Sustainable materials – Page 4

Anisotropic Growth of Filamentous Fungi in Wood Hydrogel Composites Increases Mechanical Properties

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Researchers developed new composite materials by growing fungi on specially treated wood. The fungi naturally grow along the wood’s fiber direction, creating stronger, more organized structures than they would in regular gelatin. By adjusting the wood type and nutrient levels, scientists could precisely control the mechanical strength of these eco-friendly materials, which could eventually be used in building products and packaging.

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.

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.

Excellent anti-mildew effect of essential oil impregnation on sliced veneer plybamboo and its anti-mildew mechanism

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Researchers discovered that clove essential oil is highly effective at preventing mold growth on decorative bamboo veneer materials. The natural oil damages fungal cell membranes and disrupts their internal chemistry, killing the mold without toxic chemicals. When bamboo sheets were treated with clove oil before assembly, they showed excellent resistance to common molds. This provides a green, sustainable alternative to harsh chemical treatments while maintaining product quality.

Living Textures and Mycelium Skin Co-Creation: Designing Colour, Pattern, and Performance for Bio-Aesthetic Expression in Mycelium-Bound Composites

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Researchers discovered that mushroom mycelium can naturally change color and texture in response to different environmental conditions, making it possible to design beautiful, sustainable building materials without chemical treatments. By controlling moisture and oxygen exposure during growth, scientists can create specific patterns and colors ranging from white to brown on mycelium composite surfaces. This breakthrough suggests that fungal-based materials could become more visually appealing and widely accepted for use in architecture and construction, supporting both environmental sustainability and public acceptance of bio-based building products.

Impact of Fomes fomentarius growth on the mechanical properties of material extrusion additively manufactured PLA and PLA/Hemp biopolymers

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This research explores how mushroom mycelium can be integrated with 3D-printed plastic materials to create sustainable biocomposites. Scientists tested whether Fomes fomentarius fungus growing on printed PLA and hemp-reinforced plastic specimens affected their strength and stiffness. Results showed that while pure PLA remained largely unaffected by mycelium growth, hemp-reinforced materials experienced some weakening, with effects depending on the duration of fungal colonization and the internal structure of the printed materials. These findings suggest potential applications in developing eco-friendly building materials and insulation products that combine the benefits of living organisms with manufactured polymers.

You Are What You Eat: How Fungal Adaptation Can Be Leveraged toward Myco-Material Properties

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Fungi can be grown to create eco-friendly materials that could replace plastics and petroleum-based products. By controlling what fungi eat and where they grow, scientists can engineer the properties of these materials to be stronger, more flexible, or water-resistant. This approach leverages the natural ability of fungi to break down organic matter and adapt to their environment. Companies like IKEA and Dell are already using these fungal materials in product packaging.

Fungal and Microalgal Chitin: Structural Differences, Functional Properties, and Biomedical Applications

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Chitin is a natural fiber found in mushroom cell walls and algae that can be extracted and used for medical applications like wound healing and drug delivery. Traditional chitin from shellfish shells contains heavy metals and requires harsh chemicals to extract, but chitin from mushrooms and algae is cleaner, more sustainable, and can be grown year-round. Scientists have developed environmentally friendly extraction methods using special solvents and enzymes that preserve the chitin’s useful properties. This makes fungal and algal chitin promising alternatives for creating biomedical materials and packaging.

Taming the Production of Bioluminescent Wood Using the White Rot Fungus Desarmillaria Tabescens

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Scientists have developed a way to make wood glow in the dark using a special fungus called Desarmillaria tabescens. By carefully controlling moisture levels and giving the fungus time to break down wood components, they created a glowing material that could one day replace electric lights. This bioluminescent wood is completely natural and requires no electricity, offering a sustainable lighting solution for homes and cities.

Superhydrophobic Fatty Acid-Based Spray Coatings with Dual-Mode Antifungal Activity

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Scientists developed easy-to-apply spray coatings made from natural fatty acids that repel water and kill fungal infections like gray mold. By combining long-chain fatty acids with shorter fatty acids like those found in food preservatives, the coatings can either passively prevent fungus from sticking to surfaces or actively kill it. These coatings are environmentally friendly, sustainable alternatives to chemical fungicides that fungi are becoming resistant to, and could be used to protect everything from building surfaces to stored crops.

Research Topic: Sustainable materials