Research Keyword: microbial fermentation

Bioactive Peptides from Quinoa (Chenopodium quinoa Willd.) as Modulators of the Gut Microbiome: A Scoping Review of Preclinical Evidence

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This review examines how quinoa and its protein-derived peptides can improve gut health by changing the balance of bacteria in the digestive system. Research shows that quinoa helps boost beneficial bacteria, increases diversity of microbial communities, and promotes production of butyrate, a beneficial compound that supports intestinal health. Different disease conditions show specific improvements, such as reduced harmful bacteria in colitis and better metabolic balance in obesity, suggesting quinoa could be tailored for personalized health interventions.

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Sustainable Innovations in Food Microbiology: Fermentation, Biocontrol, and Functional Foods

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This review explores how microorganisms can make food production more sustainable and healthier. It discusses traditional fermented foods like yogurt and sauerkraut, modern biotechnology techniques to reduce food waste and create natural preservatives, and special food ingredients with beneficial bacteria that support digestive and mental health. The paper shows how applying microbial science could help address global food challenges while meeting consumer demands for natural, safe, and healthy products.

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Biochemical and molecular characterization of fungal isolates from California annual grassland soil

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Scientists studied soil fungi from California grasslands to find the best strains for producing biofuels and health supplements. They discovered that Mortierella fungi are especially good at accumulating oils and producing beneficial compounds like arachidonic acid. Three specific fungal strains stood out as having the highest oil content and best fatty acid profiles, making them promising candidates for industrial production of sustainable fuels and nutritional supplements.

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Ascosphaera apis as a target for the antifungal activity of symbiotic Bifidobacteria in honey bees

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Researchers found that certain beneficial bacteria (Bifidobacterium asteroides) living in honey bee guts can fight the fungus that causes chalkbrood disease, a serious condition affecting bee colonies. These bacteria produce natural compounds, especially propanoic acid and ethanol, that kill the fungus and prevent it from growing. This discovery offers a safe, natural alternative to chemical treatments for protecting honeybees from fungal infections while maintaining colony health.

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Research on Development and Challenges of Forest Food Resources from an Industrial Perspective—Alternative Protein Food Industry as an Example

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As the global population grows, we need new sources of protein to feed everyone sustainably. Scientists are developing four main types of alternative proteins from forests: edible insects, plants, microorganisms like mushrooms and yeast, and lab-grown meat. While these technologies show tremendous promise and are already appearing in stores, they still face challenges like high costs, safety concerns, and consumer hesitation. Solving these problems will require better research, clearer safety standards, and coordinated efforts across industries and governments.

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Quorum-driven microbial consortium for Bioplastic production from agro-waste

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Scientists created a partnership between a fungus and bacteria to make eco-friendly plastic (PHA) from brewery and cooking waste. The fungus breaks down the tough plant material while the bacteria converts the released compounds into bioplastic. By adding a natural chemical signal (farnesol), they improved the process and scaled it up successfully in a larger reactor without needing expensive pretreatment steps.

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Consolidated Bioprocess for Bioethanol Production from Raw Flour of Brosimum alicastrum Seeds Using the Native Strain of Trametes hirsuta Bm-2

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Scientists successfully used a wood-rotting fungus called Trametes hirsuta to convert ramon tree seeds (which contain lots of starch) into bioethanol in a simple one-step process. The fungus naturally produces its own enzymes to break down the starch and ferment it into ethanol, eliminating the need for expensive commercial enzymes. The leftover material from this process contains high protein content and could be used as animal feed, making the process economically attractive for sustainable biofuel production.

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