Mycelium as a self-growing biobased material for the fabrication of single-layer masks

IF 20.2 Q1 MATERIALS SCIENCE, PAPER & WOOD
Victoria French, Chuanshen Du, E. Johan Foster
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引用次数: 0

Abstract

Disposable face masks are an essential piece of personal protective equipment for workers in medical facilities, laboratories, and the general public to prevent the spread of illnesses and/or contamination. Covid-19 resulted in an uptick in the usage and production of face masks, exacerbating issues related to the waste and recycling of these materials. Traditionally, face masks are derived from petrochemicals, such as melt-blown or spunbound polypropylene. As such, there is a need to find sustainable mask materials that can maintain or improve the performance of petrochemical masks. This paper explores an alternative mask material that utilizes fungal mycelium as self-growing filaments to enhance the efficiency of individual polypropylene mask layers. By engineering the growth pattern and time, breathability and filtration efficiency was optimized such that one layer of the mycelium-modified mask could replace all three layers of the traditional three-layer mask. Additionally, it was found that the mycelium-modified mask exhibits asymmetric hydrophobicity, with super-hydrophobicity at the composite-air interface and lower hydrophobicity at the composite-medium interface. This property can improve the performance of the modified mask by protecting the mask from external liquids without trapping water vapor from the user's breath. The findings from this study can provide a basis for further development of mycelium to create sustainable filtration materials with enhanced functionality.

菌丝体作为一种自生长的生物基材料,用于制作单层掩膜
一次性口罩是医疗机构、实验室和公众工作人员防止疾病传播和/或污染的重要个人防护设备。新冠肺炎导致口罩的使用和生产增加,加剧了与这些材料的浪费和回收有关的问题。传统上,口罩来源于石化产品,如熔喷或纺粘聚丙烯。因此,需要找到能够保持或提高石化口罩性能的可持续口罩材料。本文探索了一种替代口罩材料,该材料利用真菌菌丝体作为自生长细丝,以提高单个聚丙烯口罩层的效率。通过设计生长模式和时间,优化了透气性和过滤效率,使一层菌丝体改性口罩可以取代传统三层口罩的全部三层。此外,还发现菌丝体改性口罩表现出不对称疏水性,在复合空气界面具有超疏水性,而在复合介质界面具有较低的疏水性。这种特性可以通过保护口罩不受外部液体的影响而提高改良口罩的性能,而不会捕获用户呼吸中的水蒸气。这项研究的发现可以为菌丝体的进一步开发提供基础,以创造具有增强功能的可持续过滤材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Bioresources and Bioproducts
Journal of Bioresources and Bioproducts Agricultural and Biological Sciences-Forestry
CiteScore
39.30
自引率
0.00%
发文量
38
审稿时长
12 weeks
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