建立了用于复合材料生产的担子菌。

Q1 Agricultural and Biological Sciences Fungal Biology and Biotechnology Pub Date : 2022-02-24 DOI:10.1186/s40694-022-00133-y
Carsten Pohl, Bertram Schmidt, Tamara Nunez Guitar, Sophie Klemm, Hans-Jörg Gusovius, Stefan Platzk, Harald Kruggel-Emden, Andre Klunker, Christina Völlmecke, Claudia Fleck, Vera Meyer
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引用次数: 11

摘要

背景:担子菌门的丝状真菌被认为是复合材料生物技术生产的一个有吸引力的来源。许多担子菌能够接受来自农业和林业的残余木质纤维素植物生物量,如秸秆、木屑和锯末作为底物,并将这些松散但增强的底物颗粒结合和粘合在一起,形成它们的菌丝网络,这使它们成为在不久的将来生产生物复合材料以取代石油基合成塑料和泡沫的理想候选者。结果:本文首次描述了火种真菌Fomes fomentarius在实验室规模生产菌丝复合材料方面的应用潜力。我们用麻屑和油菜籽秸秆的细、中、粗颗粒组分制备了一套多样化的复合材料,并表明材料的力学性能取决于基材的性质和颗粒大小。压缩试验和扫描电子显微镜用于表征复合材料的特性,并通过数值模拟模拟其压缩行为。它们的性能相互比较,并与基准膨胀聚苯乙烯(EPS)进行比较,EPS是一种用于建筑行业隔热的石油基泡沫。分析发现,EPS的弹性模量为2.37±0.17 MPa,是真菌复合材料的4倍,而抗压强度为0.09±0.003 MPa,在真菌复合材料的范围内。然而,当比较较高应变值下真菌复合材料承受压缩力的能力时,真菌复合材料的表现优于EPS。在50%压缩时,大麻基复合材料的抗压缩力为0.2 MPa,油菜籽基复合材料的抗压缩力为0.3 MPa, EPS仅为0.15 MPa。结论:本研究获得的数据表明,F. fomentarius是未来生产具有与合成泡沫(如EPS)相似力学性能的真菌复合材料的有希望的细胞工厂。未来的工作将集中在通过优化基质特性、培养条件和调节F. fomentarius的生长和细胞壁组成(即在中观和微观水平上影响复合行为的因素)来设计材料特性。
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Establishment of the basidiomycete Fomes fomentarius for the production of composite materials.

Background: Filamentous fungi of the phylum Basidiomycota are considered as an attractive source for the biotechnological production of composite materials. The ability of many basidiomycetes to accept residual lignocellulosic plant biomass from agriculture and forestry such as straw, shives and sawdust as substrates and to bind and glue together these otherwise loose but reinforcing substrate particles into their mycelial network, makes them ideal candidates to produce biological composites to replace petroleum-based synthetic plastics and foams in the near future.

Results: Here, we describe for the first time the application potential of the tinder fungus Fomes fomentarius for lab-scale production of mycelium composites. We used fine, medium and coarse particle fractions of hemp shives and rapeseed straw to produce a set of diverse composite materials and show that the mechanical materials properties are dependent on the nature and particle size of the substrates. Compression tests and scanning electron microscopy were used to characterize composite material properties and to model their compression behaviour by numerical simulations. Their properties were compared amongst each other and with the benchmark expanded polystyrene (EPS), a petroleum-based foam used for thermal isolation in the construction industry. Our analyses uncovered that EPS shows an elastic modulus of 2.37 ± 0.17 MPa which is 4-times higher compared to the F. fomentarius composite materials whereas the compressive strength of 0.09 ± 0.003 MPa is in the range of the fungal composite material. However, when comparing the ability to take up compressive forces at higher strain values, the fungal composites performed better than EPS. Hemp-shive based composites were able to resist a compressive force of 0.2 MPa at 50% compression, rapeseed composites 0.3 MPa but EPS only 0.15 MPa.

Conclusion: The data obtained in this study suggest that F. fomentarius constitutes a promising cell factory for the future production of fungal composite materials with similar mechanical behaviour as synthetic foams such as EPS. Future work will focus on designing materials characteristics through optimizing substrate properties, cultivation conditions and by modulating growth and cell wall composition of F. fomentarius, i.e. factors that contribute on the meso- and microscale level to the composite behaviour.

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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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