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A general organocatalyzed Michael-Michael cascade reaction generates functionalized cyclohexenes.


ABSTRACT: Although ?-dicarbonyl compounds are regularly employed as Michael donors, intermediates arising from the Michael addition of unsaturated ?-ketoesters to ?,?-unsaturated aldehydes are susceptible to multiple subsequent reaction pathways. We designed cyclic unsaturated ?-ketoester substrates that enabled the development of the first diphenyl prolinol silyl ether catalyzed Michael-Michael cascade reaction initiated by a ?-dicarbonyl Michael donor to form cyclohexene products. The reaction conditions we developed for this Michael-Michael cascade reaction were also amenable to a variety of linear unsaturated ?-ketoester substrates, including some of the same linear unsaturated ?-ketoester substrates that were previously ineffective in Michael-Michael cascade reactions. These studies thus revealed that a change in simple reaction conditions, such as solvent and additives, enables the same substrate to undergo different cascade reactions, thereby accessing different molecular scaffolds. These studies also culminated in the development of a general organocatalyzed Michael-Michael cascade reaction that generates highly functionalized cyclohexenes with up to four stereocenters, in up to 97% yield, 32:1 dr, and 99% ee, in a single step from a variety of unsaturated ?-ketoesters.

SUBMITTER: McGarraugh PG 

PROVIDER: S-EPMC3198797 | biostudies-literature | 2011 Aug

REPOSITORIES: biostudies-literature

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A general organocatalyzed Michael-Michael cascade reaction generates functionalized cyclohexenes.

McGarraugh Patrick G PG   Jones Joshua H JH   Brenner-Moyer Stacey E SE  

The Journal of organic chemistry 20110708 15


Although β-dicarbonyl compounds are regularly employed as Michael donors, intermediates arising from the Michael addition of unsaturated β-ketoesters to α,β-unsaturated aldehydes are susceptible to multiple subsequent reaction pathways. We designed cyclic unsaturated β-ketoester substrates that enabled the development of the first diphenyl prolinol silyl ether catalyzed Michael-Michael cascade reaction initiated by a β-dicarbonyl Michael donor to form cyclohexene products. The reaction condition  ...[more]

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