mycelial growth inhibition

Green synthesis of silver nanoparticles by sweet cherry and its application against cherry spot disease

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Researchers developed a natural, eco-friendly method to fight a fungal disease that damages sweet cherries after harvest. Using tiny silver particles created from cherry fruit extracts, they successfully stopped the growth of harmful Alternaria fungi. This approach offers farmers an environmentally safe alternative to traditional chemical fungicides while protecting cherry crops from rot.

Benzothiazole—An Antifungal Compound Derived from Medicinal Mushroom Ganoderma lucidum against Mango Anthracnose Pathogen Colletotrichum gloeosporioides

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Scientists discovered that a chemical called benzothiazole found in the medicinal mushroom Ganoderma lucidum can effectively kill the fungus that causes mango anthracnose, a major disease affecting mango crops. The research showed that this natural compound completely stops fungal growth at very low concentrations (50 ppm) and prevents spore germination. This discovery offers a promising eco-friendly alternative to synthetic fungicides that can cause environmental pollution and drug resistance.

Essential Oil of Xylopia frutescens Controls Rice Sheath Blight Without Harming the Beneficial Biocontrol Agent Trichoderma asperellum

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Researchers discovered that oil extracted from leaves of a Brazilian plant called Xylopia frutescens effectively kills the fungus that causes rice sheath blight, a serious disease that can destroy rice crops. The oil contains two main compounds that work against the fungus and can be applied before or after infection to prevent or treat the disease. Importantly, the oil doesn’t harm beneficial fungi like Trichoderma asperellum that farmers use as natural pest control, making it an environmentally friendly alternative to chemical fungicides.

Nanoemulsion formulation of lemongrass essential oil using Pseudomonas-derived rhamnolipids for targeted phytopathogen suppression

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This study developed a nano-sized formulation of lemongrass oil stabilized with naturally-derived rhamnolipid surfactant to fight plant fungal diseases. The formulation successfully inhibited the growth of three major plant pathogens and remained stable during storage. This bio-based approach offers farmers an environmentally-friendly alternative to synthetic chemical fungicides for protecting crops.

Inhibitory and synergistic effects of volatile organic compounds from bat caves against Pseudogymnoascus destructans in vitro

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Researchers discovered that two natural compounds found in bat cave environments—isovaleric acid and ethyl methyl carbonate—can effectively kill the fungus that causes white-nose syndrome in bats. When used together, these compounds work even better than alone, disrupting the fungus’s cell membranes, causing it to produce too many reactive molecules (free radicals), and triggering cell death. This discovery offers hope for developing new treatments to protect bat populations that have been devastated by this disease in North America.

Antifungal Effect of Chitosan/Nano-TiO2 Composite Coatings against Colletotrichum gloeosporioides, Cladosporium oxysporum and Penicillium steckii

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This research demonstrates that a coating made from chitosan combined with tiny titanium dioxide particles effectively kills three types of mold that spoil mangoes after harvest. The composite coating works by breaking down the mold’s cell membranes and causing them to leak their contents, leading to cell death. This combination is more effective than chitosan alone, with some mold species being completely eliminated at optimal concentrations.

Actinomycetes isolated from rhizosphere of wild Coffea arabica L. showed strong biocontrol activities against coffee wilt disease

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Researchers discovered that certain bacteria called actinomycetes, particularly a strain called MUA26, can effectively fight coffee wilt disease, a serious fungal infection that damages coffee plants. These beneficial bacteria produce natural compounds that kill the disease-causing fungus and were tested on coffee seedlings in a greenhouse, showing 83% effectiveness at preventing the disease. This discovery offers coffee farmers an organic alternative to chemical pesticides, which are expensive and harmful to the environment.

Pathogen identification and biological fungicides screening for Plumbago auriculata blight in China

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A newly identified fungal disease caused by Fusarium ipomoeae is harming Plumbago auriculata plants in China. Scientists identified the pathogen using genetic analysis and tested seven plant-based treatments. They found that osthole, a natural compound, effectively controls the disease with 88% success rate, offering an environmentally friendly solution for protecting ornamental plants.

Morphological, molecular, and biological characterization of bulb rot pathogens in stored Lanzhou lily and the in vitro antifungal efficacy of three plant essential oils

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Lanzhou lily is a valuable medicinal and food plant that loses 20-25% of its crop annually due to fungal rot during storage. Researchers identified the main culprit as a fungus called Fusarium oxysporum and found that natural essential oils from cinnamon, tea tree, and angelica plants can effectively inhibit this fungus’s growth. Cinnamon essential oil proved most effective and could serve as a natural alternative to chemical fungicides for protecting stored lily bulbs.

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.

therapeutic action: mycelial growth inhibition