solid-state fermentation

From purposeless residues to biocomposites: A hyphae made connection

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Researchers developed eco-friendly packaging materials using mushroom mycelium and agricultural waste from fruit and sugar cane processing. Two native Colombian fungal species were grown on leftover fruit peels and bagasse to create lightweight, biodegradable composites. From just 50 kilograms of fruit peel waste, nearly 1,840 cups can be manufactured, offering a sustainable alternative to plastic packaging that naturally decomposes after use.

Cultivation of Different Oyster Mushroom (Pleurotus species) on Coffee Waste and Determination of Their Relative Biological Efficiency and Pectinase Enzyme Production, Ethiopia

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This research shows that oyster mushrooms can be successfully grown on leftover coffee waste (husks and parchment), turning an environmental problem into a nutritious food source. Different oyster mushroom species performed differently, with P. ostreatus being the most efficient. Pre-composting the coffee waste improved mushroom yields significantly. The study demonstrates that using coffee waste for mushroom cultivation is both economically viable and environmentally beneficial.

Solid-state fermentation as a strategy for improvement of bioactive properties of the plant-based food resources

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This review explains how fermentation—a natural biological process—can enhance the health-promoting compounds in plant-based foods. By using specific fungi and bacteria on solid plant materials, scientists can increase beneficial antioxidants and proteins that may help prevent chronic diseases. This method is more environmentally friendly and cost-effective than traditional extraction techniques, making nutritious plant foods even healthier.

Techno-economic analysis of a novel laccase production process utilizing perennial biomass and the aqueous phase of bio-oil

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Researchers developed a new method to produce laccase, a useful enzyme with many industrial applications, by growing oyster mushrooms on prairie plants and waste materials from bio-oil production. Through optimization experiments and economic modeling, they found that this process could produce laccase at prices significantly lower than current commercial enzyme products, making it economically viable at small to moderate production scales. The method has the added benefit of providing farmers with a financial incentive to grow perennial prairie plants instead of traditional crops, supporting ecological and soil health improvements.

Pigment production by a newly isolated strain Pycnoporus sanguineus SYBC-L7 in solid-state fermentation

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Researchers isolated a fungal strain that produces bright orange natural pigments through fermentation on wood chips and other agricultural waste. By optimizing growing conditions such as pH and moisture, they achieved high pigment yields with antibacterial properties. The pigments identified in this study showed effectiveness against harmful bacteria and could replace synthetic dyes in food, cosmetics, and textile products.

From Nature to Design: Tailoring Pure Mycelial Materials for the Needs of Tomorrow

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Scientists are developing new materials made from mushroom mycelium that could replace leather, foam, and plastic products. These fungal-based materials grow on simple agricultural waste, are completely biodegradable, and have a much smaller environmental footprint than traditional materials. Companies like MycoWorks are already producing mycelium leather for major fashion brands, showing this technology is moving from laboratories into real products.

Sustainable Innovations in Food Microbiology: Fermentation, Biocontrol, and Functional Foods

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This review explores how microorganisms can make food production more sustainable and healthier. It discusses traditional fermented foods like yogurt and sauerkraut, modern biotechnology techniques to reduce food waste and create natural preservatives, and special food ingredients with beneficial bacteria that support digestive and mental health. The paper shows how applying microbial science could help address global food challenges while meeting consumer demands for natural, safe, and healthy products.

Vermiculite as a new carrier for extracellular protease production by Aspergillus spp. under solid-state fermentation

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Researchers discovered that vermiculite, a naturally occurring mineral, is an excellent material for growing fungi that produce proteases—enzymes used in medicine, laundry detergents, and food processing. When Aspergillus fungi were grown on vermiculite using a technique called solid-state fermentation, they produced 3 to 18 times more protease than when grown on other materials. This discovery could make enzyme production more efficient and cost-effective for industrial applications.

Solid-state fermentation of hemp waste: enhancing the performance of Hermetia illucens larvae and altering the composition of hemp secondary metabolites

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Researchers tested whether fermenting hemp plant waste with different mushroom types could make it a better food source for black soldier fly larvae, which produce valuable protein for animal feed. They found that different mushroom species had different effects: Ganoderma lucidum significantly increased the amount of larvae produced, while Trichoderma reesei increased beneficial cannabinoid content. Pleurotus ostreatus and Hypsizygus ulmarius removed unwanted cannabinoids from the waste. This approach offers a promising way to turn hemp waste into high-quality insect feed while controlling the levels of bioactive compounds.

Biosourcing and optimization of fungal lipase production from cheap agro waste via solid state fermentation

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Researchers discovered a fungus called Aspergillus oryzae that produces lipase, an important enzyme used in many industries. They found that this fungus works best when grown on cheap agricultural waste materials like wheat bran and rice bran, making enzyme production more affordable and environmentally friendly. By optimizing growth conditions and using waste materials, they successfully increased lipase production and showed this approach could be used in industrial-scale enzyme manufacturing.

Research Topic: solid-state fermentation