Research Topic: Heavy metal toxicity

Mitigating nickel-induced toxicity: the protective role of native probiotic strains on oxidative stress and inflammatory pathways in mice lung tissues

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This study examined how probiotic bacteria can protect lung tissue from damage caused by nickel exposure. Researchers gave mice nickel to cause oxidative stress and inflammation, then treated them with beneficial bacteria from four probiotic strains. The probiotics successfully reduced oxidative stress markers and inflammatory responses in the lung tissue by activating protective genes and deactivating inflammatory genes. This research suggests that probiotics could be a natural way to prevent lung damage from heavy metal exposure.

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Efficacy of Lacticaseibacillus rhamnosus probiotic strains in treating chromate induced dermatitis

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This research shows that a beneficial bacteria called Lacticaseibacillus rhamnosus can help treat skin problems caused by chromate exposure, a common hazard for construction workers and factory employees. The bacteria work by reducing toxic chromate to a less harmful form through a special protein called flavin reductase. When tested on mice with chromate-induced skin damage, the probiotic treatment significantly improved skin healing and reduced inflammation. This suggests these beneficial bacteria could offer a safe, natural treatment for occupational skin conditions caused by heavy metal exposure.

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Molecular mechanisms of metal toxicity and transcriptional/post-transcriptional regulation in plant model systems

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Plants face serious damage from heavy metals like cadmium, arsenic, and chromium in contaminated soils and water. Scientists are discovering how plants defend themselves through changes in gene expression, special proteins that trap metals, and modifications to their DNA that control stress response genes. Understanding these natural defense mechanisms could help us develop crops that survive in polluted environments and remove heavy metals from contaminated areas, making food safer and protecting human health.

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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.

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Impact of sublethal zinc exposure on ectomycorrhizal Laccaria bicolor x poplar symbiosis

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This research examines how a fungus called Laccaria bicolor helps poplar trees survive in soil contaminated with excess zinc. The study found that even under zinc stress, the fungus and tree can maintain their symbiotic partnership, though both grow slower and the fungal layer around roots thins. The fungus activates special defense mechanisms and transporter proteins to manage zinc levels and protect the tree host, demonstrating remarkable resilience of this natural partnership.

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