antifungal – Page 7

Inhibitive effect of Urginea epigea methanolic extract and silver/zinc oxide nanoparticles on Aspergillus and aflatoxin production

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Scientists tested a plant called Urginea epigea and special tiny particles made of silver and zinc to stop a dangerous fungus called Aspergillus flavus from growing and producing aflatoxins, which are harmful poisons found in food. When used at the right concentration, the plant extract completely stopped the fungus from growing. The treatment worked by turning off the fungus’s ability to make the poison by reducing the activity of specific genes. This natural approach could offer a safer alternative to chemical fungicides for protecting our food supply.

Expression of a novel NaD1 recombinant antimicrobial peptide enhances antifungal and insecticidal activities

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Scientists created a new genetically modified tobacco plant that produces a powerful natural pest-fighting protein called NaD1. By attaching special chitin-binding components to this protein, they made it stick better to fungal pathogens and insect digestive systems. When tested, these enhanced proteins killed fungi more effectively and caused higher mortality rates in crop-damaging insects, offering a promising natural alternative to chemical pesticides.

Inhibitory Effect and Mechanism of Dryocrassin ABBA Against Fusarium oxysporum

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Researchers found that dryocrassin ABBA, a compound from a traditional East Asian fern, can effectively kill the fungus that causes potato rot disease. The compound damages the fungus by increasing harmful reactive oxygen species and disrupting the fungus’s ability to break down plant cell walls. This natural substance could potentially replace synthetic chemical fungicides, offering a safer and more environmentally friendly way to protect potatoes from disease.

Antifungal activity of zinc oxide nanoparticles (ZnO NPs) on Fusarium equiseti phytopathogen isolated from tomato plant in Nepal

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Researchers in Nepal developed a natural way to fight tomato plant diseases by creating tiny zinc oxide nanoparticles from tea leaves. These nanoparticles successfully stopped the growth of a harmful fungus called Fusarium equiseti that was damaging tomato crops. Unlike chemical fungicides that can harm the environment, this eco-friendly approach damaged the fungus’s cell structures without posing risks to surrounding ecosystems, offering farmers a safer way to protect their crops.

Essential Oils as an Antifungal Alternative to Control Several Species of Fungi Isolated from Musa paradisiaca: Part III

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This research tested how essential oils from common cooking herbs like oregano, thyme, and cinnamon can prevent fungal diseases on bananas after harvest. Scientists identified five different fungi causing banana rot, then tested six plant-based oils at different strengths to see which ones worked best. Thyme oil was most effective, completely stopping fungal growth at the highest concentration tested. These natural oils could replace harsh chemical fungicides while being safer for people and the environment.

Inhibition Mechanism of Cinnamomum burmannii Leaf Essential Oil Against Aspergillus flavus and Aflatoxins

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This research shows that essential oil from cinnamon leaves can effectively prevent a dangerous fungus (Aspergillus flavus) from contaminating stored foods like peanuts and grains, and stops it from producing a cancer-causing toxin called aflatoxin. The oil works by damaging the fungus’s cell membrane, disrupting its energy production, and triggering stress responses. Ten main aromatic compounds in the oil, especially eucalyptol and borneol, are responsible for this protective effect. This suggests cinnamon leaf oil could be used as a natural, safe alternative to chemical fungicides for protecting stored food.

An Efficient Microwave Synthesis of 3-Acyl-5-bromoindole Derivatives for Controlling Monilinia fructicola and Botrytis cinerea

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Researchers created new chemical compounds based on indoles that can kill harmful fungi affecting fruit crops. These compounds were made using microwave energy, which made the synthesis faster and more efficient. Testing showed that some of these new compounds worked better at stopping fungal growth and spore germination than currently used commercial fungicides, making them promising candidates for protecting fruit crops from rot diseases.

Identification and biological characterization of pathogen causing sooty blotch of Ardisia crispa (Thunb.) A.DC.

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Researchers identified two fungi causing sooty blotch, a serious disease affecting Ardisia crispa, an important Chinese medicinal plant. The disease creates black mold on leaves that reduces the plant’s ability to produce energy through photosynthesis. The study found that extracts from specific medicinal plants can effectively inhibit the growth of these harmful fungi, offering an environmentally friendly alternative to chemical pesticides for protecting these valuable medicinal plants.

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

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Scientists are using special fungi called pycnidial fungi to create tiny nanoparticles that could revolutionize medicine and environmental cleanup. These fungi naturally produce chemicals that can turn metal into useful nanoparticles without the toxic processes used in factories. The resulting nanoparticles show promise in fighting bacteria, cancer cells, and cleaning polluted water, offering a safer and more eco-friendly alternative to traditional methods.

Cell Wall-Mediated Antifungal Activity of the Aqueous Extract of Hedera helix L. Leaves Against Diplodia corticola

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Scientists discovered that extract from ivy leaves can effectively kill a fungus called Diplodia corticola that damages cork oak trees. The extract works by damaging the fungus’s protective cell wall rather than interfering with its internal chemistry. This natural alternative to chemical fungicides could help protect cork production worldwide while being safer for human health and the environment.

Research Keyword: antifungal