neurological disorders

Role of Genetically Modified Microorganisms for Effective Elimination of Heavy Metals

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Heavy metals like lead, mercury, and arsenic are dangerous pollutants that accumulate in our environment and food chain, causing serious health problems. Traditional methods to remove these metals are expensive and inefficient. Scientists have created genetically modified bacteria and fungi that are much better at absorbing and breaking down heavy metals from contaminated water and soil, offering a cheaper and more environmentally friendly solution to clean up pollution.

Biological approaches to mitigate heavy metal pollution from battery production effluents: advances, challenges, and perspectives

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Battery factories produce dirty water containing harmful heavy metals like lead and cadmium. Instead of using expensive chemical treatments, scientists are finding natural ways to clean this water using plants, bacteria, and other living organisms. These biological methods can remove up to 99% of the metals and are better for the environment. This review examines all these natural cleaning methods and suggests ways to make battery production cleaner and safer.

Microbes’ role in environmental pollution and remediation: a bioeconomy focus approach

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Microbes like bacteria and fungi can break down pollutants and transform harmful waste into useful products through biological processes called bioremediation. By employing these naturally occurring or genetically modified microorganisms, we can clean up contaminated soil and water while producing valuable products like proteins and biofuels. This approach offers an environmentally friendly and economically sustainable solution to waste management that reduces pollution while creating a circular bioeconomy.

Scoping Review on Mitigating the Silent Threat of Toxic Industrial Waste: Eco-Rituals Strategies for Remediation and Ecosystem Restoration

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This review examines how industrial waste contaminates soil and water through heavy metals and chemicals, harming ecosystems and human health through food chain contamination. The study shows that pollutants like cadmium and lead kill aquatic life, reduce soil fertility, and disrupt beneficial soil microorganisms. The review recommends solutions including cleaner manufacturing practices, advanced wastewater treatment, and eco-friendly methods like using plants to absorb contaminants.

Biodegradation of BTEX by Bacteria Isolated From Soil Contaminated With Petroleum Sludge and Liquid and Solid Petrochemical Effluents

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Scientists isolated bacteria from oil-contaminated soil that can effectively break down BTEX chemicals, which are toxic pollutants from petroleum products. Two bacterial strains, Arthrobacter pascens and Bacillus sp., proved most effective at degrading these harmful compounds, removing over 80% within 12 days. These findings suggest these bacteria could be used to clean up contaminated sites naturally and cost-effectively.

Bioactive Potential of Tocosh Supplemented with Selenium-Enriched Saccharomyces Cerevisiae Biomass

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Researchers enhanced a traditional Peruvian fermented potato food called tocosh by adding selenium-enriched yeast. This combination reduced inflammation markers in immune cells without affecting its blood sugar impact or antioxidant properties. The resulting product shows promise as a functional food that could help people manage inflammatory conditions while improving nutritional content.

Fungal β-Glucans: Biological Properties, Immunomodulatory Effects, Diagnostic and Therapeutic Applications

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β-glucans are beneficial compounds found in fungi and some plants that help your body in multiple ways. They boost your immune system, lower cholesterol and blood sugar, protect against oxidative stress, and may help fight cancer and infections. Recent research shows they could be useful as diagnostic markers for fungal infections and as vaccine boosters, especially for diseases like COVID-19.

Biological applications of yttrium oxide nanocomposites synthesized from Aspergillus penicillioides and their potential role in environmental remediation

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Researchers used a fungus called Aspergillus penicillioides to create tiny particles of yttrium oxide that can remove dangerous metals like lead and nickel from contaminated water. These particles work like microscopic sponges that grab onto the toxic metals when exposed to UV light. The particles also kill bacteria and fight harmful free radicals, making them useful for both cleaning water and potentially treating infections.

Influence of Culture Conditions on Bioactive Compounds in Cordyceps militaris: A Comprehensive Review

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This review examines how growing conditions affect the medicinal compounds produced by Cordyceps militaris mushrooms. The research shows that factors like light exposure, specific nutrient combinations, and growing on insect-based substrates can significantly boost production of beneficial compounds like cordycepin. These findings suggest ways to produce more effective and affordable medicinal mushroom products for use in supplements and pharmaceuticals.

Influence of Culture Conditions on Bioactive Compounds in Cordyceps militaris: A Comprehensive Review

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Cordyceps militaris is a medicinal fungus that produces powerful health-promoting compounds used to boost energy, strengthen immunity, and fight cancer. This review explains how different growing conditions—like the type of food the fungus is grown on, light exposure, and temperature—affect which beneficial compounds it produces and how much. By optimizing these conditions, producers can create more effective products for health supplements and medicines, though more research is needed to standardize production methods.

Disease: neurological disorders