. 232 and 233).336,406 The trimethylsilyl ether of the alcohol also provides the oxepane.306... 

E)-Enol silyl ethers.1 A new highly stereoselective route to (E)-enol silyl ethers involves addition of CH,Li to silyl ketones substituted at the a -position by a SC6H5 group such as 1. The adduct (a) undergoes a Brook rearrangement and... 

Retro-Brook rearrangement of the [l,3]-variant will readily take place in sp and sp carbanion systems. Kuwajima and Takeda and Corey and Rticker have developed the [l,3]-retro-Brook rearrangement of silyl enol ether anions which provide a-silyl ketones (equation 100 and 101). 

Siloxy-l-vinylcyclopropanes rearrange thermally to give 1-siloxycyclopentene derivatives or may be hydrolyzed to cyclobutanones by acids (J.M. Conia, 1975 B.M. Trost, 1973 G.C. Girard, 1974). The cyclopropane ring may also be opened by base-catalyzed hydrolysis of the silyl ethers to form ethyl ketones. 

On the other hand, methylaluminum bis(4-bromo-2,6-di-fert-butylphenoxide) can effect the a-alkylation of enol silyl ethers of a variety of ketones, esters and some aldehydes108. Use of the (Z-Bu)Me2Si group is recommended in the ketene silyl acetal substrates. Use of a less bulky Me3Si or Et3Si group leads to a mixture of monoalkylation products and rearranged a-silyl esters. 

An unexpected rearrangement was observed during studies directed towards the synthesis of bicyclic keto silanes by the thermal rearrangement of cycloalkanones bearing an co-silylacetylenic chain P to the carbonyl group. Thus, the bicyclic enol silyl ether 2 was formed in 60-65% yield when the ketone 1 was heated neat at 300°C for 2 hours. 

The ozonolysis of substituted-allyl silyl ethers or allyl esters followed by treatment with bases or Ph3P give the corresponding a-silyloxy ketones or a-acyloxy ketones.116 The reaction is proposed to proceed via an ene-diol rearrangement of the corresponding a-silyloxyaldehyde or a-acyloxyaldehydes intermediates. 

Tsai and coworkers89,91,246,247 reported the synthesis of cyclic silyl enol ethers and silyl ethers by using a radical cyclization followed by the radical Brook rearrangement (equation 111). The cyclization of 4-bromo-4-stannylbutyl silyl ketones 188 in benzene with a catalytic amount of tributyltin hydride and AIBN gave cyclic silyl enol ethers 18989 91 247. The whole catalytic cycle proposed is shown in equation 112. 

Rearrangement of (a-methyldiphenylsilyl)alkyl ketones.1 These a-silyl ketones rearrange thermally to a mixture of (Z)- and (E)-enol silyl ethers. However, rearrangement in acetonitrile results in only the (Z)-enol silyl ethers (>99 1). These enol silyl ethers are useful precursors to (Z)-lithium enolates. 

Enol ethers, and in particular silylated ends (see Volume 2, Chapter 2.3), react with peroxy acid reagents to give initially a silyloxy qpoxide, which rearranges with silyl migration to yield an a-silyloxy ketone, " as in Scheme 3. The net result is that a ketone is converted to a protected a-hydroxy ketone, and the stereochemistry b determined by the least hindered approach of the peroxy acid to the enol. 

Acyloins. The anion of the adduct of cyanotrimethylsilane with benzaldehyde reacts with aldehydes and ketones to form acyloin silyl ethers (2), by way of a 1,4-O-siIyI rearrangement, a—>b. On hydrolysis acyloins (3) are obtained in high yield. 

With cyclopropanation products of trimethylsilyl enol ethers the same rearrangement is induced even by aqueous sodium hydroxide. a-Methyl ketones were obtained in near quantitative yield, e.g. formation of 62, 64, and 65. " Silyl ethers are optimal starting materials since acidic. 

Bridged bicyclic ketones 7 are obtained by the Cope rearrangement of silyl enol ethers or lithium enolate anions derived from ent/o-vinylcyclopropanes 4. i 11 The corresponding exo-isomers of 5 require flash-vacuum pyrolysis at temperatures in the range of 250-500°C to... 

---