Dry gel spinning of fungal hydrogels for the development of renewable yarns from food waste.

Q1 Agricultural and Biological Sciences Fungal Biology and Biotechnology Pub Date : 2024-08-02 DOI:10.1186/s40694-024-00178-1
Alice Lindh, E R Kanishka B Wijayarathna, Göksu Cinar Ciftci, Samira Syed, Tariq Bashir, Nawar Kadi, Akram Zamani
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Abstract

Background: Renewable materials made using environmentally friendly processes are in high demand as a solution to reduce the pollution created by the fashion industry. In recent years, there has been a growing trend in research on renewable materials focused on bio-based materials derived from fungi.

Results: Recently, fungal cell wall material of a chitosan producing fungus has been wet spun to monofilaments. This paper presents a modification for the fungal monofilament spinning process, by the development of a benign method, dry gel spinning, to produce continuous monofilaments and twisted multifilament yarns, from fungal cell wall, that can be used in textile applications. The fungal biomass of Rhizopus delemar, grown using bread waste as a substrate, was subjected to alkali treatment with a dilute sodium hydroxide solution to isolate alkali-insoluble material (AIM), which mainly consists of the fungal cell wall. The treatment of AIM with dilute lactic acid resulted in hydrogel formation. The morphology of the hydrogels was pH dependent, and they exhibited shear thinning viscoelastic behavior. Dry gel spinning of the fungal hydrogels was first conducted using a simple lab-scale syringe pump to inject the hydrogels through a needle to form a monofilament, which was directly placed on a rotating receiver and left to dry at room temperature. The resulting monofilament was used to make twisted multifilament yarns. The process was then improved by incorporating a heated chamber for the quicker drying of the monofilaments (at 30⁰C). Finally, the spinning process was scaled up using a twin-screw microcompounder instead of the syringe pump. The monofilaments were several meters long and reached a tensile strength of 63 MPa with a % elongation at break of 14. When spinning was performed in the heated chamber, the tensile strength increased to 80 MPa and further increased to 103 MPa when a micro-compounder was used for spinning.

Conclusion: The developed dry gel spinning method shows promising results in scalability and demonstrates the potential for renewable material production using fungi. This novel approach produces materials with mechanical properties comparable to those of conventional textile fibers.

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利用真菌水凝胶的干凝胶纺丝技术,从食物垃圾中开发可再生纱线。
背景:采用环保工艺生产的可再生材料作为减少时装业污染的一种解决方案,受到了广泛的关注。近年来,有关可再生材料的研究呈上升趋势,重点研究从真菌中提取的生物基材料:最近,一种生产壳聚糖的真菌细胞壁材料被湿法纺成单丝。本文对真菌单丝纺丝工艺进行了改进,开发了一种良性方法--干凝胶纺丝法,利用真菌细胞壁生产连续单丝和加捻多丝纱线,可用于纺织品应用。以面包废料为基质培养的根瘤菌(Rhizopus delemar)的真菌生物质经过稀氢氧化钠溶液的碱处理,分离出碱不溶物(AIM),其中主要包括真菌细胞壁。用稀乳酸处理 AIM 后形成水凝胶。水凝胶的形态与 pH 值有关,并表现出剪切稀化粘弹性行为。真菌水凝胶的干凝胶纺丝首先使用一个简单的实验室规模注射泵,通过针头注入水凝胶形成单丝,然后直接将其放在旋转接收器上,在室温下静置干燥。得到的单丝可用于制造加捻多丝纱线。随后,为了加快单丝的干燥速度(30⁰C),该工艺又进行了改进,加入了一个加热室。最后,使用双螺杆微成型机取代注射泵,扩大了纺丝工艺的规模。单丝长达数米,拉伸强度达到 63 兆帕,断裂伸长率为 14%。在加热室中纺丝时,拉伸强度增加到 80 兆帕,使用微型压片机纺丝时,拉伸强度进一步增加到 103 兆帕:结论:所开发的干凝胶纺丝方法在可扩展性方面显示出良好的效果,并证明了利用真菌生产可再生材料的潜力。这种新方法生产出的材料具有与传统纺织纤维相当的机械性能。
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
Fungal Biology and Biotechnology
Fungal Biology and Biotechnology Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
10.20
自引率
0.00%
发文量
17
审稿时长
9 weeks
期刊最新文献
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