Antifungal activity – Page 2

Synergistic inhibition of Aspergillus flavus by organic acid salts: growth, oxidative stress, and aflatoxin gene modulation

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A dangerous fungus called Aspergillus flavus contaminates animal feed and produces harmful toxins called aflatoxins that can make animals sick. Researchers tested a combination of three salt-based organic acids commonly used as natural food preservatives and found they work together to kill this fungus much better than using them individually. The combination damages the fungus’s cell structure, creates harmful reactive oxygen inside the cells, and shuts down the genes that produce the toxins, making it an excellent safe option for protecting animal feed.

An implementation framework for evaluating the biocidal potential of essential oils in controlling Fusarium wilt in spinach: from in vitro to in planta

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Researchers tested four common essential oils (thyme, oregano, marjoram, and tea tree) to see if they could stop a dangerous fungal disease in spinach plants. They found that thyme and oregano oils worked best at killing the fungus in laboratory tests and when applied to spinach seeds in the greenhouse, with thyme oil reducing disease by over half without harming the plants.

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 tested a spice-derived essential oil called Bunium persicum and two of its active compounds to see if they could work better with the antifungal drug fluconazole against drug-resistant yeast infections. They found that one component called cuminaldehyde was particularly effective and worked synergistically with fluconazole, meaning the combination was more powerful than either treatment alone. These natural compounds could potentially help treat fungal infections that no longer respond to standard medications, offering a promising approach using plant-based remedies alongside conventional drugs.

Microminutinin, a Fused Bis-Furan Coumarin from Murraya euchrestifolia, Exhibits Strong Broad-Spectrum Antifungal Activity by Disrupting Cell Membranes and Walls

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Researchers discovered a natural compound called microminutinin from a plant used in traditional medicine. This compound shows strong ability to kill various fungal pathogens that damage crops, particularly tea plants. The compound works by breaking down the protective structures of fungal cells, making it a promising candidate for developing safer, plant-based fungicides for agriculture.

Essential Oils as an Antifungal Alternative for the Control of Various Species of Fungi Isolated from Musa paradisiaca: Part I

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Researchers tested six common cooking and medicinal herbs in oil form to see if they could kill fungi that damage bananas after harvest. Cinnamon oil was the most effective, successfully stopping all five types of harmful fungi at relatively low concentrations. The findings suggest these natural oils could replace harsh chemical fungicides used to preserve bananas during storage and transport, making banana production more environmentally friendly.

Impact of Clove Oil on Biofilm Formation in Candida albicans and Its Effects on Mice with Candida Vaginitis

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This research demonstrates that clove oil, a natural and FDA-approved dietary supplement, can effectively combat Candida albicans infections that cause vaginal yeast infections. The study found that clove oil works by preventing the fungus from forming protective biofilms and by reducing inflammation. In mice with vaginal yeast infections, clove oil treatment significantly improved symptoms and reduced fungal levels, suggesting it could serve as a safer alternative to conventional antifungal medications.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

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Researchers found that an extract from Cinchona bark, containing the compound quinine, effectively kills rice-damaging fungus Rhizoctonia solani through two mechanisms: starving the fungus of the amino acid tryptophan and disrupting its energy-producing mitochondria. This natural plant-based treatment could serve as an eco-friendly alternative to synthetic fungicides, reducing crop losses from fungal diseases while avoiding the environmental damage and resistance problems associated with chemical pesticides.

In Vitro Screening of the Antifungal and Antimycotoxin Effects of a Stilbenoids-Rich Grapevine Cane Extract on Fusarium graminearum, Aspergillus flavus and Penicillium expansum

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Researchers tested an extract made from grapevine pruning waste to see if it could stop harmful fungi and the toxins they produce. The extract, rich in natural compounds called stilbenoids, successfully reduced growth and toxin production in three dangerous fungi that contaminate crops. The effects were strong enough that scientists believe this agricultural waste could become a natural alternative to chemical fungicides for protecting crops.

Algae and Cyanobacteria Fatty Acids and Bioactive Metabolites: Natural Antifungal Alternative Against Fusarium sp.

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Fusarium fungi cause serious crop diseases that farmers traditionally treat with chemical fungicides, but these chemicals harm the environment and create resistant fungi. Scientists are finding that algae and cyanobacteria (blue-green algae) produce natural compounds like fatty acids that can fight these fungi effectively. This research shows promising results for developing natural, environmentally-friendly fungicides that could help farmers protect crops without chemical damage.

Sandalwood Sesquiterpene (Z)-α-Santalol Exhibits In Vivo Efficacy Against Madurella mycetomatis in Galleria mellonella Larvae

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Researchers tested sandalwood compounds against a fungal infection that causes a tropical disease called eumycetoma. Using a laboratory model with wax moth larvae infected with the fungus, they found that a specific compound called (Z)-α-santalol significantly extended the survival of infected larvae. This compound was more effective than current antifungal drugs and showed promise as a potential new treatment for this neglected tropical disease.

Research Topic: Antifungal activity