Nature Communications (Jul 2023)

Electrocatalyzed direct arene alkenylations without directing groups for selective late-stage drug diversification

  • Zhipeng Lin,
  • Uttam Dhawa,
  • Xiaoyan Hou,
  • Max Surke,
  • Binbin Yuan,
  • Shu-Wen Li,
  • Yan-Cheng Liou,
  • Magnus J. Johansson,
  • Li-Cheng Xu,
  • Chen-Hang Chao,
  • Xin Hong,
  • Lutz Ackermann

DOI
https://doi.org/10.1038/s41467-023-39747-0
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 8

Abstract

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Abstract Electrooxidation has emerged as an increasingly viable platform in molecular syntheses that can avoid stoichiometric chemical redox agents. Despite major progress in electrochemical C−H activations, these arene functionalizations generally require directing groups to enable the C−H activation. The installation and removal of these directing groups call for additional synthesis steps, which jeopardizes the inherent efficacy of the electrochemical C−H activation approach, leading to undesired waste with reduced step and atom economy. In sharp contrast, herein we present palladium-electrochemical C−H olefinations of simple arenes devoid of exogenous directing groups. The robust electrocatalysis protocol proved amenable to a wide range of both electron-rich and electron-deficient arenes under exceedingly mild reaction conditions, avoiding chemical oxidants. This study points to an interesting approach of two electrochemical transformations for the success of outstanding levels of position-selectivities in direct olefinations of electron-rich anisoles. A physical organic parameter-based machine learning model was developed to predict position-selectivity in electrochemical C−H olefinations. Furthermore, late-stage functionalizations set the stage for the direct C−H olefinations of structurally complex pharmaceutically relevant compounds, thereby avoiding protection and directing group manipulations.