mycelium-bound composites

Mechanical properties of dense mycelium-bound composites under accelerated tropical weathering conditions

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Researchers developed a sustainable alternative to traditional particleboard using mushroom mycelium (fungal root structure) grown on agricultural waste like sawdust and palm fruit remnants. When exposed to hot, humid tropical conditions for 35 days, the material’s strength decreased significantly, but applying a protective oil coating helped preserve tensile strength. The study shows that with improvements to manufacturing processes, these mushroom-based composites could replace harmful formaldehyde-based particleboards in indoor construction.

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.

A Comprehensive Review on Studying and Developing Guidelines to Standardize the Inspection of Properties and Production Methods for Mycelium-Bound Composites in Bio-Based Building Material Applications

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This review examines mycelium-based composites, which are innovative building materials made from fungal networks grown on agricultural waste. These eco-friendly materials are biodegradable and use less energy to produce than traditional construction materials. The authors analyze current testing methods and propose standardized production guidelines to ensure consistent quality, helping make these sustainable materials more reliable for widespread use in buildings and construction.

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.

3D printed gyroid scaffolds enabling strong and thermally insulating mycelium-bound composites for greener infrastructures

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Scientists developed a new eco-friendly building material by growing mushroom mycelium on specially designed 3D-printed scaffolds made from wood and plant-based plastic. These mycelium bricks are stronger, better insulators, and more fire-resistant than traditional bricks or foam insulation, while being completely biodegradable. This breakthrough could help reduce the construction industry’s massive carbon footprint and provide a sustainable alternative to harmful conventional building materials.

3D printed gyroid scaffolds enabling strong and thermally insulating mycelium-bound composites for greener infrastructures

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Scientists developed a new eco-friendly building material made from mushroom mycelium grown on 3D-printed scaffolds. This material is as strong as traditional bricks, provides excellent insulation like foam, resists fire better than conventional materials, and is completely compostable. The innovation could help reduce carbon emissions from construction by replacing harmful petroleum-based and energy-intensive traditional building materials.

Research Keyword: mycelium-bound composites

Mechanical properties of dense mycelium-bound composites under accelerated tropical weathering conditions

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

A Comprehensive Review on Studying and Developing Guidelines to Standardize the Inspection of Properties and Production Methods for Mycelium-Bound Composites in Bio-Based Building Material Applications

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

3D printed gyroid scaffolds enabling strong and thermally insulating mycelium-bound composites for greener infrastructures

3D printed gyroid scaffolds enabling strong and thermally insulating mycelium-bound composites for greener infrastructures