waste valorization – Page 2

Biomass carbon mining to develop nature-inspired materials for a circular economy

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This paper explains how we can turn waste biomass from agriculture and industry into valuable materials to replace petroleum-based products. By using computational methods and artificial intelligence, researchers can design more efficient processes to convert plant and animal waste into bioplastics, chemicals, and building materials. Over 100 companies are already successfully doing this, creating products from waste coffee grounds, seaweed, agricultural residue, and other biomass sources.

Valorization and Environmental Impacts of Pecan Waste: A Critical Review

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Pecan shells, which make up about half of the pecan nut and are usually discarded, contain valuable compounds with health-promoting properties like antioxidants and anti-inflammatory agents. These shells can be transformed into useful products including ingredients for food supplements and medicines, activated carbon for cleaning water, materials for making eco-friendly plastics, and energy sources. By converting pecan waste into valuable products instead of throwing it away, communities can reduce environmental pollution, improve public health, and create economic opportunities while supporting sustainable farming practices.

The value of microbial bioreactors to meet challenges in the circular bioeconomy

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Scientists are using specially designed containers called bioreactors to grow helpful microorganisms and mushrooms that can solve environmental and health problems. These bioreactors can produce medicines like natural diabetes treatments from mushrooms, create eco-friendly plastics, clean up polluted water, and turn waste products into valuable materials. This approach is sustainable, safe, and scalable, supporting the United Nations’ goals for a healthier planet.

Structure-Forming Properties of Pleurotus ostreatus: A Promising Resource for Edible 3D Printing Applications

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Low-grade oyster mushrooms, which normally go to waste due to cosmetic imperfections, contain valuable nutrients and compounds that make them excellent for 3D food printing. These mushrooms naturally possess properties like chitin and β-glucans that create the right consistency for printing edible structures. Using these discarded mushrooms for innovative 3D printing reduces waste, cuts production costs by up to 75%, and creates nutritious, customizable food products.

Textile residue-based mycelium biocomposites from Pleurotus ostreatus

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Researchers successfully grew oyster mushroom mycelium on textile waste to create eco-friendly biocomposites that could replace plastic packaging. The fungus naturally binds textile fibers together, creating lightweight materials with useful structural properties. This approach transforms textile waste into sustainable products while addressing plastic pollution, offering a promising solution for converting unwanted clothing and fabric scraps into useful materials.

Novel chia (Salvia Hispanica L.) residue-based substrate formulations for oyster mushroom (Pleurotus ostreatus) cultivation

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Researchers discovered that leftover plant material from chia seed production can be used to grow oyster mushrooms with excellent nutritional value. When chia residues were combined with rice straw in the right proportions, they produced mushrooms with higher protein content, more beneficial compounds, and better yields than traditional growing methods. This finding helps solve two problems at once: it creates a valuable use for chia farming waste while producing highly nutritious mushrooms for human consumption.

Mycofabrication of sustainable mycelium-based leather using Talaromyces sp. and irradiated eggplant peel waste

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Scientists developed a new type of eco-friendly leather made from fungal mycelium grown on eggplant peel waste. Using radiation to treat the eggplant peels made them stronger and more flexible, and optimizing the growing conditions improved the material’s quality. The resulting mycoleather has mechanical properties comparable to real leather but is completely biodegradable and sustainable, offering a promising alternative to traditional leather production.

Statistical methodologies for enhancing lipase production from Aspergillus Niger and using biologically treated cottonseed waste in animal nutrition

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This study shows how scientists can grow an enzyme called lipase on cottonseed waste using a fungus called Aspergillus niger. The leftover treated material becomes excellent animal feed with high protein and important amino acids. This approach solves two problems at once: producing valuable enzymes for industry while creating nutritious feed for livestock from agricultural waste.

Quorum-driven microbial consortium for Bioplastic production from agro-waste

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Scientists created a partnership between a fungus and bacteria to make eco-friendly plastic (PHA) from brewery and cooking waste. The fungus breaks down the tough plant material while the bacteria converts the released compounds into bioplastic. By adding a natural chemical signal (farnesol), they improved the process and scaled it up successfully in a larger reactor without needing expensive pretreatment steps.

Conversion of Soluble Compounds in Distillery Wastewater into Fungal Biomass and Metabolites Using Australian Ganoderma Isolates

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Researchers discovered that Ganoderma mushroom mycelium can clean up rum distillery wastewater while producing edible, protein-rich fungal biomass. The mycelium successfully removed harmful compounds from the wastewater and accumulated bioactive compounds with health benefits. This dual-benefit approach transforms an environmental waste problem into a valuable food ingredient, offering a sustainable and economical solution for the distillery industry.

Research Keyword: waste valorization