The Proline Enamine Formation Pathway Revisited in Dimethyl Sulfoxide: Rate Constants Determined via NMR.

Enamine catalysis is a fundamental activation mode in organocatalysis and can be successfully combined with other catalytic methods, e.g., photocatalysis. Recently, the elusive enamine intermediates were detected, and their stabilization modes were revealed. However, the formation pathway of this central organocatalytic intermediate is still a matter of dispute, and several mechanisms involving iminium and/or oxazolidinone are proposed. Here, the first experimentally determined rate constants and rates of enamine formation are presented using 1D selective exchange spectroscopy (EXSY) buildup curves and initial rate approximation. The trends of the enamine formation rates from exo-oxazolidinones and endo-oxazolidinones upon variation of the proline and water concentrations as well as the nucelophilic/basic properties of additives are investigated together with isomerization rates of the oxazolidinones. These first kinetic data of enamine formations in combination with theoretical calculations reveal the deprotonation of iminium intermediates as the dominant pathway in dimethyl sulfoxide (DMSO). The dominant enamine formation pathway varies according to the experimental conditions, e.g., the presence and strength of basic additives. The enamine formation is zero-order in proline and oxazolidinones, which excludes the direct deprotonation of oxazolidinones via E2 mechanism. The nucleophilicity of the additives influences only the isomerization rates of the oxazolidinones and not the enamine formation rates, which excludes a nucleophile-assisted anti elimination of oxazolidinones as a major enamine formation pathway.