Trametes versicolor – Page 14

Pleurotus eryngii Culture Filtrate and Aqueous Extracts Alleviate Aflatoxin B1 Synthesis

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This research demonstrates that extracts from oyster mushrooms (Pleurotus eryngii) can effectively reduce dangerous aflatoxin contamination in food and feed by up to 94%. Aflatoxins are toxic compounds produced by mold fungi that can cause serious health problems including cancer. The study shows that mushroom compounds work through multiple mechanisms including antioxidant activity and enzyme production, offering a natural and environmentally friendly alternative to harmful synthetic chemicals for protecting our food supply.

Screening of Basidiomycete Strains Capable of Synthesizing Antibacterial and Antifungal Metabolites

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Researchers tested 18 different types of wood-decay fungi (basidiomycetes) to see if they could produce natural antibiotics and antifungal compounds. They found that 16 of the 18 strains successfully produced antimicrobial substances. Five strains were particularly promising, showing strong activity against dangerous bacteria including antibiotic-resistant strains. The study identified specific chemical compounds from these fungi that could potentially be developed into new medicines.

Study on Optimization of Liquid Fermentation Medium and Antitumor Activity of the Mycelium on Phyllopora lonicerae

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Researchers improved the production of a medicinal fungus called Phylloporia lonicerae that grows on honeysuckle plants. They developed a better growing medium that produced more fungus in less time. They then discovered that components from this fungus can kill cancer cells, particularly lung and esophageal cancer cells, by triggering a natural cell death process called apoptosis. This work suggests the fungus could be developed into an anti-cancer functional food.

Binder Jetting 3D Printing of Biomass–Fungi Composite Materials: A Preliminary Experimental Study

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Researchers developed a new 3D printing method called binder jetting to create eco-friendly materials made from agricultural waste and fungi. The fungi’s root-like structures naturally bind plant particles together, creating a biodegradable alternative to plastic. This method produces complex shapes with better precision than previous techniques and could revolutionize sustainable manufacturing for packaging and furniture.

Perspectives of Insulating Biodegradable Composites Derived from Agricultural Lignocellulosic Biomass and Fungal Mycelium: A Comprehensive Study of Thermal Conductivity and Density Characteristics

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Scientists created eco-friendly insulation material by combining agricultural waste like wheat, hemp, and flax straw with fungal mycelium as a natural binder. These composites are fully biodegradable, lightweight, and have thermal insulation properties comparable to conventional materials, offering a sustainable alternative for building insulation that performs better per unit weight than many traditional options.

In Vitro and Computational Response of Differential Catalysis by Phlebia brevispora BAFC 633 Laccase in Interaction with 2,4-D and Chlorpyrifos

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Scientists studied how two common pesticides (2,4-D and chlorpyrifos) interact with an enzyme called laccase produced by a white rot fungus. Using laboratory tests and computer simulations, they found that the fungus can survive exposure to these pesticides while still producing active laccase. Importantly, chlorpyrifos actually increased the enzyme’s activity, suggesting it could be useful for breaking down pesticide-contaminated soil and water.

Microbial decay of wooden structures: actors, activities and means of protection

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Wood is an increasingly popular sustainable building material, but fungi and bacteria can cause significant damage to wooden structures. This review explains how different types of fungi and bacteria decay wood through various mechanisms, describes advanced DNA methods to identify these microorganisms, and outlines practical strategies to protect wood. By combining proper design, chemical treatments, and wood modification techniques, builders can extend the lifespan of wooden structures while maintaining environmental sustainability.

Uncovering the transcriptional landscape of Fomes fomentarius during fungal-based material production through gene co-expression network analysis

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Scientists studied how the mushroom Fomes fomentarius decomposes plant materials and grows as a biomaterial for making sustainable products. Using advanced gene analysis, they discovered which genes control the fungus’s ability to break down wood and form composites, and identified key genetic switches that could be used to improve material production. This research provides a blueprint for engineering better fungal-based alternatives to conventional construction and packaging materials.

The Fungus Among Us: Innovations and Applications of Mycelium-Based Composites

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Mycelium-based composites are eco-friendly building materials made by growing mushroom fungus on agricultural waste like sawdust and straw. These materials are lightweight, provide excellent insulation and soundproofing, and are much more sustainable than synthetic alternatives. However, they absorb water easily and aren’t strong enough for load-bearing structures, making them best suited for insulation and non-structural panels.

Hydrothermal liquefaction aqueous phase mycoremediation to increase inorganic nitrogen availability

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This research shows that a common mushroom fungus called Trametes versicolor can clean up wastewater produced during the conversion of food waste into biofuel. The fungus transforms hard-to-use nitrogen compounds in the waste into forms that plants can absorb. After three days of treatment, the nitrogen that plants can use increased dramatically. When bacteria known for converting ammonia to nitrate were added to the fungal treatment, the results improved even more, suggesting this waste could eventually be recycled as a fertilizer for growing plants in water-based farming systems.

Fungal Species: Trametes versicolor