In situ product removal

Q2 Physics and Astronomy

Physical Sciences Reviews Pub Date : 2023-11-28 DOI:10.1515/psr-2022-0111

U. A. Salas-Villalobos, Oscar Aguilar

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引用次数: 0

Abstract

Abstract During current years, the industrial biotechnology area has grown at giant steps, supported by the necessity of a sustainable supply chain and the inevitable depletion of petrochemical feedstocks. From this accelerated growth, the need for the development of more efficient bioprocesses in term of productivity and cost has emerged. A substantial number of bioprocesses have their potential hindered by product inhibition, a phenomenon that appears due to microbial metabolites produced in concentrations that become toxic even for the producing microorganism. In situ product recovery (ISPR) appears as a strategy to overcome such problems by primary recovery stage to the upstream, thus continuously extracting a desired or undesired target molecule from the fermentation broth as soon as it is produced. In this chapter, we will review the inherent advantages of implementing this technology in the production process, not only in terms of productivity, but also in equipment. A revision across the main the ISPR technologies can be found, explaining their main mechanisms and configurations, the appropriate scenarios to use each one and the main factors that must be considered that affect process efficiency. The chapter will be divided into three parts according to the types of ISPR that are reviewed, liquid–liquid, solid–liquid and gas–liquid techniques. Some recent trends and further perspectives for each method are also mentioned leaving space for further analysis of these technologies.

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就地清除产品

摘要近年来，在可持续供应链的必要性和石油化工原料不可避免地枯竭的支持下，工业生物技术领域取得了长足的发展。在这一加速增长的过程中，出现了开发在生产率和成本方面更高效的生物工艺的需求。大量生物工艺的潜力受到了产品抑制的阻碍，这种现象的出现是由于微生物产生的代谢物浓度过高，甚至对生产微生物产生毒性。原位产物回收（ISPR）是一种克服此类问题的策略，它将初级回收阶段转移到上游，从而在所需或不想要的目标分子产生后立即从发酵液中持续提取出来。在本章中，我们将回顾在生产过程中采用这种技术的固有优势，不仅在生产率方面，而且在设备方面。我们将对 ISPR 的主要技术进行修订，解释其主要机制和配置、每种技术的适当使用场景以及影响工艺效率的主要因素。本章将根据所审查的 ISPR 类型（液-液、固-液和气-液技术）分为三个部分。此外，还提到了每种方法的一些最新趋势和进一步展望，为进一步分析这些技术留出了空间。

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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来源期刊

Physical Sciences Reviews MULTIDISCIPLINARY SCIENCES-

CiteScore

2.40

自引率

0.00%

发文量

173