Epoxides, Mukaiyama aldol reaction

Jacobsen epoxidation 359 -, Katsuki epoxidation 361 -, Mukaiyama-aldol reaction 367 f. -, oxime ether reduction 363 -, Sharpless asymmetric dihydroxyla-tion 361... 

Herein we will focus on the recent development of vinylogous [1] aldol reactions and their application in the synthesis of natural products [2-5]. In particular the synthesis of unsaturated esters through the vinylogous Mukaiyama aldol reaction is of great interest, since it provides rapid access to larger carbon frameworks and allows for a wide variety of transformations of the double bond (dihydroxylation, epoxidation, cuprate addition etc.). 

The authors used (5)-carvotanacetone (dihydrocarvone) as starting material (Scheme 34). To prepare the linearly conjugated sUylenol ether, they used the Kharash protocol and attained y-alkylation by Mukaiyama aldol reaction with trimethylorthoformate (195). The ketoacetal 295 was a-hydroxylated according to Rubottom by silylenol ether formation followed by epoxidation and silyl migration. Acid treatment transformed 296 to the epimeric cyclic acetals 297 and 298. endo-Aceta 297 was equilibrated thereby increasing the amount of exo-acetal 298. The necessary unsaturated side chain for the prospected radical cyclization was introduced by 1,4-addition of a (trimethylsilyl)butynylcopper compound. 

Lanthanide Lewis acids catalyze many of the reactions catalyzed by other Lewis acids, for example, the Mukaiyama-aldol reaction [14], Diels-Alder reactions [15], epoxide opening by TMSCN and thiols [14,10], and the cyanosilylation of aldehydes and ketones [17]. For most of these reactions, however, lanthanide Lewis acids have no advantages over other Lewis acids. The enantioselective hetero Diels-Alder reactions reported by Danishefsky et al. exploited one of the characteristic properties of lanthanides—mild Lewis acidity. This mildness enables the use of substrates unstable to common Lewis acids, for example Danishefsky s diene. It was recently reported by Shull and Koreeda that Eu(fod)3 catalyzed the allylic 1,3-transposition of methoxyace-tates (Table 7) [18]. This rearrangement did not proceed with acetates or benzoates, and seemed selective to a-alkoxyacetates. This suggested that the methoxy group could act as an additional coordination site for the Eu catalyst, and that this stabilized the complex of the Eu catalyst and the ester. The reaction proceeded even when the substrate contained an alkynyl group (entry 7), or when proximal alkenyl carbons of the allylic acetate were fully substituted (entries 10, 11 and 13). In these cases, the Pd(II) catalyzed allylic 1,3-transposition of allylic acetates was not efficient. 

Lanthanide(ni) on ion exchange resins catalyse Mukaiyama aldol reactions in aqueous media, acetalisations, additions of silyl enol ethers to imines, saz-Diels-Alder reactions and the ringopening of epoxides with alcohols as depicted in Scheme 3.6.7. 

Sml2-mediated aldol reactions can also be carried out using epoxides and aziridines as precursors to the Sm(III) enolate. In 2000, Mukaiyama reported a method for the synthesis of unsymmetrical bis-aldols using Sml2 to... 

Furthermore, Heck [9], aldol [10], epoxidation [11], hydrogenation [12], cyclo-propanation [13], Mukaiyama aldol condensation [14], and oxidative kinetic resolution [15] batch reactions have also been successfully performed with SILP systems. 

---