Microreaction and membrane technologies for continuous single-enantiomer production: A review

Catalysis Reviews Pub Date : 2021-09-28 DOI:10.1080/01614940.2021.1977009

Z. Petrusová, Z. Slouka, Lucie Vobecká, Petr Polezhaev, P. Hasal, M. Přibyl, P. Izák

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引用次数: 3

Abstract

ABSTRACT Microreaction and membrane technologies offer optimal conditions for controlling enantiomer synthesis and purification processes in continuous production, with numerous advantages over batch manufacturing. One of the many forces driving the development of such technologies for the production of single optical isomers is the need for enantiomerically pure pharmaceutical drugs because enantiomers may display opposite therapeutic effects or different treatment efficacies and side effects. Yet, despite advances in asymmetric synthesis and separation techniques, preparing enantiomerically pure compounds remains a challenging task. Here, we review the progress in microfluidics and membrane chiral separation over the last two decades. In addition to describing and critically assessing the state of the art in both disciplines, we provide an overview of their beneficial properties and characteristics for developing technologies toward producing enantiomerically pure compounds. Concomitantly, we evaluate efforts to integrate synthesis and membrane separation into a microfluidic platform and pinpoint the limiting factors that must be overcome before these platforms can be fully deployed in the industry.

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连续生产单对映体的微反应和膜技术综述

微反应和膜技术为连续生产中控制对映体的合成和纯化过程提供了最佳条件，与批量生产相比具有许多优势。推动这种生产单一光学异构体的技术发展的众多力量之一是对对映体纯药物的需求，因为对映体可能显示相反的治疗效果或不同的治疗效果和副作用。然而，尽管不对称合成和分离技术取得了进步，制备对映体纯化合物仍然是一项具有挑战性的任务。本文综述了近二十年来微流体和膜手性分离的研究进展。除了描述和批判性地评估这两个学科的最新进展外，我们还概述了它们的有益性质和特征，以开发生产对映异构纯化合物的技术。同时，我们评估了将合成和膜分离整合到微流控平台中的努力，并指出了在这些平台完全应用于工业之前必须克服的限制因素。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Catalysis Reviews

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