γ 位胺的 C-H 官能团化:通过乙烯砜基自由基辅助的三重 H 原子转移。
γ C-H Functionalization of Amines via Triple H-Atom Transfer of a Vinyl Sulfonyl Radical Chaperone.
机构信息
Department of Chemistry and Biochemistry, The Ohio State University, Columbus, Ohio 43210, United States.
出版信息
J Am Chem Soc. 2022 Jul 27;144(29):13366-13373. doi: 10.1021/jacs.2c05266. Epub 2022 Jul 12.
Abstract
A selective, remote desaturation has been developed to rapidly access homoallyl amines from their aliphatic precursors. The strategy employs a triple H-atom transfer (HAT) cascade, entailing (i) cobalt-catalyzed metal-HAT (MHAT), (ii) carbon-to-carbon 1,6-HAT, and (iii) Co-H regeneration via MHAT. A new class of sulfonyl radical chaperone (to rapidly access and direct remote, radical reactivity) enables remote desaturation of diverse amines, amino acids, and peptides with excellent site-, chemo-, and regioselectivity. The key, enabling C-to-C HAT step in this cascade was computationally designed to satisfy both thermodynamic (bond strength) and kinetic (polarity) requirements, and it has been probed via regioselectivity, isomerization, and competition experiments. We have also interrupted this radical transfer dehydrogenation to achieve γ-selective C-Cl, C-CN, and C-N bond formations.
摘要
已经开发出一种选择性的远程去饱和化方法,可从其脂肪族前体快速获得偕烯丙基胺。该策略采用了三重 H 原子转移 (HAT) 级联反应,包括 (i) 钴催化的金属-HAT (MHAT),(ii) 碳-碳 1,6-HAT,以及 (iii) 通过 MHAT 再生 Co-H。一种新的磺酰基自由基辅助剂(可快速获得并直接进行远程自由基反应)能够实现各种胺、氨基酸和肽的远程去饱和化,具有出色的位点、化学和区域选择性。该级联反应中的关键 C-C HAT 步骤是通过计算设计来满足热力学(键强度)和动力学(极性)要求的,并通过区域选择性、异构化和竞争实验进行了验证。我们还中断了这种自由基转移脱氢反应,实现了γ-选择性的 C-Cl、C-CN 和 C-N 键形成。
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