Mycotoxin contamination

Pleurotus spp.—an effective way in degradation mycotoxins? A comprehensive review

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This review examines how oyster mushrooms (Pleurotus species) can break down mycotoxins—harmful compounds produced by molds in food and animal feed. These mushrooms produce special enzymes that can degrade toxins like aflatoxins and zearalenone, potentially reaching 30-100% degradation depending on conditions. This offers a safer, more environmentally friendly alternative to chemical detoxification methods currently used in the food industry.

Essential Oil Nanoemulsions—A New Strategy to Extend the Shelf Life of Smoothies

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This review explores how essential oil nanoemulsions could naturally preserve smoothies and extend their freshness. Essential oils have antimicrobial and antioxidant properties but taste and smell too strong at effective doses. Nanoemulsions—tiny oil droplets encapsulated in water—solve this problem by being more effective at lower concentrations while maintaining good taste, making them a promising natural alternative to chemical preservatives.

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.

Transforming Tomato Industry By-Products into Antifungal Peptides Through Enzymatic Hydrolysis

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Researchers have found a way to turn tomato processing waste into useful antifungal compounds. By breaking down tomato seed proteins using enzymes, they created peptides that can prevent harmful fungi like Fusarium from growing on crops. This discovery helps reduce food waste while providing a natural alternative to chemical pesticides for protecting tomato and grain crops.

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.

Phylogeny of Aspergillus section Circumdati and inhibition of ochratoxins potential by green synthesised ZnO nanoparticles

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Researchers identified four types of Aspergillus fungi that contaminate crops and produce a toxic substance called ochratoxin. They tested whether tiny zinc oxide particles, created using plant extracts, could stop these fungi from making toxins. The green-synthesized nanoparticles successfully reduced toxin production in some fungal species, offering a promising natural approach to protecting food crops.

Influence of Light Spectrum on Bread Wheat Head Colonization by Fusarium graminearum and on the Accumulation of Its Secondary Metabolites

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Researchers studied how different colors of light affect a fungal disease in wheat and the toxic compounds it produces. They found that blue light reduces disease spread but increases toxin production, while red light also reduces disease but increases different types of toxins. This discovery could help farmers better manage wheat diseases by understanding how light conditions affect both the fungus and the grain’s safety.

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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This study tested a natural extract from grapevine pruning waste to see if it could stop three dangerous fungi that produce harmful toxins in crops. The extract worked well at stopping both fungal growth and toxin production, with effects that lasted even after the extract was removed. These results suggest that grapevine waste could be turned into a natural fungicide to protect crops from contamination.

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

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This review examines how fatty acids and other compounds from algae and cyanobacteria can naturally fight Fusarium fungus, which damages crops like wheat, corn, and tomatoes. Traditional chemical fungicides harm the environment and can make fungi resistant, so scientists are exploring algae-based alternatives that work sustainably. The research shows these algal compounds can damage fungal cell membranes and boost plant defenses against infection. While promising, more work is needed to develop these natural solutions for practical farm use.

Disease: Mycotoxin contamination