Tunable Fungal Monofilaments from Food Waste for Textile Applications

IF 4.4 4区 综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES
E. R. Kanishka B Wijayarathna, Ghasem Mohammadkhani, Farshad Homayouni Moghadam, Linn Berglund, Jorge A. Ferreira, Karin H. Adolfsson, Minna Hakkarainen, Akram Zamani
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Abstract

A fungal biorefinery is presented to valorize food waste to fungal monofilaments with tunable properties for different textile applications. Rhizopus delemar is successfully grown on bread waste and the fibrous cell wall is isolated. A spinnable hydrogel is produced from cell wall by protonation of amino groups of chitosan followed by homogenization and concentration. Fungal hydrogel is wet spun to form fungal monofilaments which underwent post-treatments to tune the properties. The highest tensile strength of untreated monofilaments is 65 MPa (and 4% elongation at break). The overall highest tensile strength of 140.9 MPa, is achieved by water post-treatment. Moreover, post-treatment with 3% glycerol resulted in the highest elongation % at break, i.e., 14%. The uniformity of the monofilaments also increased after the post-treatments. The obtained monofilaments are compared with commercial fibers using Ashby's plots and potential applications are discussed. The wet spun monofilaments are located in the category of natural fibers in Ashby's plots. After water and glycerol treatments, the properties shifted toward metals and elastomers, respectively. The compatibility of the monofilaments with human skin cells is supported by a biocompatibility assay. These findings demonstrate fungal monofilaments with tunable properties fitting a wide range of sustainable textiles applications.

Abstract Image

从厨余垃圾中提取可调真菌单丝用于纺织品应用
本文介绍了一种真菌生物炼制技术,可将食物垃圾转化为真菌单丝,使其具有可调整的特性,用于不同的纺织品用途。Rhizopus delemar 成功地在面包废料上生长,并分离出纤维状细胞壁。通过壳聚糖氨基的质子化,然后进行均质化和浓缩,从细胞壁中制备出可纺丝的水凝胶。真菌水凝胶通过湿法纺丝形成真菌单丝,并经过后处理以调整其特性。未经处理的单丝的最高拉伸强度为 65 兆帕(断裂伸长率为 4%)。经过水后处理后,整体最高拉伸强度达到 140.9 兆帕。此外,用 3% 的甘油进行后处理可获得最高的断裂伸长率,即 14%。经过后处理后,单丝的均匀性也有所提高。利用阿什比图谱将获得的单丝与商业纤维进行了比较,并讨论了潜在的应用领域。在阿什比图谱中,湿纺单丝属于天然纤维。经过水和甘油处理后,其特性分别向金属和弹性体转变。单丝与人类皮肤细胞的相容性得到了生物相容性检测的支持。这些研究结果表明,真菌单丝具有可调整的特性,适合广泛的可持续纺织品应用。
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来源期刊
Global Challenges
Global Challenges MULTIDISCIPLINARY SCIENCES-
CiteScore
8.70
自引率
0.00%
发文量
79
审稿时长
16 weeks
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