Fermentation – Page 4

Soy Sauce Fermentation with Cordyceps militaris: Process Optimization and Functional Profiling

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Researchers created a new type of soy sauce using Cordyceps militaris fungus, which contains health-promoting compounds. Using scientific optimization techniques, they found the best conditions for fermentation, resulting in a soy sauce with much higher levels of cordycepin and other beneficial compounds compared to traditional soy sauce. This product offers both the familiar taste of soy sauce and added health benefits, potentially serving as a functional food that people can use daily.

Enhancement of polysaccharides production using microparticle enhanced technology by Paraisaria dubia

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Researchers developed a new method to produce medicinal polysaccharides from a Cordyceps fungus using tiny talc particles to improve fermentation. By adding the right amount and size of talc particles, they were able to produce significantly more polysaccharides with beneficial health properties. The method works well in large-scale bioreactors and could be used to produce these valuable medicinal compounds more efficiently.

Editorial: Enhancing nutrient profile, safety, and sustainability with fermentation technology

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Fermentation is an ancient food preparation method that science is rediscovering as a powerful tool for making foods more nutritious and safer to eat. By using specific bacteria and fungi to ferment various foods like soybeans, grains, and vegetables, researchers have found that fermentation increases the availability of vitamins and minerals our bodies can absorb, reduces harmful compounds in foods, and helps preserve them naturally. This technology also offers sustainable solutions by making use of overlooked crops and reducing food waste, all while potentially lowering salt content in traditionally salty foods.

Dynamic changes of nutrients, isoflavone composition and antioxidant activities during liquid-state fermentation of soybean embryo homogenate by Ganoderma lucidum

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Researchers fermented soybean embryo using Ganoderma lucidum mushroom to create a more nutritious and better-tasting food product. During fermentation, the mushroom’s enzymes broke down hard-to-digest compounds and converted isoflavones into more absorbable forms while dramatically increasing antioxidant activity. The fermented product showed 8-fold higher antioxidant power and reduced unpleasant flavors, making soybean embryo a viable functional food ingredient.

Multi-Organism Composites: Combined Growth Potential of Mycelium and Bacterial Cellulose

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Scientists combined two biological materials—mycelium (fungal roots) and bacterial cellulose—to create new sustainable composites. Through a series of experiments, they found these organisms could grow together successfully when using knitted fabric as a scaffold. The main challenge was preventing mold contamination when both organisms were alive, but the resulting materials showed strong attachment and diverse functional possibilities. This research could lead to new eco-friendly materials for architecture and design.

Biosourcing and optimization of fungal lipase production from cheap agro waste via solid state fermentation

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Researchers discovered a fungus called Aspergillus oryzae that produces lipase, an important enzyme used in many industries. They found that this fungus works best when grown on cheap agricultural waste materials like wheat bran and rice bran, making enzyme production more affordable and environmentally friendly. By optimizing growth conditions and using waste materials, they successfully increased lipase production and showed this approach could be used in industrial-scale enzyme manufacturing.

Draft genome sequence of Aspergillus oryzae (Ahlburg) Cohn ATCC 16868

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Scientists have sequenced the genetic code of Aspergillus oryzae, a fungus commonly used to make fermented foods and animal feed. This fungus produces useful enzymes that break down plant materials, making nutrients more available. The completed genome sequence helps researchers ensure the fungus is safe for food production by checking for any potential health risks.

Ascoidea xinghuacunensis sp. nov., a novel ascomycetous yeast species from Xinghuacun Fenjiu old workshop, Shanxi province of China

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Scientists discovered a new type of yeast called Ascoidea xinghuacunensis from a traditional Chinese liquor-making workshop in Shanxi province. This yeast is special because it can tolerate higher temperatures (37°C) than other known yeasts of its type. The discovery is significant because it marks the first time this yeast genus has been found in China and the first time it has been identified in a liquor production environment.

Efficient conversion of tea residue nutrients: Screening and proliferation of edible fungi

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Researchers developed an environmentally friendly method to convert tea waste into nutritious fungal protein using edible mushrooms. By testing six different fungal species, they found that Monascus kaoliang B6 was most efficient at breaking down the complex fiber structures in tea residue and converting them into fungal biomass. This sustainable process eliminates the need for chemical treatments and harsh conditions, turning agricultural waste into valuable food ingredients.

Improving the production of micafungin precursor FR901379 in Coleophoma empetri using heavy-ion irradiation and its mechanism analysis

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Researchers used heavy-ion radiation to create improved strains of a fungus that produces a precursor to micafungin, an important antifungal drug. The improved strains produced over 3.5 times more of the desired compound than the original strain. By analyzing the genetic changes in these improved strains, the scientists identified which genes were most important for boosting production, helping guide future improvements in manufacturing this life-saving medicine.

Research Keyword: Fermentation