Flow chemistry-enabled asymmetric synthesis of cyproterone acetate in a chemo-biocatalytic approach
Yajiao Zhang, Minjie Liu, Xianjing Zheng, Liang Gao, Wan Li, Dang Cheng, Fen‐Er Chen
Abstract
Flow chemistry has many advantages over batch synthesis of organic small-molecules in terms of environmental compatibility, safety and synthetic efficiency when scale-up is considered. Herein, we report the 10-step chemo-biocatalytic continuous flow asymmetric synthesis of cyproterone acetate (4) in which 10 transformations are combined into a telescoped flow linear sequence from commercially available 4-androstene-3, 17-dione (11). This integrated one-flow synthesis features an engineered 3-ketosteroid-Δ1-dehydrogenase (ReM2)-catalyzed Δ1-dehydrogenation to form the C1, C2-double bond of A ring, a substrate-controlled Co-catalyzed Mukaiyama hydration of 9 to forge the crucial chiral C17α-OH group of D ring with excellent stereoselectivity, and a rapid flow Corey-Chaykovsky cyclopropanation of 7 to build the cyclopropyl core of A ring. By strategic use of these three key reactions and fully continuous-flow operations, cyproterone acetate (4) is produced in an overall yield of 9.6% in 3 h of total reaction time, this is the highest total number of chemical transformation performance in any other continuous-flow synthesis reported to date. Flow chemistry has many advantages over batch synthesis of organic small molecules in terms of environmental compatibility, safety and synthetic efficiency when scale-up is considered. Herein, the authors report a 10-step chemobiocatalytic, continuous-flow asymmetric synthesis of cyproterone acetate in which 10 transformations are combined into a telescoped flow linear sequence from commercially available 4-androstene-3,17-dione.