Possible remediation of hexavalent chromium by native fungi of Sukinda mining area: a review
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Published
Jul 26, 2022
Subhra Subhadarsini
Debasis Dash
https://orcid.org/0000-0002-7494-2442
Debasis Dash
Abstract
The expeditious industrialization is helping the world to give a new modern era with all sorts of amenities. But the consequences are following great risks that might result in a terrifying future. Heavy metal pollution and its hazardous effects are one of them. Though India is the 3rd largest chromium producing country and the Sukinda valley of Odisha, is the chief source for chromium, hence here the threat of chromium pollution is at a high point. Countermeasures to this problem have become of prime importance. Among several remedial measures, bioremediation is an approaching process to control the accelerated growth of heavy metal contamination including chromium. In the world of microorganisms, the congenital characteristics of fungi have great importance as they can grow easily in polluted habitats. Again, there is evidence of native fungi having the potential to bind with heavy metals and remove toxic agents from natural environments. The pathway of chromium toxicity and its possible remediation potential by fungi have been studied extensively in the Sukinda area. This study signifies some positive aspects that can be practised in the future as a convenient option for bioremediation. Fungal bioremediation improved with biotechnology tools will be suitable output for rapid remediation which is vital for this moment.
How to Cite
Subhadarsini, S., & Dash, D. (2022). Possible remediation of hexavalent chromium by native fungi of Sukinda mining area: a review. Environment Conservation Journal, 23(3), 425–438. https://doi.org/10.36953/ECJ.10502246
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Keywords
bioremediation, chromium toxicity, fungal remediation, heavy metal stress, hexavalent chromium, sukinda
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Bennett, R. M., Cordero, P. R. F., Bautista, G. S., & Dedeles, G. R. (2013). Reduction of hexavalent chromium using fungi and bacteria isolated from contaminated soil and water samples. Chemistry and Ecology, 29(4), 320-328.
Bhutiani, R., & Ahamad, F. (2018). Efficiency assessment of Sand Intermittent Filtration Technology for waste water Treatment. International Journal of advance research in science and engineering (IJARSE), 7(03), 503-512.
Bhutiani, R., Ahamad, F., & Ruhela, M. (2021). Effect of composition and depth of filter-bed on the efficiency of Sand-intermittent-filter treating the Industrial wastewater at Haridwar, India. Journal of Applied and Natural Science, 13(1), 88-94.
Bhutiani, R., Rai, N., Kumar, N., Rausa, M., & Ahamad, F. (2019). Treatment of industrial waste water using Water hyacinth (Eichornia crassipus) and Duckweed (Lemna minor): A Comparative study. Environment Conservation Journal, 20(1&2), 15-25.
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Chen, C., & Wang, J. L. (2007). Characteristics of Zn2+ biosorption by Saccharomyces cerevisiae. Biomedical and Environmental Sciences: BES, 20(6), 478-482.
Chrysochoou, M., & Johnston, C. P. (2015). Polysulfide speciation and reactivity in chromate-contaminated soil. Journal of Hazardous Materials, 281, 87-94.
Clementino, M., Shi, X., & Zhang, Z. (2018). Oxidative stress and metabolic reprogramming in Cr (VI) carcinogenesis. Current Opinion In Toxicology, 8, 20-27.
Czakó-Vér, K., Batiè, M., Raspor, P., Sipiczki, M., & Pesti, M. (1999). Hexavalent chromium uptake by sensitive and tolerant mutants of Schizo saccharomyces pombe. FEMS Microbiology Letters, 178(1), 109-115.
Das, A. P., & Mishra, S. (2010). Biodegradation of the metallic carcinogen hexavalent chromium Cr (VI) by an indigenously isolated bacterial strain. Journal of Carcinogenesis, 9.
Das, A. P., & Singh, S. (2011). Occupational health assessment of chromite toxicity among Indian miners. Indian Journal of Occupational and Environmental Medicine, 15(1), 6.
Dehghani, M. H., Taher, M. M., Bajpai, A. K., Heibati, B., Tyagi, I., Asif, M., ... & Gupta, V. K. (2015). Removal of noxious Cr (VI) ions using single-walled carbon nanotubes and multi-walled carbon nanotubes. Chemical Engineering Journal, 279, 344-352.
Dell'Anno, A., Beolchini, F., Rocchetti, L., Luna, G. M., & Danovaro, R. (2012). High bacterial biodiversity increases degradation performance of hydrocarbons during bioremediation of contaminated harbor marine sediments. Environmental Pollution, 167, 85-92.
den Braver-Sewradj, S. P., van Benthem, J., Staal, Y. C., Ezendam, J., Piersma, A. H., & Hessel, E. V. (2021). Occupational exposure to hexavalent chromium. Part II. Hazard assessment of carcinogenic effects. Regulatory Toxicology and Pharmacology, 126, 105045.
Dhal, B., Thatoi, H. N., Das, N. N., & Pandey, B. D. (2013). Chemical and microbial remediation of hexavalent chromium from contaminated soil and mining/metallurgical solid waste: a review. Journal of hazardous materials, 250, 272-291.
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