mycotoxin reduction – mycolab.ai

Olive mill solid waste induces beneficial mushroom-specialized metabolite diversity revealed by computational metabolomics strategies

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Researchers studied how adding olive mill waste to mushroom growing substrate affects the beneficial compounds in two edible mushrooms. They used advanced computer analysis of chemical data to find that this waste product increases healthy compounds like hericenones while reducing potentially harmful mycotoxins. This discovery could help make mushroom farming more sustainable and produce safer, healthier mushrooms for consumers.

Citric acid impairs type B trichothecene biosynthesis of Fusarium graminearum but enhances its growth and pigment biosynthesis: transcriptomic and proteomic analyses

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Researchers discovered that citric acid, a natural acid found in plant roots and commonly used in agriculture, can reduce the production of dangerous mycotoxins called trichothecenes that contaminate wheat and corn crops. While citric acid surprisingly boosts the fungus’s growth and changes its color, it simultaneously shuts down the genes responsible for producing these toxic compounds. This discovery could help farmers use citric acid more strategically to prevent Fusarium head blight, a devastating crop disease, though care must be taken since it also promotes fungal growth.

Talaromyces pinophilus Strain HD25G2 as a Novel Biocontrol Agent of Fusarium culmorum, the Causal Agent of Root and Crown Rot of Soft Wheat

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Researchers discovered that a fungus called Talaromyces pinophilus can fight against Fusarium culmorum, a harmful fungus that damages wheat crops and produces toxic compounds. The beneficial fungus works by producing natural enzymes that break down the walls of harmful fungal cells. Importantly, when applied before the harmful fungus appears, it completely prevents infection and toxin production, offering farmers a natural alternative to chemical pesticides.

Effect of Popcorn (Zea mays var. everta) Popping Mode (Microwave, Hot Oil, and Hot Air) on Fumonisins and Deoxynivalenol Contamination Levels

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This study examined how different popping methods affect harmful toxins (called mycotoxins) in popcorn. Researchers tested 39 popcorn samples using three cooking methods: hot air, hot oil, and microwave, measuring how much the dangerous toxins fumonisins and deoxynivalenol decreased. They found that all three methods reduced toxin levels, with hot oil popping being the most effective, reducing fumonisins by 98% and deoxynivalenol by 58%. These findings suggest that eating properly prepared popcorn can significantly reduce exposure to naturally occurring toxins in corn.

Research Keyword: mycotoxin reduction

Olive mill solid waste induces beneficial mushroom-specialized metabolite diversity revealed by computational metabolomics strategies

Citric acid impairs type B trichothecene biosynthesis of Fusarium graminearum but enhances its growth and pigment biosynthesis: transcriptomic and proteomic analyses

Talaromyces pinophilus Strain HD25G2 as a Novel Biocontrol Agent of Fusarium culmorum, the Causal Agent of Root and Crown Rot of Soft Wheat

Effect of Popcorn (Zea mays var. everta) Popping Mode (Microwave, Hot Oil, and Hot Air) on Fumonisins and Deoxynivalenol Contamination Levels