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Catalytic Asymmetric Synthesis


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alt="Schematic illustration of first enantioselective alkylation using chiral cation phase transfer catalysis."/>

      Source: Based on [2].

Schematic illustration of enantioselective benzylation of glycine imines.

      Source: Based on [3].

Schematic illustration of catalyst development for the enantioselective mono-alkylation of glycine imines.

      Concurrently, efforts by a number of groups aimed to explore catalyst architectures that significantly differed from cinchoninium alkaloids. In 1999, Maruoka reported the use of C 2‐symmetric chiral ammonium salts derived from binaphthyl backbones [12]. High enantioselectivity (up to 96% ee) was achieved with this family of catalysts and marked the first departure from previously reported cinchoninium catalysts. Later, the same group reported a related catalyst wherein one chiral binaphthyl group is replaced by a more flexible achiral biphenyl group, which also achieved high enantioselectivity (94% ee) [13]. Building on this, Lygo reported in 2003 a structurally distinct chiral ammonium catalyst based on a simple biphenyl backbone, where the chiral element originates from a chiral benzylic amine [14]. Due to the scaffold’s modular synthesis and ease of diversification, a small library of ammonium catalysts was synthesized and benchmarked against the enantioselective benzylation of glycine imine. The optimal catalyst featured an α‐methylnathphtylamine group and proved to be highly enantioselective (97% ee). In 2002, Shibasaki reported a tartrate‐derived bis‐ammonium catalyst that proved to be highly enantioselective for the same reaction (93% ee) [15–17]. The hypothesis was that the tert‐butyl glycinate anion would preferentially orient itself between both ammonium centers, leading to enantiotopic face discrimination. Monte Carlo molecular mechanics simulations were consistent with this substrate‐catalyst binding mode. In 2003, Sasai reported another dicationic bis‐ammonium catalyst based on a spirocyclic bis‐pyrrolidinium scaffold, which also proved to be highly enantioselective in the same reaction (95% ee) [18]. In 2002, Nagasawa reported pentacyclic guanidine salts as efficient catalysts for the same reaction (90% ee) [19]. Hydrogen bonding interactions with the glycinate anion are proposed, which allow for high levels of enantioinduction. In 2011, Denmark disclosed a family of tricyclic ammonium catalysts that proved to be moderately enantioselective (up to 62% ee) [20]. Most recently in 2016, Lu reported that quaternary phosphonium salts derived from amino acids were highly efficient catalysts for the benzylation of glycine imines (93% ee) [21].

      The use of benzophenone‐derived imines in the enantioselective phase‐transfer catalyzed alkylation reactions described above allowed for exclusive mono‐alkylation selectivity over bis‐alkylation and avoided product racemization. This is due to the lower C–H acidity (pKa~23) of the mono‐alkylated benzophenone imine product compared to the nonalkylated starting material (pKa~19) [22]. The stark difference in acidity can be rationalized by unfavorable allylic 1,3‐strain between the benzophenone imine phenyl group and the α‐alkyl substituent, forcing them out of plane and reducing stabilization of the azaallyl anion.

      While α‐amino acid imines have arguably been the most explored class of substrates for enantioselective phase‐transfer catalysis, enolates derived from ketones, esters, and amides have also successfully been used in such transformations. Furthermore, numbers of different alkyl electrophiles, both activated and unactivated, have been reported in such transformations. These will not be comprehensively discussed in this chapter, but can be found in more detailed reviews on the subject [28]. Overall, successful implementation of enantioselective phase‐transfer catalysis for enolate alkylation hinges on controlling mono‐alkylation and bis‐alkylation, while avoiding product racemization.

Schematic illustration of catalyst development for the enantioselective synthesis alpha,alpha-dialkylated glycine imines.

       4.2.1.2. Addition to Michael Acceptors