Cocrystallization‐Induced Spontaneous Deracemization: A General Thermodynamic Approach to Deracemization

Processes leading to enantiomerically pure compounds are of utmost importance, in particular for the pharmaceutical industry. Starting from a racemic mixture, crystallization‐induced diastereomeric transformation allows in theory for 100 % transformation of the desired enantiomer. However, this meth...

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Veröffentlicht in:	Angewandte Chemie 2020-07, Vol.132 (28), p.11399-11402
Hauptverfasser:	Guillot, Michael, Meester, Joséphine, Huynen, Sarah, Collard, Laurent, Robeyns, Koen, Riant, Olivier, Leyssens, Tom
Format:	Artikel
Sprache:	eng
Schlagworte:	Chemistry chiral resolution Cocrystallization cocrystals Crystallization deracemization Enantiomers Feasibility studies Fungicides Organic compounds Pharmaceutical industry thermodynamics
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creator	Guillot, Michael Meester, Joséphine Huynen, Sarah Collard, Laurent Robeyns, Koen Riant, Olivier Leyssens, Tom
description	Processes leading to enantiomerically pure compounds are of utmost importance, in particular for the pharmaceutical industry. Starting from a racemic mixture, crystallization‐induced diastereomeric transformation allows in theory for 100 % transformation of the desired enantiomer. However, this method has the inherent limiting requirement for the organic compound to form a salt. Herein, this limitation is lifted by introducing cocrystallization in the context of thermodynamic deracemization, with the process applied to a model chiral fungicide. We report a new general single thermodynamic deracemization process based on cocrystallization for the deracemization of (R,S)‐4,4‐dimethyl‐1‐(4‐fluorophenyl)‐2‐(1H‐1,2,4‐triazol‐1‐yl)pentan‐3‐one. This study demonstrates the feasibility of this novel approach and paves the way to further development of such processes. One model to fit all: As a general approach to deracemization, cocrystallization‐induced spontaneous deracemization takes advantage of the universal dimension of cocrystallization to create a pair of diastereomers and combines it with a racemization reaction in solution (see picture). This model was successfully applied to a fungicide, the deracemization of which was not possible by established methods.
doi_str_mv	10.1002/ange.202002464
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subjects	Chemistry chiral resolution Cocrystallization cocrystals Crystallization deracemization Enantiomers Feasibility studies Fungicides Organic compounds Pharmaceutical industry thermodynamics
title	Cocrystallization‐Induced Spontaneous Deracemization: A General Thermodynamic Approach to Deracemization
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