immunomodulatory – mycolab.ai

Evaluation of Immune Modulation by β-1,3; 1,6 D-Glucan Derived from Ganoderma lucidum in Healthy Adult Volunteers, A Randomized Controlled Trial

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A study tested whether a supplement made from Reishi mushroom could boost immune system function in healthy adults. Over 84 days, people taking the Reishi β-glucan supplement showed significant improvements in immune cells and antibodies compared to those taking a placebo. The supplement was safe and well-tolerated with no negative side effects, suggesting it may help strengthen the body’s natural defenses against infections.

Cultivation and mycelium production from spore suspensions of desert truffles: prospective use as inoculum for host plants in arid zones

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Desert truffles are valuable edible fungi that grow in arid regions and have health benefits. This research successfully grew two desert truffle species (Terfezia boudieri and Tirmania nivea) in laboratory conditions using standard culture media. The study found that potato dextrose agar was the best medium for rapid growth, while both media supported good mycelial development. This breakthrough could enable large-scale production of truffle inoculum for reforestation programs in Morocco’s degraded desert areas.

In vitro fermentation characteristics and prebiotic activity of herbal polysaccharides: a review

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This review explores how plant-based polysaccharides from traditional herbs can benefit our health by feeding good bacteria in our gut. When these polysaccharides are fermented by our gut microbiota, they break down into smaller compounds that produce short-chain fatty acids, which have anti-inflammatory and immune-boosting effects. The research shows that different herbs have different structures that are recognized by specific beneficial bacteria, which suggests we can develop personalized functional foods tailored to promote specific health benefits.

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.

Multi-omics analysis of Taiwanofungus gaoligongensis: effects of different cultivation methods on secondary metabolites

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Researchers studied how different growing methods affect the medicinal compounds produced by Taiwanofungus gaoligongensis, a rare fungus. By growing the fungus on different substrates including wood from specific trees, they found that certain growing methods produced much higher levels of beneficial compounds like antcins that have anti-cancer and anti-inflammatory properties. They also identified which genes control the production of these compounds, which could help improve cultivation methods to make the fungus more medicinally valuable.

Multi-omics analysis of Taiwanofungus gaoligongensis: effects of different cultivation methods on secondary metabolites

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Scientists studied a medicinal mushroom called Taiwanofungus gaoligongensis to understand how different growing methods affect the production of beneficial compounds. They found that growing the mushroom in special bags with certain wood substrates produced far more of the valuable compounds (up to 12-fold more) compared to growing it on rice medium. By examining which genes were active in different growing conditions, they discovered how the mushroom’s cells control the production of these medicinal compounds, which could help farmers grow more potent medicinal mushrooms.

Multi-omics analysis of Taiwanofungus gaoligongensis: effects of different cultivation methods on secondary metabolites

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This study examined how different growing methods affect the medicinal compounds found in Taiwanofungus gaoligongensis, a rare Chinese medicinal fungus. Researchers discovered that growing this fungus on wood substrates from specific trees significantly increased production of beneficial compounds like antcins and antrodin C, which have anti-cancer and anti-inflammatory properties. By analyzing gene expression patterns, they identified key genes and regulatory mechanisms that control the production of these medicinal compounds, suggesting ways to improve cultivation methods for better medicinal value.

Burst agitation rate promotes sustained semicontinuous cultivation of filamentous fungi in stirred tank reactors

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Scientists improved the way shiitake mushrooms are grown in fermentation tanks by using a smart agitation strategy. Instead of constant stirring, they used periodic bursts of high-speed mixing to prevent clumping while maintaining healthy fungal growth. This approach increased the amount of usable biomass produced and allowed the fermentation to run longer without interruption, making mushroom cultivation more efficient and sustainable.

Multi-omics analysis of Taiwanofungus gaoligongensis: effects of different cultivation methods on secondary metabolites

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Scientists studied a medicinal mushroom species to understand how different growing methods affect its beneficial compounds. They found that growing the mushroom on specific wood substrates (from cinnamon trees) produced much higher levels of therapeutic compounds compared to rice-based cultivation. Using advanced molecular techniques, they identified the genes responsible for producing these medicinal compounds and how they are controlled, providing insights to improve mushroom cultivation for better health benefits.

A Chromosome-Scale Genome of Trametes versicolor and Transcriptome-Based Screening for Light-Induced Genes That Promote Triterpene Biosynthesis

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Scientists created a detailed map of the Trametes versicolor mushroom’s genetic code using advanced sequencing technologies. This medicinal mushroom is known for cancer-fighting and immune-boosting properties. The research discovered that light exposure increases the production of beneficial compounds called triterpenes, which may explain how this mushroom’s medicinal qualities work and could help scientists grow it more effectively.

Research Keyword: immunomodulatory