利用细菌群落从农业废弃物中生产生物塑料的可能性和前景:在废物管理中寻找一线生机

IF 4.8 Q1 MICROBIOLOGY
Mamun Mandal , Anamika Roy , Debasis Mitra , Abhijit Sarkar
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引用次数: 0

摘要

为了满足全球人口增长的需要,现代农业面临着生产更多粮食以及纤维、木材、生物燃料等的巨大挑战,因此产生了更多废物。农业废弃物(农业废弃物)的持续增长及其管理策略引起了全世界的关注,因为它对环境造成了严重的影响,包括空气、土壤和水污染。同样,对未来可持续发展的日益关注也推动了生物聚合物的发展,生物聚合物是生物体内存在和/或由生物体产生的物质,可替代各种有害的合成聚合物,尤其是石油基塑料。现在,农业废弃物的成分为通过机械和微生物程序生产生物塑料提供了令人鼓舞的机会。即使是微生物(包括细菌和真菌)系统,也能带来更低的能耗和更好的生态友好型替代品。这篇综述主要集中于编目和了解从各种农业废弃物中开发生物塑料的细菌 "投入"。特别是,Cupriavidus necator、Chromatium vinosum 和 Pseudomonas aeruginosa 等细菌利用淀粉(来自玉米和马铃薯废料)和纤维素(来自甘蔗渣和玉米皮废料)生产短链和中链长的聚(3-羟基烷基)(P3HB)聚合物。同样,C. necator 和转化体 Wautersia eutropha 利用脂基成分(如棕榈油废料)生产 P3HB 聚合物。值得注意的是,这些聚合物的合成与细菌的一般代谢活动相互关联,例如克雷布斯循环、糖酵解循环、β-氧化、卡尔文循环、新脂肪酸合成等。总之,农业废弃物是利用细菌群落生产生物塑料的合理低成本原料;整个过程无疑为可持续废物管理战略提供了机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Possibilities and prospects of bioplastics production from agri-waste using bacterial communities: Finding a silver-lining in waste management

Possibilities and prospects of bioplastics production from agri-waste using bacterial communities: Finding a silver-lining in waste management

To meet the need of the growing global population, the modern agriculture faces tremendous challenges to produce more food as well as fiber, timber, biofuels, etc.; hence generates more waste. This continuous growth of agricultural waste (agri-waste) and its management strategies have drawn the attention worldwide because of its severe environmental impacts including air, soil and water pollution. Similarly, growing concerns about the sustainable future have fuelled the development of biopolymers, substances occurring in and/or produced by living organisms, as substitute for different synthetic and harmful polymers, especially petroleum-based plastics. Now, the components of agri-waste offer encouraging opportunities for the production of bioplastics through mechanical and microbial procedures. Even the microbial, both bacterial and fungal, system results in lower energy consumption and better eco-friendly alternatives. The review mainly concentrates on cataloging and understanding the bacterial 'input' in developing bioplastics from diverse agri-waste. Especially, the bacteria like Cupriavidus necator, Chromatium vinosum, and Pseudomonas aeruginosa produce short- and medium-chain length poly(3-hydroxyalkanote) (P3HB) polymers using starch (from corn and potato waste), and cellulose (from sugarcane bagasse, corn husks waste). Similarly, C. necator, and transformant Wautersia eutropha produce P3HB polymer using lipid-based components (such as palm oil waste). Important to note that, the synthesis of these polymers are interconnected with the bacterial general metabolic activities, for example Krebs cycle, glycolysis cycle, β-oxidation, calvin cycle, de novo fatty acid syntheses, etc. Altogether, the agri-waste is reasonably low-cost feed for the production of bioplastics using bacterial communities; and the whole process certainly provide an opportunity towards sustainable waste management strategy.

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来源期刊
Current Research in Microbial Sciences
Current Research in Microbial Sciences Immunology and Microbiology-Immunology and Microbiology (miscellaneous)
CiteScore
7.90
自引率
0.00%
发文量
81
审稿时长
66 days
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