Research Topic: lignocellulosic substrates

Temporal characterization of biocycles of mycelium-bound composites made from bamboo and Pleurotus ostreatus for indoor usage

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Scientists created a sustainable building material by growing oyster mushroom fungus on bamboo fibers. The material was strong enough for packaging and could be composted after use to enrich soil, completing a full cycle in about 7 months. By adding a natural beeswax coating, the material lasted longer while remaining completely biodegradable. This proof-of-concept demonstrates how fungal materials could replace synthetic plastics in a circular economy.

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Production of oyster mushroom (Pleurotus ostreatus) from some waste lignocellulosic materials and FTIR characterization of structural changes

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Researchers successfully grew oyster mushrooms on hazelnut branch waste, a byproduct previously burned or discarded in Turkey. The mushrooms grown on hazelnut branches produced higher yields than traditional wheat straw substrates. Scientists used specialized analysis to show how the fungus breaks down the plant material’s structure. This finding suggests a practical way to recycle agricultural waste while producing nutritious food.

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Artificial Neural Network Prediction of Mechanical Properties in Mycelium-Based Biocomposites

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Scientists developed an artificial intelligence model that can predict how strong and durable mushroom-based composite materials will be. These composites are made by growing mushroom mycelium (fungal threads) through wood particles and other plant materials, creating an eco-friendly alternative to synthetic materials. The AI model learns from physical measurements and can accurately predict mechanical properties, potentially reducing the need for extensive testing and helping design better sustainable materials.

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Artificial Neural Network Prediction of Mechanical Properties in Mycelium-Based Biocomposites

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Researchers used artificial intelligence to predict how strong mushroom-based materials would be. These eco-friendly composites are made from wood particles held together by fungal networks instead of synthetic glue. The AI model successfully learned to predict the strength of these materials based on which type of fungus was used and what wood particles they were grown on, potentially reducing the need for expensive testing.

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Valorization of various lignocellulosic wastes to Ganoderma lucidum (Curtis) P. Karst (Reishi Mushroom) cultivation and their FT-IR assessments

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This research demonstrates how agricultural and forestry waste materials can be effectively converted into nutritious Reishi mushrooms through sustainable cultivation practices. Oak wood substrates produced the highest mushroom yields, while various agricultural wastes showed promising results for producing medicinal mushrooms. Using specialized spectroscopy techniques, scientists confirmed that the Reishi mushroom effectively breaks down and utilizes the complex plant materials in these waste substrates. This approach offers an environmentally friendly solution to waste management while producing valuable medicinal mushrooms.

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Development and Characterization of Mycelium-Based Composite Using Agro-Industrial Waste and Ganoderma lucidum as Insulating Material

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Researchers developed an eco-friendly insulation material using mushroom mycelium (Ganoderma lucidum) combined with waste plant materials from Colombia: Arboloco pith and grass clippings. The resulting material is lightweight, thermally efficient, and comparable to commercial insulators like expanded polystyrene. However, the material shrinks significantly and absorbs water when exposed to moisture, so additional treatments are needed before it can be widely used in buildings.

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