tissue engineering – mycolab.ai

Synthesis of Acetobacter xylinum Bacterial Cellulose Aerogels and Their Effect on the Selected Properties

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Scientists created a special lightweight foam-like material made from bacterial cellulose that could be used in wound dressings, insulation, and water filtration. The material was made sustainably using just tea, sugar, and bacteria—no harmful chemicals needed. Different freezing methods were tested to create the best possible structure, with liquid nitrogen freezing producing the most porous and uniform results. The material showed excellent insulation properties and is biodegradable, making it an environmentally friendly alternative to synthetic foams.

Biomimetic Catechol-Incorporated Polyacrylonitrile Nanofiber Scaffolds for Tissue Engineering of Functional Salivary Glands

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Scientists developed a new synthetic material made from tiny fibers that can grow functional salivary glands in the laboratory. The special fibers, called PAN-C, attract and hold important proteins that naturally help glands develop. When cells are grown on these fibers, they form working gland structures that produce saliva-related proteins, offering hope for treating dry mouth and similar conditions.

Green nanobiopolymers for ecological applications: a step towards a sustainable environment

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This article explains how scientists are creating eco-friendly nanomaterials from natural sources like plants and crustacean shells to replace harmful plastic products. These green nanobiopolymers can break down naturally in the environment and are used in applications ranging from wound dressings to food packaging. The review covers how these materials are extracted and processed at the nanoscale to improve their properties for practical uses while reducing environmental pollution.

Processes of Obtaining Nanostructured Materials with a Hierarchical Porous Structure on the Example of Alginate Aerogels

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Scientists created lightweight, sponge-like materials called aerogels made from alginate (a substance derived from seaweed) with special internal structures. They tested three different techniques to create these structures: using soap-like surfactants, using a plant protein called zein, and using pressurized carbon dioxide. Each method produced materials with different pore sizes and characteristics, making them suitable for different medical applications like delivering medications slowly or growing cells for tissue repair.

Innovative Bioactive Nanofibrous Materials Combining Medicinal and Aromatic Plant Extracts and Electrospinning Method

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This research explains how scientists use a technique called electrospinning to create tiny, beneficial fibers from medicinal plants. By combining plant extracts like turmeric with biodegradable polymers, researchers create advanced materials that can deliver medicine, promote wound healing, and fight bacteria. These innovative fibers represent a natural approach to healthcare, bringing ancient plant wisdom into modern nanotechnology for practical medical applications.

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.

Gradient porous structures of mycelium: a quantitative structure–mechanical property analysis

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Scientists studied how mushroom root structures (mycelium) naturally develop different properties from bottom to top as they grow. They found that the thicker, older parts near the food source are stiffer and more densely packed with fibers, while the thinner, younger parts are more porous and flexible. This natural gradient could be useful for creating biodegradable materials for medical implants, filters, and other applications where changing properties are beneficial.

Functionalized Micellar Membranes from Medicinal Mushrooms as Promising Self-Growing Bioscaffolds

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Researchers created special membranes from medicinal mushrooms that could be used for wound healing and skin repairs. These membranes were grown in laboratory conditions and then treated with mango peel extract, which gave them antimicrobial properties to fight bacteria. The membranes are biodegradable, environmentally friendly, and work similar to the structure of skin tissue, making them promising for medical applications.

Functionalized Micellar Membranes from Medicinal Mushrooms as Promising Self-Growing Bioscaffolds

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Scientists created special membranes from medicinal mushrooms that can help heal wounds and regenerate damaged skin. These membranes are grown naturally in liquid culture and enriched with extract from mango peels to fight bacteria and promote healing. The material is completely natural, biodegradable, and performs better than many conventional wound healing materials, making it an eco-friendly option for medical applications.

Sustainable Extraction and Multimodal Characterization of Fungal Chitosan from Agaricus bisporus

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Researchers successfully extracted chitosan from button mushrooms (Agaricus bisporus) using environmentally friendly chemical processes. This fungal-derived chitosan offers a sustainable alternative to traditional sources from shellfish and avoids issues like allergies and harsh chemical pollution. The extracted material showed promising properties for medical applications including wound healing and drug delivery systems.

Research Keyword: tissue engineering