Research Keyword: ROS

Neuroprotective Effect of Mixed Mushroom Mycelia Extract on Neurotoxicity and Neuroinflammation via Regulation of ROS-Induced Oxidative Stress in PC12 and BV2 Cells

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A mixture of three medicinal mushrooms (Phellinus linteus, Ganoderma lucidum, and Inonotus obliquus) was tested for its ability to protect nerve cells from damage. The extract successfully reduced cell death in laboratory models of neurodegeneration by reducing harmful molecules called reactive oxygen species and reducing inflammation. These results suggest the mushroom extract could potentially help prevent or slow neurological diseases like Alzheimer’s.

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Flammulina velutipes polysaccharides exhibit potent antioxidant and anti-pyroptotic properties in diabetes-associated periodontitis: A preliminary in vitro study

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Researchers studied a compound from the Flammulina velutipes mushroom (enoki mushroom) to see if it could help protect gum tissue in people with both diabetes and gum disease. Using human gum cell samples exposed to disease-simulating conditions, they found that the mushroom polysaccharides reduced cell damage, decreased inflammation, and prevented a harmful type of cell death called pyroptosis. The results suggest this mushroom compound could potentially be used as a supplementary treatment for people with diabetes-related gum disease.

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Cestrum tomentosum L.f. Extracts against Colletotrichum scovillei by Altering Cell Membrane Permeability and Inducing ROS Accumulation

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Researchers found that extracts from the Cestrum tomentosum plant effectively kill a fungus that causes anthracnose disease in chili peppers. The plant extract works by damaging the fungal cell membranes and causing harmful reactive oxygen species to accumulate inside fungal cells. This natural remedy showed strong protective and therapeutic effects when applied to chili pepper fruits, offering a safer alternative to synthetic chemical fungicides.

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Strain-specific effects of Desulfovibrio on neurodegeneration and oxidative stress in a Caenorhabditis elegans PD model

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This research shows that different strains of bacteria called Desulfovibrio have very different effects on brain health. When scientists exposed worms to six different strains, they found that environmental strains actually protected against Parkinson’s-like symptoms, while strains from human patients and animals caused more damage. The worms strongly preferred to eat the environmental strains, suggesting they could sense which bacteria were harmful. This highlights how the type of bacteria in our gut matters just as much as the total amount.

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Global research hotspots and trends in oxidative stress-related diabetic nephropathy: a bibliometric study

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This study analyzed over 4,000 research papers published between 2014 and 2024 about how oxidative stress damages kidneys in diabetic patients. Researchers found that China and the United States lead this research field, with increasing focus on natural compounds and traditional medicines that can reduce harmful reactive oxygen species. The findings suggest future treatments for diabetic kidney disease should target oxidative stress through both conventional drugs and natural antioxidant compounds derived from plants and fungi.

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Anoectochilus roxburghii Extract Extends the Lifespan of Caenorhabditis elegans through Activating the daf-16/FoxO Pathway

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Researchers studied a traditional Asian orchid plant (Anoectochilus roxburghii) and found it can extend the lifespan of laboratory worms by about 16% and help them resist stress from UV light and heat. The plant works by activating a specific genetic pathway that increases the worm’s natural antioxidant defenses, protecting cells from damage. These findings suggest the plant could potentially be developed into anti-aging products for humans.

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Antimicrobial effects and mechanisms of hydrogen sulphide against nail pathogens

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Researchers discovered that hydrogen sulphide (H2S), a small gas molecule, can effectively kill the fungi and bacteria that cause painful nail infections. Unlike current treatments that struggle to penetrate into the nail, hydrogen sulphide easily diffuses through the nail plate. The study found that H2S works by damaging the fungi’s respiratory system and creating harmful reactive oxygen species, while also modifying proteins in a way that disrupts their normal function. This innovative approach could offer patients a new topical treatment option for nail infections that have been difficult to treat with existing medications.

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