Cycloaddition Cyclohexanone enolates

Transition-metal mediated carbene transfer from 205 to benzaldehyde generates carbonyl ylides 211 which are transformed into oxiranes 216 by 1,3-cyclization, into tetrahydrofurans 212, 213 or dihydrofurans 214 by [3 + 2] cycloaddition with electron-deficient alkenes or alkynes, and 1,3-dioxolanes 215 by [3 + 2] cycloaddition with excess carbonyl compound120 (equation 67). Related carbonyl ylide reactions have been performed with crotonaldehyde, acetone and cyclohexanone (equation 68). However, the ylide generated from cyclohexanone could not be trapped with dimethyl fumarate. Rather, the enol ether 217, probably formed by 1,4-proton shift in the ylide intermediate, was isolated in low yield120. In this respect, the carbene transfer reaction with 205 is not different from that with ethyl diazoacetate121, whereas a close analogy to diazomalonates is observed for the other carbonyl ylide reactions. 

The tandem carbonyl ylide/cycloaddition reaction is also observed when crotonaldehyde or acetone is used instead of benzaldehyde (dimethyl fumarate as dipolarophile), whereas with cyclohexanone, an enol ether derived from the carbonyl ylide is isolated [19] (Scheme 9). 

Very few pericyclic reactions of carbene complexes have been studied that are not in the cycloaddition class. The two examples that are known involve ene reactions and Claisen rearrangements. Both of these reactions have been recently studied and thus future developments in this area are anticipated. Ene reactions have been observed in the the reactions of alkynyl carbene complexes and enol ethers, where a competition can exist with [2 + 2] cycloadditions. Ene products are the major components firom the reaction of silyl enol ethers and [2 + 2] cycloadducts are normally the exclusive products with alkyl enol ethers (Section 9.2.2.1). As indicated in equation (7), methyl cyclohexenyl ether gives the [2 -t- 2] adduct (84a) as the major product along with a minor amount of the ene product (83a). The t-butyldimethylsilyl enol ether of cyclohexanone gives the ene product 9 1 over the [2 + 2] cycloadduct. The reason for this effect of silicon is not known at this time but if the reaction is stepwise, this result is one that would be expected on the basis of the silicon-stabilizing effect on the P-oxonium ion. 

The nudeophiUdty of some of the silyl-enolates may lead to the formation of Michael adducts with electron-poor dienophiles. Nevertheless, the cycloaddition was used to furnish cyclohexanone-linked peptide conjugates bound to hydrophihc PEOPOPisoo (305, 307) [310] or PEGA [309] resins, which the authors used for protease inhibitor assays (Scheme 65) [309],... 

P, P] Seebach and Brock reported the dichlorodiisopropoxytitanium-mediated addition of the trimethylsilyl enol ether of cyclohexanone to /3-nitrostyrenes (83). The initial products generated are nitronic esters 39.1-39.3. Separation followed by fluoride-induced desilylation of these intermediates yields the corresponding syn and anti nitroketones. The results of this study are summarized in Scheme 39 and Table 12. Anti isomers are obtained in moderate diastereomeric excess. Moreover, the method is complementary to the additions of similar substrates by way of their lithium enolates (2) or enamines (vide supra), which provide the syn diastereomers. Further reactions of the intermediate nitronic esters were briefly explored. For example, addition of aldehydes and activated olefins provides stereoselectively the products from nitroaldol and [3 + 2] cycloadditions. 

The reactions of TBS and TIPS enol ethers of cyclohexanone with trifluoroethyl acrylate and 10 mol% of catalyst 18 in CH2CI2 proceeded smoothly to give [2+2] cycloaddition products 19a-f. Although the endo ester predominated in each case, the selectivity (97 3) was greater for the TIPS enol ether 6a than for the TBS enol ether 5a (82 18) (entries 1 and... 

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