Catalytic Asymmetric Synthesis. Группа авторов

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Catalytic Asymmetric Synthesis - Группа авторов


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base‐catalyzed reaction, one must take into account the balance of the acidities of a pronucleophile and a product and the basicity of a catalyst. In other words, both the effective generation of an anionic nucleophile and the efficient regeneration of a catalyst are essential to promote a catalytic reaction efficiently. If the basicity of a catalyst is not high enough to deprotonate a substrate, the reaction does not proceed. Therefore, the range of the pronucleophiles applicable to the reaction is highly dependent on the basicity of the employed catalysts. On the other hand, if the basicity of the anionic intermediate, that is the conjugate base of a product, is not high enough to deprotonate the conjugate acid of a catalyst, the catalyst turnover does not occur, and the reaction does not proceed at least in a catalytic fashion. Furthermore, in the case of catalytic enantioselective reactions, the application of a proper chiral catalyst is also critical to achieve high stereoselectivity. Therefore, the development of chiral catalysts is crucial to accomplish various types of catalytic enantioselective reactions. Indeed, a variety of chiral uncharged organobase catalysts has been developed to date, which has broadened the utility of asymmetric Brønsted base catalysis in organic synthesis.

Schematic illustration of general catalytic cycle for Bronsted base catalysis. Schematic illustration of relationship between basicity of uncharged organobases and acidity of representative pronucleophiles (including approximations based on the reported pKBH+ in other solvents).

      Source: Based on [2].

      In this chapter, we categorize the chiral organobase catalysts on the basis of their Brønsted base functionalities and present a brief overview of each category with representative catalysts and their selected applications. It should be noted that there are several excellent reviews on chiral tertiary amine catalysts [3], chiral guanidine catalysts [4], and the other chiral organobase catalysts [5]. In particular, the third edition of this book includes the detail of the background of chiral tertiary amine catalysts and their fundamental applications [6]. Therefore, as to the category of chiral tertiary amine catalysts, we here mainly focus on the recent applications. Although the chiral ion‐pair type Brønsted base catalysts, such as chiral ammonium betaines [7], and chiral anionic Brønsted base catalysts, such as chiral ureates [8], may also be categorized as a family of chiral organobase catalysts, only chiral uncharged organobase catalysts are discussed in this chapter.

Schematic illustration of enantioselective addition of aryl thiols to cyclic enones catalyzed by 1a.

      Source: Based on [10].

Schematic illustration of cinchona alkaloids and derivatives. Schematic illustration of chiral acid–base bifunctional catalysts. Schematic illustration of enantioselective addition of malonates to nitroalkenes catalyzed by 2a.
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