Diabetes – Page 8 – mycolab.ai

Influence of substrate formulation on some morphometric characters and biological efficiency of Pleurotus ostreatus EM-1 (Ex. Fr) Kummer grown on rice wastes and wawa (Triplochiton scleroxylon) sawdust in Ghana

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This study examined how different combinations of agricultural waste materials affect the growth and quality of oyster mushrooms. Researchers tested various recipes using rice straw, rice husks, and sawdust with different additives, composting for different lengths of time. They found strong relationships between mushroom size (cap width and stalk length) and overall yield, suggesting these measurements can reliably predict mushroom quality and help with pricing and grading.

From Microbes to Myocardium: A Comprehensive Review of the Impact of the Gut-Brain Axis on Cardiovascular Disease

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Your gut bacteria play a surprising role in heart health through a communication network called the gut-brain axis. When the balance of gut bacteria is disrupted (dysbiosis), it can lead to heart disease, high blood pressure, and clogged arteries. Beneficial bacteria produce helpful compounds like short-chain fatty acids that reduce inflammation and protect blood vessels, while harmful bacteria produce compounds that increase heart disease risk. Simple interventions like eating more fiber, taking probiotics, managing stress, and exercising can help maintain a healthy gut microbiome and improve heart health.

Plant and Fungal Polysaccharides in Periodontitis Treatment: Diverse Mechanisms and Therapeutic Roles

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Periodontitis is a serious gum disease that causes tooth loss and affects overall health. This review examines how polysaccharides (complex carbohydrates) from plants and fungi can help treat periodontitis by reducing inflammation, fighting bacteria, and helping gum tissue repair. These natural compounds work through multiple biological pathways to improve oral health outcomes while avoiding the side effects and resistance problems associated with conventional drugs.

Advancing Pistacia terebinthus L. (Anacardiaceae) Research: Food Preservation, Functional Foods, and Nutraceutical Potential

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The turpentine tree (Pistacia terebinthus L.) is a Mediterranean plant traditionally used in food and medicine that is now being studied for modern food applications. Its fruits, seeds, leaves, and resin contain powerful compounds that fight bacteria, reduce oxidative stress, and promote health. Scientists are developing new techniques like microencapsulation and fermentation to preserve its beneficial properties in functional foods, yogurt, and other products. This underutilized plant could become an important natural ingredient for food preservation and health supplements.

Biologically active secondary metabolites from white-rot fungi

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White-rot fungi are special mushrooms that can break down wood and produce unique chemical compounds with amazing health benefits. These compounds have been found to fight cancer, kill harmful bacteria, reduce inflammation, and protect nerve cells. Scientists are excited about using these natural fungal compounds to create new medicines and treat various diseases in the future.

Fruit and Vegetable Processing Waste as Potential Raw Material for Food Enrichment With Dietary Fiber

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This study examined the fiber content of leftover materials from processing fruits and vegetables, finding that pomace (processing waste) is an excellent source of dietary fiber. Chokeberries and blackcurrants were found to have particularly high fiber levels, while apples and carrots were rich in soluble fiber types. These waste products can be used to create nutritious fiber-enriched foods and supplements, providing both environmental benefits by reducing waste and health benefits through increased dietary fiber consumption.

Polysaccharides from fungi: A review on their extraction, purification, structural features, and biological activities

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Mushrooms contain special compounds called polysaccharides that have powerful health benefits. Scientists have found these polysaccharides can help fight cancer, boost immunity, reduce inflammation, and manage diabetes. This review explains different ways to extract and purify these beneficial compounds from mushrooms and describes how they work in the body to provide these health benefits.

Unveiling the full spectrum of maitake mushrooms: A comprehensive review of their medicinal, therapeutic, nutraceutical, and cosmetic potential

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Maitake mushrooms, long used in Asian traditional medicine, contain powerful compounds that may help fight cancer, support immune function, manage blood sugar, and protect skin health. Research shows they can inhibit bacterial and viral infections, reduce tumor growth in various cancer types, and improve overall metabolic health. These mushrooms can be incorporated into food-based supplements and skincare products. While promising results have been seen in laboratory and animal studies, more human clinical trials are needed to fully understand their benefits and safety.

Airlift bioreactor–based strategies for prolonged semi-continuous cultivation of edible Agaricomycetes

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Scientists studied how to grow medicinal mushrooms in liquid bioreactors to produce health-beneficial compounds called glucans more efficiently. By testing different feeding rates in specially designed fermentation systems, they found that Trametes versicolor (turkey tail mushroom) grows best at a moderate feeding rate, producing substantial amounts of glucans—compounds known to support immune function and reduce blood sugar levels. This research shows that growing medicinal mushrooms in controlled bioreactors could be much more efficient and faster than traditional farming methods.

Functional Approaches to Discover New Compounds via Enzymatic Modification: Predicted Data Mining Approach and Biotransformation-Guided Purification

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Scientists are developing faster ways to discover new medicines from plants using two innovative methods. The first approach uses computer programs to predict which plant compounds can be chemically modified by enzymes to create new medicines with better properties. The second approach combines enzyme chemistry with traditional purification to directly isolate these modified compounds from plant extracts. These methods have successfully created new compounds with improved effectiveness against diseases like diabetes and cancer, often with much better solubility for medical use.

Disease: Diabetes