Research Keyword: nanotechnology

Graphene nanomaterials: A new frontier in preventing respiratory fungal infections

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Graphene nanomaterials, especially nano-graphene oxide, show promise as new treatments for serious lung fungal infections that particularly threaten people with weakened immune systems. These tiny materials work by generating damaging reactive oxygen species that kill fungal cells and prevent biofilm formation. Unlike traditional antifungal drugs, nano-graphene oxide can be delivered directly to infected lung tissue via inhalation, delivering medicine exactly where needed while reducing harmful side effects throughout the body.

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Ganoderma lucidum inspired silver nanoparticles and its biomedical applications with special reference to drug resistant Escherichia coli isolates from CAUTI

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Researchers created tiny silver particles using a medicinal mushroom called Ganoderma lucidum to fight dangerous bacteria that resist antibiotics and are associated with urinary catheter infections. These nanoparticles were found to effectively kill drug-resistant bacteria, work as antioxidants better than a common antioxidant standard, and showed promise in killing breast cancer cells. This eco-friendly approach offers a natural alternative to conventional antibiotics for treating serious antibiotic-resistant infections.

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Microbial-Based Green Synthesis of Silver Nanoparticles: A Comparative Review of Bacteria- and Fungi-Mediated Approaches

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Scientists are developing environmentally friendly ways to make silver nanoparticles using bacteria and fungi instead of harsh chemicals. These tiny particles show promise in fighting infections, treating cancer, cleaning water, and protecting crops. The review compares how bacteria and fungi each produce these particles and explains how different conditions affect their properties and effectiveness.

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Things you wanted to know about fungal extracellular vesicles (but were afraid to ask)

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Fungal extracellular vesicles (EVs) are tiny packages released by fungal cells that play important roles in fungal infections and how our immune system responds to them. Scientists have confirmed these EVs are real biological structures, not laboratory artifacts, and discovered they are produced by many different fungal species. Interestingly, these EVs can have opposite effects on the immune system depending on the fungus involved—sometimes helping our bodies fight infection and sometimes making infections worse, making them both potential vaccines and virulence factors.

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Design and Evaluation of a Inonotus obliquus–AgNP–Maltodextrin Delivery System: Antioxidant, Antimicrobial, Acetylcholinesterase Inhibitory and Cytotoxic Potential

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Researchers studied Chaga mushroom from Romania and developed new ways to package and deliver its beneficial compounds using silver nanoparticles and a food-safe ingredient called maltodextrin. These new delivery systems were designed to work better in the body by improving how well the mushroom’s active ingredients dissolve and stay stable. Testing showed these enhanced formulations were very effective at fighting bacteria, protecting cells from damage, and killing cancer cells.

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Graphene nanomaterials: A new frontier in preventing respiratory fungal infections

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Scientists are exploring nano-graphene oxide, a microscopic material made from graphene, as a new treatment for serious lung fungal infections. These tiny particles can kill fungal cells through multiple mechanisms and deliver antifungal drugs directly to infection sites while reducing harmful side effects. Researchers found that graphene oxide can be combined with existing antifungal medications to make them work better and even help overcome drug-resistant fungal infections.

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Antifungal potential of copper oxide nanoparticles against Microsporum canis isolates in canine and feline dermatophytosis

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Researchers tested tiny copper oxide particles created using plant extracts against a fungus that causes ringworm in dogs and cats. These nanoparticles successfully killed the fungus in laboratory tests, with effectiveness at concentrations ranging from 500-2,000 parts per million. While slightly less effective than current medications, the nanoparticles showed promise as an alternative treatment, especially important as the fungus becomes resistant to traditional drugs.

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