therapeutic action: bioaccumulation

Water Quality Degradation Due to Heavy Metal Contamination: Health Impacts and Eco-Friendly Approaches for Heavy Metal Remediation

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Heavy metals from factories, farms, and waste contaminate our drinking water and cause serious health problems like kidney damage and cancer. Traditional chemical methods to clean this water are expensive and create more pollution. Scientists are discovering that certain bacteria and plant materials can remove heavy metals naturally and cheaply, offering a sustainable solution to protect public health.

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Innovative Approaches and Evolving Strategies in Heavy Metal Bioremediation: Current Limitations and Future Opportunities

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Heavy metals like lead, mercury, and arsenic accumulate in soil and water, harming both ecosystems and human health. Traditional cleanup methods are expensive and harmful to the environment. Scientists are developing biological solutions using microorganisms and special plants that can absorb or break down these toxic metals, combined with genetic engineering and nanotechnology to make the process faster and more effective.

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Mycoremediation: Expunging environmental pollutants

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Fungi can be used to clean up environmental pollution from industrial waste, pesticides, and heavy metals. Unlike expensive chemical treatments, fungal mycoremediation is cost-effective and environmentally friendly. Fungi produce natural enzymes that break down harmful pollutants into harmless substances, making it a promising solution for protecting soil and water contamination.

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Ni2+ and Cd2+ Biosorption Capacity and Redox-Mediated Toxicity Reduction in Bacterial Strains from Highly Contaminated Soils of Uzbekistan

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Researchers in Uzbekistan discovered three types of bacteria that can remove dangerous heavy metals like cadmium and nickel from contaminated soil. These bacteria work by clinging to the metal particles on their surfaces and even chemically transforming them into less harmful forms. The study found that these bacteria work best at neutral pH and warmer temperatures, making them promising candidates for cleaning up polluted environments naturally and affordably.

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