Approaching Highly Enantioselective Reductive Amination

Abstract

A longstanding problem in enantioselective catalysis concerns the transformation of prochiral ketones into chiral amines. To date, this reaction is mainly associated with the hydrogenation of imines or enamine derivatives using late transition metal complexes based on chiral P-ligands. However, the one-pot reduction of a suitable intermediate arising from the reaction of the carbonyl compounds and amine would be much more favorable (direct reductive amination), since one step is saved. In this account, we report on the story of the development of chiral Rh-diphosphine catalysts, which can be used for this enantioselective transformation. For example, α-amino acids were prepared by this methodology in up to 98% ee. Before we achieved this goal, all possible products arising from the reaction between carbonyl component and starting amine, like imines, enamines and N,O-acetals, and serving therefore as potential substrates, were successfully subjected to hydrogenation. Apparently, in the direct reductive amination, different substrates may serve as precursors for chiral amine products ­depending on the starting material and reaction conditions. This matter complicates the rational design of catalysts. Therefore, the use of high-throughput methods for identification of efficient ­catalysts is recommended. 1 Introduction 2 Hydrogenation of Unsaturated and Saturated Nitrogen ­Substrates 2.1 Hydrogenation of Imines 2.2 Enantioselective Hydrogenation of Enamines 2.3 Hydrogenation of Saturated Nitrogen Species (N,O-Acetals and Related Compounds) 3 Direct Reductive Amination (DRA) of Carbonyl ­Compounds 3.1 Nonasymmetric Version 3.2 Enantioselective Direct Reductive Amination 4 Conclusions