Yeast immobilisation for brewery fermentation

IF 2.4 3区农林科学 Q3 FOOD SCIENCE & TECHNOLOGY Journal of The Institute of Brewing Pub Date : 2021-10-17 DOI:10.1002/jib.671

Thiago M. Araujo, Marcelo C. Barga, Bianca E. Della-Bianca, Thiago O. Basso

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引用次数: 3

Abstract

Cell immobilisation is the physical restriction of cells in a delimited region by means of physical and chemical approaches. It usually comprises a solid support containing cell biomass. In brewing fermentations, yeast cell immobilisation was widely explored during the 1970s to the 90s, with the expectation that immobilised systems would revolutionise the brewing industry. The most studied immobilisation method has been the attachment to a surface and entrapment within a porous solid. Some industrial applications were developed, but the flavour profile of the product rarely matched that produced by batch fermentation. Numerous factors are important in immobilised yeast systems and its successful industrial implementation. Although cell immobilisation results in many advantages, such as high biomass loading and ease of cell reuse, there are drawbacks including physiological changes and mass transfer limitations. Therefore, in order to design a feasible brewing fermentation process using immobilised yeast cells, the solid support, immobilisation method and the bioreactor system require to be properly developed. In this review, yeast cell immobilisation technology in brewing is considered together with methods of immobilisation with the associated advantages and drawbacks. Physiological and metabolic alterations in yeast are also explored and industrial applications are highlighted. It is suggested that immobilisation technology has new opportunities as the market is increasingly open to novel flavours and styles. © 2021 The Institute of Brewing & Distilling

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啤酒发酵用酵母固定化

细胞固定化是通过物理和化学方法将细胞物理限制在一个划定的区域。它通常由含有细胞生物量的固体载体组成。在酿造发酵中，酵母细胞固定化在20世纪70年代到90年代被广泛探索，人们期望固定化系统将彻底改变酿造工业。研究最多的固定化方法是附着在表面并包裹在多孔固体中。已经开发了一些工业应用，但产品的风味特征很少与批量发酵生产的产品相匹配。在固定化酵母系统及其成功的工业实施中，有许多重要的因素。尽管细胞固定化具有许多优点，如高生物量负荷和易于细胞再利用，但也存在包括生理变化和传质限制在内的缺点。因此，为了设计一种可行的固定化酵母细胞酿造发酵工艺，需要对固体载体、固定化方法和生物反应器系统进行适当的开发。本文综述了酿酒中酵母细胞固定化技术及其固定化方法的优缺点。还探讨了酵母的生理和代谢变化，并强调了工业应用。这表明，随着市场对新颖口味和风格的日益开放，固定技术有了新的机遇。©2021 The Institute of Brewing;蒸馏

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来源期刊

Journal of The Institute of Brewing 工程技术-食品科技

CiteScore

6.20

自引率

7.70%

发文量

审稿时长

6 months

期刊介绍： The Journal has been publishing original research for over 125 years relating to brewing, fermentation, distilling, raw materials and by-products. Research ranges from the fundamental to applied and is from universities, research institutes and industry laboratories worldwide. The scope of the Journal is cereal based beers, wines and spirits. Manuscripts on cider may also be submitted as they have been since 1911. Manuscripts on fruit based wines and spirits are not within the scope of the Journal of the Institute of Brewing.