lignocellulose – mycolab.ai

A Combination of Transcriptome and Enzyme Activity Analysis Unveils Key Genes and Patterns of Corncob Lignocellulose Degradation by Auricularia heimuer under Cultivation Conditions

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Researchers investigated using corncob, a corn industry byproduct, as a growing medium for Auricularia heimuer mushrooms instead of expensive sawdust. By analyzing which genes the mushroom activates at different growth stages, they identified key enzymes responsible for breaking down corncob’s tough cellulose structure. The findings show the mushroom can effectively adapt to use corncob as a substrate, offering a sustainable and economical alternative for mushroom farming while reducing agricultural waste.

Influence of the chemical content of sawdust on the levels of important macronutrients and ash composition in Pearl oyster mushroom (Pleurotus ostreatus)

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This research shows that oyster mushrooms grown on different types of sawdust develop different nutritional profiles. By choosing sawdust with specific pH levels (slightly acidic to slightly basic) and hemicellulose content, mushroom farmers can grow mushrooms with higher protein, minerals, or fiber depending on consumer dietary preferences. The study helps growers make informed choices about substrate selection to optimize the nutritional value of their mushroom crops.

Turning the Cocopith Waste into Myceliated Biocomposite to Make an Insulator

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Researchers developed an environmentally-friendly insulation material by growing mushroom mycelium (Ganoderma lucidum) on cocopith, a waste product from coconut fiber processing. The resulting biocomposite has thermal insulation properties comparable to commercial insulators like Styrofoam and polyurethane, but is completely biodegradable and made from agricultural waste. This innovation addresses waste management problems while creating a sustainable material for thermal insulation in buildings, food processing, and industrial equipment.

Production of β-Glucans by Pleurotus ostreatus: Cultivation and Genetic Background

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Oyster mushrooms (Pleurotus ostreatus) are increasingly popular edible fungi that can grow on various waste materials like agricultural byproducts and food waste, making them both economical and environmentally friendly. These mushrooms produce valuable health-promoting compounds called β-glucans that have immune-boosting and antioxidant properties. Modern scientific techniques, including genetic analysis and artificial intelligence, are being used to optimize cultivation methods and increase production of these beneficial compounds. This sustainable approach to mushroom farming helps reduce waste while providing nutritious and medicinal food products.

Diversity of Culturable Fungi in Two-Phase Olive Mill Waste, a Preliminary Evaluation of Their Enzymatic Potential, and Two New Trichoderma Species

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Scientists discovered 31 different fungal species living in olive mill waste, including two previously unknown species. These fungi have the ability to break down tough plant materials and remove harmful dyes from waste, making them useful for cleaning up environmental pollution. This research suggests these fungi could be used to transform olive oil production waste into useful products, supporting a circular economy.

Conversion of Lignocellulosic Biomass Into Valuable Feed for Ruminants Using White Rot Fungi

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Researchers tested how three types of edible and medicinal fungi could improve the nutritional quality of agricultural plant waste for feeding livestock. They found that one fungus species, Ceriporiopsis subvermispora, was particularly effective at breaking down tough plant fibers, especially in rapeseed straw and spent reed materials. The fungal treatment not only made the feed easier for ruminant animals to digest but also reduced methane gas production, which is beneficial for environmental sustainability.

Efficient conversion of tea residue nutrients: Screening and proliferation of edible fungi

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Tea leaves left over from making instant tea are usually thrown away, but researchers found that special edible mushrooms can break down these tea residues and convert them into nutritious mushroom protein. Monascus kaoliang B6 was the most effective, using powerful enzymes to decompose the tough plant fibers in tea residue and transform the nutrients into edible mushroom biomass. This discovery offers an environmentally friendly way to recycle tea industry waste into a useful food product without using harsh chemicals.

The Structural and Functional Diversities of Bacteria Inhabiting Plant Woody Tissues and Their Interactions with Fungi

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Bacteria living in tree wood work together with fungi to break down wood and nutrients, which is important for forest health. Some bacteria can protect trees from harmful fungi by fighting them off, making them useful for controlling plant diseases. Understanding how bacteria and fungi interact in wood can help us grow healthier plants, manage tree diseases better, and improve wood decomposition processes.

Biorefining spent substrates of shiitake (Lentinula edodes) and oyster mushroom (Pleurotus ostreatus): enzymatic saccharification of cellulose and xylan, with lignin recovery from residues

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This research explores how to turn leftover mushroom growing material into useful products. After mushrooms are harvested, significant waste remains that contains valuable sugars and lignin. The study found that shiitake mushroom waste is naturally easier to break down into sugars than oyster mushroom waste, and they developed methods to extract high-purity lignin from the leftovers. This approach could help mushroom farmers reduce waste while creating valuable materials for biofuels and other products.

Assessing lignocellulosic biomass as a source of emergency foods

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After a major catastrophe that blocks sunlight and prevents crop growth, people could potentially survive by converting inedible plant material like leaves, grass, and wood into food. However, this biomass alone cannot provide all necessary nutrients—it has plenty of carbohydrates but lacks protein and fat. Combining biomass with edible insects and supplements could create a balanced diet to sustain families for extended periods.

Research Keyword: lignocellulose