利用马齿苋生物质生产纳米纤维素

Q2 Materials Science
Stanislav Sukhikh , Olga Babich , Svetlana Ivanova , Olga Kriger , Alexander Prosekov , Svetlana Noskova , Elena Ulrikh , Ekaterina Budenkova , Olga Kalashnikova
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引用次数: 0

摘要

纳米纤维素材料以其安全性、生物降解性和适应性而著称。研究表明,细菌纳米纤维素不含木质素和半纤维素,具有超细网络结构。这种材料与生物分子的广泛兼容性和改变其结构的能力,使纳米纤维素成为一种很有前途的医疗应用材料。目前,纳米纤维素的生产主要使用软木。尽管纳米纤维素具有明显的优势,但生产中的限制因素是木材原料的高成本以及砍伐森林对环境造成的破坏。因此,人们对廉价且每年可再生的草本植物生物质越来越感兴趣,这是一种潜在的负成本合成纳米纤维素的原材料。本综述旨在评估使用马齿苋属植物作为纳米纤维素主要来源的可行性。文章讨论了各类纳米纤维素的特性以及从木棉中制备纳米纤维素的方法。马齿苋植物抗病、抗冻、生长迅速。这种植物的生物量每公顷可达 35 吨,寿命长达 20 年。由于马齿苋含有丰富的纤维素,因此是一种很有前景的纳米纤维素晶体来源。开发出获取纳米纤维素的有效方法后,就可以引入一类新材料,用于生产生物技术复合液体和固体成分,以及食品、医疗和制药行业的原材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Production of nanocellulose from miscanthus biomass

Production of nanocellulose from miscanthus biomass

Nanocellulose materials are distinguished by their safety, biodegradability, and adaptability. It was shown that bacterial nanocellulose does not contain lignin and hemicellulose and has an ultrafine network structure. The wide compatibility of such materials with biological molecules and the ability to change their structure makes nanocellulose a promising material for medical applications. Today, in the production of nanocellulose, mainly softwood is used. Despite the obvious advantages of nanocellulose, the limiting factor in production is the high cost of wood raw materials and the environmental damage caused by deforestation. Therefore, there is increasing interest in cheap and annually renewable herbaceous plant biomass, which is a potential raw material with a negative cost for the synthesis of nanocellulose. This review aimed to evaluate the viability of using Miscanthus plant genus as the primary source of nanocellulose. The characteristics of various types of nanocellulose and methods for their preparation from miscanthus are discussed. Miscanthus plants are disease resistant, frost resistant, and grow rapidly. The biomass growth of this plant reaches 35 tons per hectare, and the life span of miscanthus reaches 20 years. Miscanthus is a promising source of nanocellulose crystals because it is rich cellulose. The development of effective methods for obtaining nanocellulose will allow the introduction of a new class of materials for the production of biotechnical composite liquid and solid compositions, as well as raw materials for the food, medical, and pharmaceutical industries.

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来源期刊
Current Research in Green and Sustainable Chemistry
Current Research in Green and Sustainable Chemistry Materials Science-Materials Chemistry
CiteScore
11.20
自引率
0.00%
发文量
116
审稿时长
78 days
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