Dual NHC/HAT-Promoted Esterification to Access α-Aryl Glycines

IF 4.4 2区化学 Q2 CHEMISTRY, APPLIED

Advanced Synthesis & Catalysis Pub Date : 2024-10-30 DOI:10.1002/adsc.202401207

Karl Scheidt, Matthew McGill, Cullen Schull, Adam Wayment

引用次数: 0

Abstract

α-Aryl glycines are among the more important carbonyl compounds, particularly as nonproteinogenic α-amino acids present in many pharmacophores. As such, many strategies have been developed to access this motif, but direct carboxylation methods remain underdeveloped. Herein, we employ a dual NHC/HAT catalysis strategy to access 2-azaallyl radicals, which subsequently couple with in situ generated ester azolium radical intermediates. Base-mediated collapse of the ensuing tetrahedral intermediate liberates the NHC catalyst and benzophenone protected aryl glycine. This methodology was employed to esterify obtain a variety of aryl substituted glycine derivatives, as well as allylic and benzylic sites. Mechanistic studies reveal that this radical process operates under both oxidative and reductive quenching cycles, while preliminary experiments employing a chiral NHC and Lewis acid additive demonstrate modest enantioselectivity.

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NHC/HAT 双促进酯化以获得 α-芳基甘氨酸

α-芳基甘氨酸是较重要的羰基化合物之一，尤其是作为非蛋白源的α-氨基酸存在于许多药剂中。因此，人们开发了许多策略来获取这一基团，但直接羧化方法仍未得到充分开发。在这里，我们采用 NHC/HAT 双催化策略来获得 2-氮杂烯丙基自由基，然后将其与原位生成的酯氮杂烯丙基自由基中间体耦合。随后的四面体中间体在碱介导下崩溃，释放出 NHC 催化剂和二苯甲酮保护的芳基甘氨酸。利用这种方法可以酯化获得各种芳基取代的甘氨酸衍生物以及烯丙基和苄基位点。机理研究表明，这种自由基过程可在氧化和还原淬灭循环下进行，而采用手性 NHC 和路易斯酸添加剂的初步实验则证明了适度的对映选择性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advanced Synthesis & Catalysis 化学-应用化学

CiteScore

9.40

自引率

7.40%

发文量

447

审稿时长

1.8 months

期刊介绍： Advanced Synthesis & Catalysis (ASC) is the leading primary journal in organic, organometallic, and applied chemistry. The high impact of ASC can be attributed to the unique focus of the journal, which publishes exciting new results from academic and industrial labs on efficient, practical, and environmentally friendly organic synthesis. While homogeneous, heterogeneous, organic, and enzyme catalysis are key technologies to achieve green synthesis, significant contributions to the same goal by synthesis design, reaction techniques, flow chemistry, and continuous processing, multiphase catalysis, green solvents, catalyst immobilization, and recycling, separation science, and process development are also featured in ASC. The Aims and Scope can be found in the Notice to Authors or on the first page of the table of contents in every issue.