Catalytic Asymmetric Synthesis. Группа авторов

Catalytic Asymmetric Synthesis - Группа авторов


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chirality conversion strategy.

      Source: Based on [52].

      Source: Based on [53].

      Guanidine is present in a variety of natural products and plays a key role in many biological activities. It can also be found as the side chain of arginine, one of natural amino acids. The intrinsic and distinctive property of guanidine is its strong basicity resulting from the resonance stability in its conjugate acid form, namely guanidinium cation, in which the positive charge can be delocalized over the three nitrogen atoms. In addition, guanidinium cation can interact strongly with anionic species through the combination of hydrogen bonding and ionic bonding, which is widely utilized in molecular recognition [55]. Because of such characteristic features of guanidine and guanidinium cation, chiral guanidine has attracted considerable attention as a promising platform for chiral Brønsted base catalysts in the field of asymmetric synthesis. Indeed, a variety of chiral guanidine catalysts has been developed, and, as a result, various types of useful enantioselective transformations including carbon–carbon bond formations and carbon‐heteroatom bond formations have been accomplished over the past two decades, which are comprehensively summarized in the literature based on the types of transformations or those of catalysts [4]. Following are the representative chiral guanidine catalysts with their fundamental and/or remarkable applications.

Schematic illustration of enantioselective Strecker reaction catalyzed by 22a.

      Source: Based on [58].

Schematic illustration of proposed reaction mechanism.

      Source: Based on [61].

Schematic illustration of enantioselective isomerization of 3-alkynoate catalyzed by 22b.

      Source: [62].

Schematic illustration of enantioselective Michael addition of glycine imines to acrylates catalyzed by 23.