Abstract
As one of the most straightforward and powerful approaches for the preparation of optically active compounds, asymmetric hydrogenation has been successfully used for different types of aromatic compounds, including quinolines, isoquinolines, quinoxalines, indoles, pyrroles, furans, imidazoles, and aromatic carbocyclic ring, with excellent enantioselectivities. Despite these advances, direct hydrogenation of simple pyridines is still a challenge. The inherent problems are apparent: First, substrates and corresponding products that possess strong coordination ability might cause the deactivation of catalysts. Second, pyridines have a stabilizing aromatic structure that might impede the reduction. Therefore, only limited examples of hydrogenation of specific pyridine derivatives bearing powerful electron-withdrawing substituent at the 2or 3-position have been previously described. In 2000, Studer et al. reported the first homogeneous rhodium-catalyzed asymmetric hydrogenation of pyridines, but only poor enantioselectivity was obtained. Zhang and co-workers described an efficient three-step rhodium-catalyzed asymmetric hydrogenation of nicotinates. Subsequently, the group of Rueping documented the first enantioselective organocatalytic transfer hydrogenation of 3-cyanoor carbonyl-substituted pyridines using Hantzsch esters as hydrogen sources, and our group also employed [{Ir(cod)Cl}2]/(S)-MeO-biphep/I2 catalyst system for asymmetric hydrogenation of specific pyridines with excellent enantioselectivities. Additionally, an elegant asymmetric hydrogenation of activated pyridines, that is, N-iminopyridinium ylides, was developed by Charette et al. As chiral piperidines are important building blocks for the synthesis of biologically active molecules and natural products, the development of an efficient strategy for the highly challenging hydrogenation of the simple pyridines is still of great significance. Iminium salts generally exhibit higher activity than the corresponding imines in hydrogenation, therefore we envisioned that the activation of simple pyridines as the corresponding N-benzyl-pyridinium bromides would effectively eliminate coordination ability of the substrate and thus the reactivity could be greatly enhanced. Moreover, the stoichiometric amount of hydrogen bromide generated in situ would effectively inhibit the coordination ability of the desired product through the formation of its piperidine hydrogen bromide salt (Scheme 1). Also, the benzyl protecting groups could be conveniently removed by hydrogenolysis. Herein, we disclose the iridium-catalyzed asymmetric hydrogenation of 2-substituted pyridinium salts with excellent enantioselectivity.
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