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Hindered dialkyl ether synthesis with electrogenerated carbocations

Author

Listed:
  • Jinbao Xiang

    (Scripps Research
    The Center for Combinatorial Chemistry and Drug Discovery of Jilin University, The School of Pharmaceutical Sciences, Jilin University)

  • Ming Shang

    (Scripps Research)

  • Yu Kawamata

    (Scripps Research)

  • Helena Lundberg

    (Scripps Research
    KTH Royal Institute of Technology)

  • Solomon H. Reisberg

    (Scripps Research)

  • Miao Chen

    (Scripps Research)

  • Pavel Mykhailiuk

    (Scripps Research
    Enamine Ltd
    Taras Shevchenko National University of Kyiv)

  • Gregory Beutner

    (Bristol-Myers Squibb)

  • Michael R. Collins

    (La Jolla Laboratories, Pfizer Inc)

  • Alyn Davies

    (Pfizer Medicinal Sciences)

  • Matthew Bel

    (La Jolla Laboratories, Pfizer Inc)

  • Gary M. Gallego

    (La Jolla Laboratories, Pfizer Inc)

  • Jillian E. Spangler

    (La Jolla Laboratories, Pfizer Inc)

  • Jeremy Starr

    (Pfizer Medicinal Sciences)

  • Shouliang Yang

    (La Jolla Laboratories, Pfizer Inc)

  • Donna G. Blackmond

    (Scripps Research)

  • Phil S. Baran

    (Scripps Research)

Abstract

Hindered ethers are of high value for various applications; however, they remain an underexplored area of chemical space because they are difficult to synthesize via conventional reactions1,2. Such motifs are highly coveted in medicinal chemistry, because extensive substitution about the ether bond prevents unwanted metabolic processes that can lead to rapid degradation in vivo. Here we report a simple route towards the synthesis of hindered ethers, in which electrochemical oxidation is used to liberate high-energy carbocations from simple carboxylic acids. These reactive carbocation intermediates, which are generated with low electrochemical potentials, capture an alcohol donor under non-acidic conditions; this enables the formation of a range of ethers (more than 80 have been prepared here) that would otherwise be difficult to access. The carbocations can also be intercepted by simple nucleophiles, leading to the formation of hindered alcohols and even alkyl fluorides. This method was evaluated for its ability to circumvent the synthetic bottlenecks encountered in the preparation of 12 chemical scaffolds, leading to higher yields of the required products, in addition to substantial reductions in the number of steps and the amount of labour required to prepare them. The use of molecular probes and the results of kinetic studies support the proposed mechanism and the role of additives under the conditions examined. The reaction manifold that we report here demonstrates the power of electrochemistry to access highly reactive intermediates under mild conditions and, in turn, the substantial improvements in efficiency that can be achieved with these otherwise-inaccessible intermediates.

Suggested Citation

  • Jinbao Xiang & Ming Shang & Yu Kawamata & Helena Lundberg & Solomon H. Reisberg & Miao Chen & Pavel Mykhailiuk & Gregory Beutner & Michael R. Collins & Alyn Davies & Matthew Bel & Gary M. Gallego & Ji, 2019. "Hindered dialkyl ether synthesis with electrogenerated carbocations," Nature, Nature, vol. 573(7774), pages 398-402, September.
    • Handle: RePEc:nat:nature:v:573:y:2019:i:7774:d:10.1038_s41586-019-1539-y
    DOI: 10.1038/s41586-019-1539-y
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    Citations

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    Cited by:

    1. Xiangfeng Lin & Xia Mu & Hongqiang Cui & Qian Li & Zhaochi Feng & Yan Liu & Guohui Li & Can Li, 2024. "Diastereo-divergent synthesis of chiral hindered ethers via a synergistic calcium(II)/gold(I) catalyzed cascade hydration/1,4-addition reaction," Nature Communications, Nature, vol. 15(1), pages 1-13, December.
    2. Liang Ge & Chi Zhang & Chengkai Pan & Ding-Xing Wang & Dong-Ying Liu & Zhi-Qiang Li & Pingkang Shen & Lifang Tian & Chao Feng, 2022. "Photoredox-catalyzed C–C bond cleavage of cyclopropanes for the formation of C(sp3)–heteroatom bonds," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
    3. Kenji Ota & Kazunori Nagao & Dai Hata & Haruki Sugiyama & Yasutomo Segawa & Ryosuke Tokunoh & Tomohiro Seki & Naoya Miyamoto & Yusuke Sasaki & Hirohisa Ohmiya, 2023. "Synthesis of tertiary alkylphosphonate oligonucleotides through light-driven radical-polar crossover reactions," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    4. Min Liu & Tian Feng & Yanwei Wang & Guangsheng Kou & Qiuyan Wang & Qian Wang & Youai Qiu, 2023. "Metal-free electrochemical dihydroxylation of unactivated alkenes," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    5. Chen Zhu & Huifeng Yue & Magnus Rueping, 2022. "Nickel catalyzed multicomponent stereodivergent synthesis of olefins enabled by electrochemistry, photocatalysis and photo-electrochemistry," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    6. Heather A. Hintz & Christo S. Sevov, 2022. "Catalyst-controlled functionalization of carboxylic acids by electrooxidation of self-assembled carboxyl monolayers," Nature Communications, Nature, vol. 13(1), pages 1-7, December.

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