Bioremediation of Toxic Metals Using Aquatic Macrophytes: Challenges and Opportunities

IF 1.5 4区环境科学与生态学 Q4 ENVIRONMENTAL SCIENCES

Clean-soil Air Water Pub Date : 2024-09-20 DOI:10.1002/clen.202400273

Salam Suresh Singh, Maibam Dhanaraj Meitei, Keshav Kumar Upadhyay, Rajdeep Chanda, Ramthar Mawi, Ngangbam Somen Singh, Francis Q. Brearley, Shri Kant Tripathi

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Abstract

Environmental pollution caused by urbanization, agricultural intensification, and industrialization has led to an increase in the disposal of toxic effluents in aquatic environments. Most ecosystems in the world receive a variety of toxic metals (TMs) that exceed the capacity of water bodies to absorb or recycle them, thereby threatening aquatic and human life. Physicochemical remediation methods encounter problems because of the high cost, labor input, and use of chemicals with long residence times that later add toxic by-products. However, bioremediation techniques are a safe option for mitigating environmental pollution because of their high efficiency, cost-effectiveness, non-intrusiveness, eco-friendliness, ease of application, and social acceptance. Submerged and free-floating macrophytes were found to be more effective in the bioaccumulation of TMs than emergent macrophytes. Furthermore, most studies have suggested the use of macrophytes for the removal of TMs from water bodies; however, studies on the management of phytoremediated biomass are scarce. This review demonstrates the role of various macrophytes for the removal of TMs from water bodies and suggests techniques for the disposal and recycling of phytoremediated biomass with accumulated TMs. Further, the applications of genetically modified plants, nanotechnology, and native hyperaccumulators have been suggested as suitable candidates for greater efficiency of phytoremediation and appropriate management of TMs in the environment in the future.

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利用水生大型营养体对有毒金属进行生物修复：挑战与机遇

城市化、农业集约化和工业化造成的环境污染导致水生环境中有毒废水的排放增加。世界上大多数生态系统都会接收到各种有毒金属（TMs），这些有毒金属超出了水体的吸收或循环能力，从而威胁到水生生物和人类的生命。物理化学修复方法由于成本高、劳动力投入大、使用的化学物质停留时间长，随后会产生有毒的副产品，因此会遇到一些问题。然而，生物修复技术因其高效率、成本效益高、无干扰、生态友好、易于应用和社会认可而成为减轻环境污染的安全选择。研究发现，沉水和自由浮游的大型水草比浮出水面的大型水草更能有效地生物累积三卤甲烷。此外，大多数研究都建议利用大型藻类植物清除水体中的三卤甲烷，但有关植物修复生物量管理的研究却很少。本综述展示了各种大型植物在清除水体中的三卤甲烷方面的作用，并提出了处理和回收累积三卤甲烷的植物修复生物质的技术。此外，还提出了转基因植物、纳米技术和本地超积累植物的应用，这些都是未来提高植物修复效率和适当管理环境中三卤甲烷的合适候选植物。

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来源期刊

Clean-soil Air Water 环境科学-海洋与淡水生物学

CiteScore

2.80

自引率

5.90%

发文量

审稿时长

3.6 months

期刊介绍： CLEAN covers all aspects of Sustainability and Environmental Safety. The journal focuses on organ/human--environment interactions giving interdisciplinary insights on a broad range of topics including air pollution, waste management, the water cycle, and environmental conservation. With a 2019 Journal Impact Factor of 1.603 (Journal Citation Reports (Clarivate Analytics, 2020), the journal publishes an attractive mixture of peer-reviewed scientific reviews, research papers, and short communications. Papers dealing with environmental sustainability issues from such fields as agriculture, biological sciences, energy, food sciences, geography, geology, meteorology, nutrition, soil and water sciences, etc., are welcome.