Research Keyword: biofilm formation

Exploring the Antifungal Potential of Lawsone-Loaded Mesoporous Silica Nanoparticles Against Candida albicans and Candida glabrata: Growth Inhibition and Biofilm Disruption

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Researchers developed a new antifungal treatment by loading lawsone (a compound from henna plants) into tiny particles called mesoporous silica nanoparticles. When tested against common fungal infections caused by Candida bacteria, this nano-formulation was more effective than lawsone alone at killing the fungi and breaking down protective biofilm structures. The treatment showed no harm to normal human cells, suggesting it could be a promising natural alternative to treat stubborn fungal infections that resist current antifungal drugs.

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A Case of Pulmonary Infection Due to Magnusiomyces capitatus in a Non-Immunocompromised Patient with Cerebral Palsy

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A young man with cerebral palsy developed a rare lung infection caused by Magnusiomyces capitatus, a fungus that usually only affects people with weakened immune systems. Doctors diagnosed the infection by analyzing fluid from his lungs and identified the fungus using advanced laboratory techniques. The patient improved after being treated with an antifungal medication called voriconazole. This case highlights that this rare fungal infection can occur in otherwise healthy people, especially those with conditions affecting their ability to clear lung secretions.

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Antimicrobial and antiparasitic potential of lupeol: antifungal effect on the Candida parapsilosis species complex and nematicidal activity against Caenorhabditis elegans

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Researchers tested a natural compound called lupeol against disease-causing yeasts and parasitic worms. Lupeol successfully killed or inhibited the growth of Candida yeast species that are becoming resistant to current medications. The compound also showed strong activity against parasitic roundworms. This discovery suggests lupeol could be developed as a new treatment option for fungal and parasitic infections.

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Overexpression of efflux pump and biofilm associated genes in itraconazole resistant Candida albicans isolates causing onychomycosis

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This study examined why some fungal nail infections caused by Candida albicans don’t respond to itraconazole treatment. Researchers found that resistant fungi have higher levels of genes that pump the antifungal drug out of their cells and genes that help them form protective biofilm layers. These findings suggest that combining itraconazole with drugs that block these pumps or disrupt biofilms could be more effective for treating stubborn fungal nail infections.

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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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Diagnostic Approaches to Invasive Candidiasis: Challenges and New Perspectives

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Invasive candidiasis is a dangerous fungal infection affecting critically ill hospital patients. Current testing methods like blood cultures are slow and unreliable, so doctors are developing faster tests using DNA detection and biomarkers. A combination of new diagnostic tools and prompt treatment with antifungal medications is essential to improve survival rates and reduce complications from this serious infection.

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The antifungal mechanism of EntV-derived peptides is associated with a reduction in extracellular vesicle release

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Researchers discovered that a small peptide derived from a bacterium called EntV can fight Candida fungal infections by targeting specialized vesicles (tiny sacs) that fungi use to spread infections. Unlike traditional antifungal drugs that kill fungi, EntV works by blocking the release of these vesicles, reducing the fungus’s ability to infect and form protective biofilms. This new approach could lead to treatments that work against drug-resistant fungi without the toxicity issues of current antifungals.

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