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perform the asymmetric hydrogenation of prochiral ketones without protective groups that are common in traditional organic synthesis [144, 145]. Although asymmetric reduction of ketones to optically pure alcohols has become quite mature in asymmetric synthesis during the last decade, it is still the most interesting strategy in preparing single enantiomers of alcohols by recent advancement in genetic engineering, coupled enzyme reaction, reaction design, and the availability of a variety of ADH. At least 150 different ADHs are available from various commercial sources, which allow the most suitable ADH to be selected for a specific substrate to access the desired (S)‐ or (R)‐enantiomer. The following are a concise introduction of the synthetic strategies used for the preparation of optically pure alcohol recently.

Chemical reaction depicting asymmetric reduction of ketone precursor o-chloroacetophenone with recombining microorganism toward chiral alcohol product. Chemical reaction depicting structure of aprepitant. Chemical reaction depicting the asymmetric synthesis of 3,5-bis(trifluoromethyl) acetophenone to (1R)-[3,5-bis(trifluoromethyl)phenyl] ethanol. Chemical reaction depicting bioreduction of α-haloketones in aqueous medium using different alcohol dehydrogenase followed by a series of chemical modifications to optically pure miconazole or econazole. Chemical reaction depicting e. coli or S. cerevisiae catalyzed reduction.

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