光氧化还原吲哚氰甲基化反应:催化剂修饰与反应机理。
Photoredox Cyanomethylation of Indoles: Catalyst Modification and Mechanism.
机构信息
Institute for Neurodegenerative Diseases (IND), UCSF Weill Institute for Neurosciences , University of California , San Francisco , California 94158 , United States.
出版信息
J Org Chem. 2018 Aug 17;83(16):8926-8935. doi: 10.1021/acs.joc.8b01146. Epub 2018 Jul 6.
Abstract
The direct cyanomethylation of indoles at the 2- or 3-position was achieved via photoredox catalysis. The versatile nitrile synthon is introduced as a radical generated from bromoacetonitrile, a photocatalyst, and blue LED as a light source. The mechanism of the reaction is explored by determination of the Stern-Volmer quenching constants. By combining photophysical data and mass spectrometry to follow the catalyst decomposition, the catalyst ligands were tuned to enable synthetically useful yields of radical coupling products. A range of indole substrates with alkyl, aryl, halogen, ester, and ether functional groups participate in the reaction, affording products in 16-90% yields. The reaction allows the rapid construction of synthetically useful cyanomethylindoles, products that otherwise require several synthetic steps.
摘要
通过光氧化还原催化实现了吲哚在 2-位或 3-位的直接氰甲基化。多用途的腈合成子是通过溴乙腈、光催化剂和蓝 LED 作为光源生成的自由基引入的。通过确定斯特恩-沃尔默猝灭常数来探究反应的机理。通过结合光物理数据和质谱来跟踪催化剂的分解,对催化剂配体进行了调整,从而实现了自由基偶联产物的合成有用产率。一系列带有烷基、芳基、卤素、酯和醚官能团的吲哚底物参与反应,以 16-90%的产率得到产物。该反应允许快速构建合成有用的氰甲基吲哚,否则这些产物需要经过几个合成步骤。
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