Quantification of fungal biomass in mycelium composites made from diverse biogenic side streams.

Q1 Agricultural and Biological Sciences
Marcello Nussbaumer, Tanja Karl, J Philipp Benz
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引用次数: 0

Abstract

Mycelium composite materials are comprised of renewable organic substrates interconnected by fungal mycelium, allowing full biodegradability after use. Due to their promising material properties, adaptability, and sustainable nature, these biomaterials are investigated intensively. However, one crucial aspect that has hardly been covered so far is the proportion of fungal biomass in the composites, which would be necessary to assess its contribution to the material characteristics. Since a complete physical separation of mycelium and substrate is not feasible, we approached this issue by isolating the fungal DNA and relating it to the mass of mycelium with the help of quantitative PCR. Overall, 20 different combinations of fungi and biogenic side streams were evaluated for their handling stability, and growth observations were related to the quantification results. Ganoderma sessile was able to form stable composites with almost all substrates, and a positive correlation between mycelial biomass and composite stability could be found. However, the amount of mycelium required for fabricating firm materials strongly depends on the combination of substrate and fungal species used. Less than five mass percent of fungal biomass can suffice to achieve this, as for example when combining Trametes versicolor with sugar beet pulp, whereas a mass fraction of twenty percent leads to crumbly materials when using Pleurotus pulmonarius on green waste. These results indicate that the mycelial biomass is an important factor for the composite's stability but that the properties of the fungal hyphae, as well as those of the substrate, are also relevant. The presented quantification method not only allows to estimate fungal growth during composite production but can also improve our understanding of how the mycelium influences the material.

用不同生物侧流制成的菌丝复合材料中真菌生物量的定量。
菌丝复合材料由真菌菌丝相互连接的可再生有机基材组成,使用后可完全生物降解。由于这些生物材料具有良好的材料特性、适应性和可持续发展性,人们对它们进行了深入研究。然而,迄今为止,真菌生物质在复合材料中所占的比例是一个几乎没有涉及的重要方面,这对于评估真菌生物质对材料特性的贡献十分必要。由于无法将菌丝和基质完全物理分离,我们通过分离真菌 DNA 并借助定量 PCR 将其与菌丝质量联系起来来解决这个问题。总之,我们对真菌和生物侧流的 20 种不同组合的处理稳定性进行了评估,并将生长观察结果与定量结果联系起来。无梗灵芝几乎能与所有基质形成稳定的复合材料,而且菌丝生物量与复合材料的稳定性呈正相关。然而,制造坚固材料所需的菌丝数量在很大程度上取决于所使用的基质和真菌种类的组合。例如,在甜菜纸浆中加入多色真菌(Trametes versicolor)时,少于百分之五的真菌生物量就足以达到这一要求;而在绿色废料中加入肺吸虫(Pleurotus pulmonarius)时,百分之二十的生物量就会导致材料变得松软。这些结果表明,菌丝生物量是影响复合材料稳定性的一个重要因素,但真菌菌丝的特性以及基质的特性也很重要。所介绍的定量方法不仅可以估计复合材料生产过程中真菌的生长情况,还可以提高我们对菌丝如何影响材料的认识。
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
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