heavy metal detoxification

Modern-Day Green Strategies for the Removal of Chromium from Wastewater

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Chromium from industries like leather tanning and metal plating contaminates water and soil, causing serious health problems including cancer and organ damage. Scientists have developed eco-friendly methods using bacteria, fungi, plants, and agricultural waste to remove chromium from polluted water at low cost. These biological treatment methods are more sustainable and affordable than traditional chemical approaches, offering a promising solution for cleaning up contaminated environments.

Enhancing environmental decontamination and sustainable production through synergistic and complementary interactions of actinobacteria and fungi

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Actinobacteria and fungi are powerful microorganisms that can be used together to clean up polluted environments and improve agriculture. When these two types of organisms work together in co-cultures, they can degrade toxic substances like pesticides and heavy metals more effectively than either could alone. This approach offers a sustainable way to address environmental contamination while potentially reducing reliance on chemical treatments.

A review on microbe–mineral transformations and their impact on plant growth

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Soil microorganisms are crucial partners that help plants access nutrients locked in soil minerals. Bacteria and fungi produce special acids and molecules that dissolve minerals, making nutrients like phosphorus, iron, and zinc available for plant roots to absorb. This natural process reduces the need for chemical fertilizers and helps plants grow stronger while cleaning up contaminated soils.

Sorption of Heavy Metals (Pb, Cd, Co, and Zn) by Bacteria of the Genus Bacillus: An Investigation of the Ability and Consequences of Bioaccumulation

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Researchers studied how three types of beneficial Bacillus bacteria can remove heavy metals like lead, cadmium, zinc, and cobalt from contaminated environments. The bacteria were most effective at capturing lead, removing up to 53% of the metal from the medium. The study showed these bacteria could potentially be used as probiotic treatments to help remove toxic metals from the body or clean up polluted soil. Microscopic analysis revealed that the metals accumulate on the bacterial cell surface, causing slight changes in bacterial shape and size.

Mycorrhizae and grapevines: the known unknowns of their interaction for wine growers’ challenges

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Arbuscular mycorrhizal fungi (AMF) form beneficial partnerships with grapevine roots, improving plant health and wine quality. These fungi help grapevines absorb water and nutrients more efficiently, making them more resistant to drought and diseases. The effectiveness of this partnership depends on which specific fungi are present, the type of grapevine rootstock used, and how vineyard soil is managed. As climate change creates new challenges for wine growers, using AMF as natural biostimulants could help grapevines better tolerate heat, drought, and other stresses.

Diversity and Ecology of Fungi from Underexplored and Extreme Environments

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This editorial discusses a special collection of studies exploring fungi that thrive in extreme and challenging environments around the world, from frozen Arctic lakes to salty lagoons and polluted soils. These fungi have evolved remarkable abilities to survive harsh conditions and can even help clean up contaminated environments or support plant growth in degraded soils. Researchers are discovering previously unknown fungal species and understanding how these organisms function in ecosystems, with potential applications for cleaning pollution, improving agriculture, and biotechnology.

In Vitro Mycorrhization for Plant Propagation and Enhanced Resilience to Environmental Stress: A Review

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This review explains how scientists are using special laboratory techniques to grow fungal partnerships with plants that boost plant health and stress tolerance. By combining plant propagation with beneficial fungi in controlled conditions, researchers can produce stronger plants that survive droughts, diseases, and other environmental challenges. These techniques offer promise for sustainable farming and addressing food security concerns as climate change impacts agriculture.

Heavy Metal Remediation by Dry Mycelium Membranes: Approaches to Sustainable Lead Remediation in Water

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This research shows that dried mushroom root networks (mycelium) can effectively remove toxic lead from contaminated water, making it a natural and sustainable alternative to expensive chemical treatments. When enhanced with phosphate treatment, mycelium can remove over 95% of lead even at high concentrations. The mycelium membranes work well in continuous water filtration systems while being biodegradable and environmentally friendly, offering promising solutions for households and communities dealing with lead-contaminated drinking water.

therapeutic action: heavy metal detoxification