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一种用于大尺寸至微型尺度C-H键硼化反应的空气稳定单组分铱预催化剂。

An Air-Stable, Single-Component Iridium Precatalyst for the Borylation of C-H Bonds on Large to Miniaturized Scales.

作者信息

D'Angelo Kyan A, La Chris, Kotecki Brian, Wilson Jake W, Karmel Caleb, Swiatowiec Rafal, Tu Noah P, Shekhar Shashank, Hartwig John F

机构信息

Department of Chemistry, University of California Berkeley, Berkeley, California 94720, United States.

Process Research and Development, AbbVie Inc., 1 North Waukegan Road, North Chicago, Illinois 60064, United States.

出版信息

J Am Chem Soc. 2024 Nov 27;146(47):32717-32729. doi: 10.1021/jacs.4c12333. Epub 2024 Nov 12.

DOI:10.1021/jacs.4c12333
PMID:39531608
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11651392/
Abstract

The functionalization of C-H bonds enables the modification of complex molecules, often with the intention of forming compound libraries. The borylation of aryl C-H bonds is a widely used class of C-H bond functionalization, and conventional catalyst systems for the borylation of C-H bonds consist of an iridium source and an ,-ligand, in conjunction with pinacolborane, to form the active iridium(III) tris(boryl) catalyst. These multicomponent catalyst systems complicate borylation reactions at large and small scales, due to the air sensitivity of the most common iridium precursor [Ir(cod)OMe], and, particularly on small scale, the challenges associated with dispensing multiple components with differing solubilities or that are air-sensitive. We describe the discovery of an air-stable, single-component iridium precatalyst, [(tmphen)Ir(coe)Cl], that generates the same active iridium(III) tris(boryl) catalyst and reacts with higher turnovers, comparable selectivity, and similar scope to those of known catalyst systems for the borylation of aryl and heteroaryl C-H bonds. We show how the development of this precatalyst enables reactions to be run on submicromole scale in a high-throughput experimentation format in conjunction with ChemBead technology, and with a second diversification step that illustrates the potential to diversify structures by chemical sequences involving catalytic reactions, including C-H bond functionalizations, on submicromole scales in the same reaction vessel.

摘要

C-H键的官能团化能够对复杂分子进行修饰,其目的通常是构建化合物库。芳基C-H键的硼化反应是一类广泛应用的C-H键官能团化反应,传统的C-H键硼化反应催化剂体系由铱源、配体以及频哪醇硼烷组成,用于形成活性铱(III)三(硼基)催化剂。这些多组分催化剂体系使得大规模和小规模的硼化反应都变得复杂,这是由于最常见的铱前体[Ir(cod)OMe]对空气敏感,尤其是在小规模反应中,还存在着分配具有不同溶解度或对空气敏感的多种组分的挑战。我们报道了一种空气稳定的单组分铱预催化剂[(tmphen)Ir(coe)Cl]的发现,它能生成相同的活性铱(III)三(硼基)催化剂,并且在芳基和杂芳基C-H键硼化反应中,其反应具有更高的周转率、相当的选择性以及与已知催化剂体系类似的底物范围。我们展示了这种预催化剂的开发如何使得反应能够在亚微摩尔规模上以高通量实验形式结合ChemBead技术进行,并且通过第二步多样化步骤说明了在同一反应容器中通过涉及催化反应(包括C-H键官能团化)的化学序列在亚微摩尔规模上实现结构多样化的潜力。

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