Fermentation – Page 5

Biopreservation of Hericium erinaceus By-Products via Lactic Acid Fermentation: Effects on Functional and Technological Properties

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This study shows how a natural fermentation process using beneficial bacteria can transform lion’s mane mushroom waste into a healthier food ingredient. The fermentation makes the mushrooms safer by eliminating spoilage organisms, increases their antioxidant power by up to 31%, and prevents the buildup of potentially harmful compounds. This approach offers a sustainable solution for mushroom producers to reduce waste while creating valuable functional food ingredients.

Microsclerotia formation of the biocontrol fungus Cordyceps javanica IF-1106 and evaluation of its stress tolerance and pathogenicity

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Researchers studied a fungus called Cordyceps javanica that can be used to control harmful soil nematodes that damage crop roots. The fungus produces special dormant structures called microsclerotia that can survive extreme heat and UV radiation for extended periods. These microsclerotia showed excellent effectiveness at controlling root-knot nematodes on cucumber plants while also promoting plant growth, making them a promising natural alternative to chemical pesticides.

Proteases from Pleurotus spp.: Properties, Production and Biotechnological Applications

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Oyster and king oyster mushrooms produce powerful enzymes called proteases that can break down proteins. These enzymes have multiple uses including fighting parasitic infections in animals and plants, making cheese, dissolving blood clots, and being used in detergents and cosmetics. The mushrooms can be grown on agricultural waste, making this a sustainable and cost-effective way to produce these valuable enzymes.

Exploring the Core Functional Microbiota Related to Flavor Compounds in Douchi from the Sichuan–Chongqing Region

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Douchi is a traditional Chinese fermented soybean product valued for its unique flavor. This research examined seven different douchi samples to understand which bacteria and fungi create the flavor compounds. The scientists found that specific microorganisms like Bacillus and Mucor produce different flavor molecules including fruity, floral, and caramel aromas. These findings can help producers select the best microorganisms to create better-tasting douchi products.

The value of microbial bioreactors to meet challenges in the circular bioeconomy

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Scientists are using specially designed containers called bioreactors to grow helpful microorganisms and mushrooms that can solve environmental and health problems. These bioreactors can produce medicines like natural diabetes treatments from mushrooms, create eco-friendly plastics, clean up polluted water, and turn waste products into valuable materials. This approach is sustainable, safe, and scalable, supporting the United Nations’ goals for a healthier planet.

Isolation, identification, and production optimization of natural functional pigments produced by Talaromyces atroroseus LWT-1

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Researchers isolated a special fungus called Talaromyces atroroseus that produces natural red pigments with cancer-fighting properties. These pigments killed cancer cells in laboratory tests while actually helping normal cells grow, which is an ideal combination for therapeutic potential. By optimizing growing conditions, scientists found they can produce large quantities of these pigments efficiently, offering a safe, natural alternative to synthetic dyes for food and cosmetic products.

Acid Phosphatase Produced by Trichoderma harzianum in Solid Fermentation Using Millet

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Researchers used a fungus called Trichoderma harzianum grown on millet grain to produce phosphatase enzymes, which help convert unavailable phosphorus in soil into forms that plants can use. By carefully controlling the amount of millet, moisture, and fungal starter culture, they achieved significantly higher enzyme production than previous methods. This inexpensive, sustainable approach could improve soil fertility and plant growth in agriculture.

Morphological Engineering of Filamentous Fungi: Research Progress and Perspectives

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Filamentous fungi are microscopic organisms used to produce important enzymes and chemicals in industries. However, their growth forms during fermentation vary significantly and affect product quality. Scientists are developing methods to control how these fungi grow, both by adjusting fermentation conditions like temperature and oxygen levels, and by using genetic engineering to modify their growth patterns. These approaches help improve industrial production of medicines, enzymes, and other useful compounds.

Enhanced extracellular production of laccase in Coprinopsis cinerea by silencing chitinase gene

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Scientists improved the production of laccase, an enzyme with industrial uses in detoxification and food processing, by genetically engineering mushroom cells to have stronger cell walls. By reducing the activity of genes that break down chitin in the cell wall, they created mushroom strains that could better withstand the stirring forces during fermentation, resulting in over twice as much enzyme production. This breakthrough could lead to cheaper, more efficient production of this useful green catalyst on an industrial scale.

Pigment Formation by Monascus pilosus DBM 4361 in Submerged Liquid Culture

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Scientists studied how to produce natural yellow, orange, and red pigments from the fungus Monascus pilosus in liquid culture. They found that the type of sugar and nitrogen used in the fermentation significantly affects pigment production. Interestingly, glucose actually reduces pigment formation through a process called carbon catabolite repression. M. pilosus offers a safer alternative to other Monascus species because it does not produce the harmful toxin citrinin, making it suitable for use in food products.

Research Keyword: Fermentation