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

Summary

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.

Background

Heavy metal contamination poses persistent risks to ecosystems and human health through bioaccumulation in environmental compartments including soil, water, and biota. Despite decades of technological advancement, conventional remediation techniques remain costly and environmentally aggressive. Bioremediation has emerged as a sustainable, environmentally friendly alternative for heavy metal decontamination.

Objective

This review explores recent advancements, ongoing challenges, and future perspectives in heavy metal bioremediation. The study aims to present current bioremediation methods for non-essential heavy metals (arsenic, lead, cobalt, cadmium, chromium, mercury, nickel), explore innovative strategies including genetic engineering and nanotechnology, and identify future opportunities for optimizing bioremediation applicability in real-world scenarios.

Results

Analysis identified 256,152 papers on heavy metals published over 34 years, with publications exceeding 20,000 annually by 2022. China, USA, and India led in publications. Key bioremediation mechanisms including biosorption, bioaccumulation, and biotransformation were identified. Microbial strains and plants demonstrated significant heavy metal removal efficiency ranging from 23.79% to 100% depending on species and conditions. Emerging approaches using genetic engineering and nanotechnology showed promise in overcoming scalability limitations.

Conclusion

Bioremediation represents a viable, sustainable alternative to conventional heavy metal remediation methods. Genetic engineering and nanotechnology offer significant potential for enhancing bioremediation efficiency and expanding field applications. Further research is essential to evaluate long-term risks and feasibility while addressing regulatory and public perception barriers to large-scale implementation.
  • Published in:Journal of Xenobiotics,
  • Study Type:Review,
  • Source: 40407527
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