Antimicrobial activity – Page 7

Harnessing pycnidia-forming fungi for eco-friendly nanoparticle production, applications, and limitations

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Certain types of fungi can produce tiny metal particles called nanoparticles that have useful properties. These fungi-made nanoparticles can kill bacteria, fight cancer cells, clean pollutants from water and soil, and be used in medicines and agriculture. Unlike traditional chemical methods for making nanoparticles, using fungi is cleaner and safer for the environment, though scientists still need to understand more about how they work and ensure they are safe to use widely.

Synergistic potential and apoptosis induction of Bunium persicum essential oil and its pure components, cuminaldehyde and γ-terpinene, in combination with fluconazole on Candida albicans isolates: in vitro and in silico evaluation

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Researchers studied how Bunium persicum essential oil and two of its active components work together with the antifungal drug fluconazole to fight resistant Candida yeast infections. They found that cuminaldehyde, one of the oil’s main components, was particularly effective when combined with fluconazole and could trigger yeast cell death. These natural compounds could offer a promising new approach to treating fungal infections that have become resistant to standard medications.

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.

Mycelial Beehives of HIVEOPOLIS: Designing and Building Therapeutic Inner Nest Environments for Honeybees

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Scientists created experimental beehives made from living mushroom mycelium (the root structure of mushrooms) combined with 3D-printed scaffolds. These hives are designed to keep bees warmer while providing natural antimicrobial compounds that protect them from diseases. The research combines digital design technology with biology to create homes that mimic the natural tree cavities where wild honeybees live, potentially making them healthier and more resilient to climate change and diseases.

In vitro and in vivo inhibitory effects and transcriptional reactions of graphene oxide on Verticillium dahliae

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Scientists discovered that graphene oxide, a nanomaterial, can effectively kill or inhibit the growth of Verticillium dahliae, a harmful fungus that causes wilt disease in cotton and other crops. The graphene oxide works by damaging the fungus’s cell membranes and disrupting its ability to grow and spread. When applied to cotton plants infected with this fungus, graphene oxide treatment reduced disease symptoms and prevented the fungus from multiplying. This research suggests graphene oxide could become a valuable alternative to chemical fungicides for controlling this destructive plant disease.

Natural Ingredients to Improve Immunity

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Many natural ingredients from plants, mushrooms, and other sources can boost your immune system and help fight infections. These include well-known items like garlic, ginger, and vitamin C, as well as lesser-known compounds like β-glucans from mushrooms and melatonin from plant sources. Proper nutrition with adequate vitamins and minerals is crucial for maintaining a strong immune system that protects you from disease without overreacting and causing autoimmune problems.

Research advances in fungal polysaccharides: production, extraction, characterization, properties, and their multifaceted applications

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This comprehensive review explores how mushrooms and fungi produce special carbohydrates called polysaccharides that have remarkable health benefits. These compounds can boost the immune system, fight cancer, reduce inflammation, and act as antioxidants. The article details various methods to produce and extract these valuable compounds from fungi and discusses their practical uses in medicine, food production, and agriculture.

A bibliometric analysis of fungal volatile organic compounds

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Fungi release distinctive smells made up of volatile compounds that help them communicate with plants, bacteria, and other organisms. These fungal smell chemicals have grown from being studied mainly in wine fermentation to being explored for helping crops grow better, fighting plant diseases naturally, and creating food flavors without chemicals. This research shows that understanding how fungi use these smell chemicals could lead to more sustainable farming practices and natural alternatives to harmful pesticides.

Miniaturized high-throughput conversion of fungal strain collections into chemically characterized extract libraries for antimicrobial discovery

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Scientists developed a fast, automated method called FLECS-96 to screen hundreds of fungal species for antimicrobial compounds in a small 96-well plate format. The method combines fungal culture, chemical extraction, and analysis to identify promising candidates against resistant bacteria like Staphylococcus aureus. The team successfully identified two bioactive compounds from the fungi tested. This innovation could significantly speed up the discovery of new antibiotics to combat antibiotic-resistant infections.

A Systematic Comparative Study on the Physicochemical Properties, Volatile Compounds, and Biological Activity of Typical Fermented Soy Foods

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This research compared six popular fermented soy foods to understand their unique flavors and health benefits. Scientists found that each food has different flavor chemicals, with natto being distinctive for containing compounds called pyrazines. All six fermented soy foods showed strong antioxidant and antibacterial properties, making them valuable for health promotion. The findings can help food producers improve these traditional foods.

therapeutic action: Antimicrobial activity