Kato Daiki, Murase Tomoya, Talode Jalindar, Nagae Haruki, Tsurugi Hayato, Seki Masahiko, Mashima Kazushi
Department of Chemistry, Graduate School of Engineering Science, Osaka University, 560-8531, Toyonaka, Osaka, Japan.
Marketing Group Research & Development Division, Tokuyama Corporation, 300-4247, Tsukuba, Ibaraki, Japan.
Chemistry. 2022 May 6;28(26):e202200474. doi: 10.1002/chem.202200474. Epub 2022 Mar 29.
Ketones were selectively synthesized from thioesters by using diarylcuprates(I) generated in situ from copper(I) salts and aryl Grignard reagents in a 1 : 1.3-1.5 ratio under ambient temperature. During the ketone synthesis, various functional groups, such as carbonyl (ketones, esters, and amides), O-protecting groups, halogens, and heteroarenes, were tolerated to afford multifunctionalized ketones in excellent yields. This copper-mediated ketone synthesis could be applied to the synthesis of not only gluconolactone-derived ketone 6, a synthetic intermediate in the transformation to the SGLT2 inhibitor canagliflozin, but also thiolactol 8, a valuable synthetic intermediate for (+)-biotin. Control experiments on an isolated diphenylcuprate(I), [CuPh ] (12), and DFT calculations revealed that this ketone synthesis proceeded by oxidative addition of the C-S bond of thioesters to [CuPh ] , while reductive elimination from the Cu intermediate produced the corresponding ketone and an inactive species [(RS)CuPh] , the latter reacted with [CuPh] (11) to regenerate the reactive diphenylcuprate(I).
在室温下,通过铜(I)盐与芳基格氏试剂以1∶1.3 - 1.5的比例原位生成二芳基铜酸盐(I),从而从硫酯中选择性地合成酮。在酮的合成过程中,各种官能团,如羰基(酮、酯和酰胺)、O - 保护基、卤素和杂芳烃,都能耐受,从而以优异的产率得到多官能化的酮。这种铜介导的酮合成不仅可以应用于合成葡糖酸内酯衍生的酮6(它是转化为SGLT2抑制剂卡格列净的合成中间体),还可以应用于合成硫代内酯8(它是(+) - 生物素的有价值的合成中间体)。对分离出的二苯基铜酸盐(I)[CuPh₂](12)进行的对照实验以及密度泛函理论计算表明,这种酮的合成是通过硫酯的C - S键向[CuPh₂]进行氧化加成而进行的,而从铜中间体进行还原消除则生成相应的酮和一种无活性的物种[(RS)CuPh],后者与[CuPh₂](11)反应以再生活性二苯基铜酸盐(I)。