AI Article Synopsis
- Base-catalyzed C-alkylation of potassium enolates with styrenes, also known as CAKES, is a recent method for synthesizing important pharmaceutical compounds.
- K enolates from diverse precursors like alkyl-substituted heterocycles and amides react with styrene in the presence of specific bases, yielding useful products.
- The study utilizes computational methods, kinetics, and deuterium labeling to illuminate the reaction mechanism and propose a general mechanism applicable to other C-alkylation reactions involving enolate-type precursors.
Article Abstract
Base-catalyzed, C-alkylation of potassium (K) enolates with styrenes (CAKES) has recently emerged as a highly practical and convenient method for elaboration or synthesis of pharmaceutically-relevant cores. K enolate-type precursors such as alkyl-substituted heterocycles (pyridines, pyrazines and thiophenes), ketones, imines, nitriles and amides undergo C-alkylation reactions with styrene in the presence of KOtBu or KHMDS. Surprisingly, no studies have probed the reaction mechanism beyond the likely initial formation of a K enolate. Herein, a synergistic approach of computational (DFT), kinetic and deuterium labelling studies rationalizes various experimental observations and supports a metal-ene-type reaction for amide CAKES. Moreover, our approach explains experimental observations in other reported C-alkylation reactions of other enolate-type precursors, thus implicating a general mechanism for CAKES.
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| http://dx.doi.org/10.1039/c9ob02495f | DOI Listing |
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