封装酵母(尤其是海藻酸盐和壳聚糖中的酵母)作为智能生物反应器和智能微型机械的潜在应用

Alireza Sadeghi , Maryam Ebrahimi , Sara Shahryari , Elham Assadpour , Seid Mahdi Jafari
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引用次数: 0

摘要

虽然已有一些关于酵母细胞及其成分作为功能载体或有前景的结构成分封装生物活性化合物的基本应用报道,但关于封装酵母(EYs)潜在应用的评论较少。最近,封装酵母在生物技术不同领域的工业应用日益受到关注,如毒素或重金属的生物修复、生物过滤、生物催化剂或生物乙醇生产等。酵母细胞大多被包裹在海藻酸盐、壳聚糖和其他一些基于多糖的涂层材料中。这些平台使我们能够提高益生菌酵母在食品、饲料和胃肠道转运过程中的存活率,并改善其粘附性和定向输送。此外,利用封装策略还能提高酵母菌对高浓度酒精的耐热性和稳定性,以及在不同发酵食品的工业加工过程中提高产量。这些具有成本效益和可扩展性的基质还具有多种创新潜力,可用于构建活细胞与工程聚合物或壳内细胞混合体的复合体,以改变产品的技术功能和感官特性,以及细胞固定、细胞表面工程和程序化智能涂层形成和/或降解。
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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Potential applications of encapsulated yeasts especially within alginate and chitosan as smart bioreactors and intelligent micro-machines

Although several fundamental applications have been reported for yeast cells and their components as functional vehicles or promising structural ingredients in encapsulation of bioactive compounds; meanwhile, potential applications of encapsulated yeasts (EYs) have been less reviewed. Recently, EYs have received increasing attention for industrial applications in different areas of biotechnology such as bioremediation of toxins or heavy metals, bio-filtration, and biocatalyst or bioethanol production. Yeast cells are mostly encapsulated within alginate, chitosan, and some other polysaccharide-based coating materials. These platforms enable us to enhance survivability of probiotic yeasts in food, feed and gastrointestinal transit, as well as to improve their mucoadhesion and targeted delivery. Furthermore, increased thermo-tolerance and stability of yeasts towards high concentrations of alcohols, as well as their improved yield during industrial processing of different fermented foods have been revealed using encapsulation strategies. These cost-effective and scalable matrices have also several innovative potentials to construct composite of living cells and engineered polymers or cell-in-shell hybrids in order to modify techno-functional and sensory properties of the product, as well as cell immobilization, cell-surface engineering and programmed intelligent coating formation and/or degradation.

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