One‐Pot Synthesis of (−)‐Oseltamivir and Mechanistic Insights into the Organocatalyzed Michael Reaction

Abstract

The one-pot sequential synthesis of (-)-oseltamivir has been achieved without evaporation or solvent exchange in 36% yield over seven reactions. The key step was the asymmetric Michael reaction of pentan-3-yloxyacetaldehyde with (Z)-N-2-nitroethenylacetamide, catalyzed by a diphenylprolinol silyl ether. The use of a bulky O-silyl-substituted diphenylprolinol catalyst, chlorobenzene as a solvent, and HCO2 H as an acid additive, were key to produce the first Michael adduct in both excellent yield and excellent diastereo- and enantioselectivity. Investigation into the effect of acid demonstrated that an acid additive accelerates not only the E-Z isomerization of the enamines derived from pentan-3-yloxyacetaldehyde with diphenylprolinol silyl ether, but also ring opening of the cyclobutane intermediate and the addition reaction of the enamine to (Z)-N-2-nitroethenylacetamide. The transition-state model for the Michael reaction of pentan-3-yloxyacetaldehyde with (Z)-N-2-nitroethenylacetamide was proposed by consideration of the absolute configuration of the major and minor isomers of the Michael product with the results of the Michael reaction of pentan-3-yloxyacetaldehyde with phenylmaleimide and naphthoquinone.