The first examples of 1,3,2-diazaphospholene-catalyzed imine reduction and conjugate reduction reactions are reported. This approach employs readily synthesized alkoxydiazaphospholene precatalysts that can be handled in open air. Reduction of substrates containing Lewis basic functionality, isolated unsaturation, and protic functional groups was accomplished. The synthetic utility of this approach is demonstrated by the synthesis of the important antiparkinson medicine rasagiline and the natural product zingerone.
The
first use of phosphenium cations in asymmetric catalysis is
reported. A diazaphosphenium triflate, prepared in two or three steps
on a multigram scale from commercially available materials, catalyzes
the hydroboration or hydrosilylation of cyclic imines with enantiomeric
ratios of up to 97:3. Catalyst loadings are as low as 0.2 mol %. Twenty-two
aryl/heteroaryl pyrrolidines and piperidines were prepared using this
method. Imines containing functional groups such as thiophenes or
pyridyl rings that can challenge transition-metal catalysts were reduced
employing these systems.
The synthesis and study of the catalytic activity of 1,2,4,3-triazaphospholenes (TAPs) is reported. TAPs represent a more modular scaffold than previously reported diazaphospholenes. TAP halides were shown to catalyze the 1,2 hydroboration of 19 imines, and three α,β unsaturated aldehydes with pinacolborane, including examples that did not undergo hydroboration by previously reported diazaphospholene systems. DFT calculations support a mechanism where a triazaphospholene cation interacts with the substrate, a mechanism distinct from diazaphospholene catalyzed hydroborations.
The first use of diazaphospholenes as chiral catalysts has been demonstrated with enantioselective imine hydroboration. A chiral diazaphospholene prepared in a simple three-step synthesis from commercial materials has been shown to achieve the highest enantioselectivity for the hydroboration of alkyl imines with pinacolborane reported to date. Enantiomer ratios of up to 88:12 were obtained with low (2 mol %) catalyst loadings. Twenty examples of asymmetric reduction employing this main-group catalysis protocol, including the synthesis of the pharmaceuticals ent-rasagiline and fendiline, are shown.
The first use of diazaphospholenes as chiral catalysts has been demonstrated with enantioselective imine hydroboration. Ac hiral diazaphospholene prepared in as imple three-step synthesis from commercial materials has been shown to achieve the highest enantioselectivity for the hydroboration of alkyli mines with pinacolborane reported to date. Enantiomer ratios of up to 88:12 were obtained with low (2 mol %) catalyst loadings.T wenty examples of asymmetric reduction employing this main-group catalysis protocol, including the synthesis of the pharmaceuticals ent-rasagiline and fendiline,a re shown. Scheme 1. Systems for the metal-free synthesis of secondary amines.Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.
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