Trametes versicolor – Page 10

Effects of Environmental and Nutritional Conditions on Mycelium Growth of Three Basidiomycota

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Researchers tested how three types of edible and medicinal mushroom fungi grow on different substrate mixtures to develop better biodegradable materials for packaging and insulation. They found that substrates rich in cotton fibers combined with specific carbon dioxide levels produced the fastest and densest fungal growth. These findings help optimize the production of eco-friendly mushroom-based materials that could replace plastic and foam products while being fully compostable.

Modern Pro-Health Applications of Medicinal Mushrooms: Insights into the Polyporaceae Family, with a Focus on Cerrena unicolor

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This research explores how medicinal mushrooms, especially a species called Cerrena unicolor, could be used to improve human health through functional foods and dietary supplements. These mushrooms contain natural compounds that fight cancer, bacteria, viruses, and free radicals that damage our cells. Scientists have found that incorporating these mushroom extracts into foods, particularly dairy products, could create powerful health-promoting foods that help with cancer treatment, diabetes management, and wound healing.

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

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Scientists have developed a new 3D printing method to create environmentally-friendly materials made from agricultural waste and fungi. Instead of using traditional plastic materials that take years to decompose, these biomass-fungi composites break down naturally. The new binder jetting printing process is faster and more precise than previous methods, making it more practical for manufacturing products like packaging, furniture, and building materials.

Enhanced biodegradation of fluorinated pharmaceutical by Aspergillus flavus and Cunninghamella elegans biofilms: kinetics and mechanisms

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Two types of fungi, Aspergillus flavus and Cunninghamella elegans, can effectively break down pharmaceutical pollutants commonly found in wastewater, such as antidepressants and antibiotics. When grown as biofilms on foam carriers, these fungi removed over 90% of the target pharmaceuticals very quickly. The fungi accomplish this primarily through enzymatic breakdown rather than absorption, making them promising candidates for cleaning wastewater at treatment plants.

Fungal Innovations—Advancing Sustainable Materials, Genetics, and Applications for Industry

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Fungi can be engineered to create sustainable, eco-friendly materials for construction, textiles, and packaging. Using advanced genetic tools and controlled growing conditions, scientists can customize fungal materials to have specific properties like flexibility or rigidity. These mycelium-based materials are biodegradable, renewable, and offer promising alternatives to traditional synthetic and conventional materials, helping reduce our dependence on petroleum-based products.

Hydrothermal liquefaction aqueous phase mycoremediation to increase inorganic nitrogen availability

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When biomass is converted to biofuel through a heating process called hydrothermal liquefaction, it produces a waste liquid containing nutrients but also toxins. Scientists used a type of fungus called Trametes versicolor to clean up this waste and convert the nitrogen into forms that plants can use. After three days of treatment with the fungus, nitrogen levels that plants can use increased dramatically. Adding helpful bacteria further improved the results, making this waste potentially usable as a fertilizer for growing vegetables hydroponically.

First Report of Trametes hirsuta, Causal Agent White Rot in Avocado Trees Grown in the State of Michoacán, México

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Researchers in Mexico discovered that a wood-decay fungus called Trametes hirsuta is infecting avocado trees in the country’s main avocado-growing region, Michoacán. The fungus causes a disease called white rot, which leads to yellowing leaves, tree defoliation, and eventually tree death. This is the first time this fungus has been identified as a disease-causing agent in avocado trees, and the researchers confirmed through laboratory tests that the fungus is indeed responsible for the damage being observed in avocado orchards.

Biocomposites Based on Mould Biomass and Waste Fibres for the Production of Agrotextiles: Technology Development, Material Characterization, and Agricultural Application

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Researchers developed a new eco-friendly material made from mould mycelium combined with waste plant fibres that can be used as a substitute for synthetic agricultural textiles. The material successfully grows in about 5 days, can be completely biodegraded in soil within 10 days, and helps seeds germinate faster. This innovation supports sustainable farming by eliminating microplastic pollution from traditional synthetic crop covers while providing better properties than many conventional alternatives.

New bioactive secondary metabolites from fungi: 2024

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Scientists discovered 907 new compounds from fungi in 2024, with most being terpenoids and polyketides that show promise as medicines. These fungal compounds demonstrate strong activity against bacteria, fungi, and inflammation, with some showing potential against cancer and diabetes. The research uses advanced techniques like genome mining and metabolomics to find these compounds more efficiently. This accelerating discovery rate suggests fungi could be a major source for developing new drugs to treat various diseases.

Oestrogen Detoxification Ability of White Rot Fungus Trametes hirsuta LE-BIN 072: Exoproteome and Transformation Product Profiling

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Scientists discovered that a white rot fungus called Trametes hirsuta can effectively remove harmful oestrogen hormones from water and soil. Within just one day, the fungus eliminated more than 90% of two common oestrogens (E1 and E2) that pollute our environment through pharmaceutical waste and animal farming. The fungus achieves this by producing special enzymes that couple oestrogen molecules together into larger, less harmful compounds that can be easily removed.

Fungal Species: Trametes versicolor