A comprehensive review on microalgae-driven heavy metals removal from industrial wastewater using living and nonliving microalgae

IF 5.4 Q2 ENGINEERING, ENVIRONMENTAL
Mohammed Omar Faruque , Shihab Uddin , Mohammad Mozahar Hossain , S.M. Zakir Hossain , Md. Shafiquzzaman , Shaikh Abdur Razzak
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Abstract

The growth of industry has caused heavy metals (HMs) to become one of the most important water pollutants because they are toxic and hurt the environment. As a consequence of HMs contamination and its effects on the environment and public health, there is a growing desire to develop a sustainable strategy for removing HMs from industrial wastewater. HMs have been sequestered using a number of traditional eradication methods. Unfortunately, for large-scale projects, the majority of these methods are expensive, require rigorous control and continuous monitoring, and are inefficient for the removal of hazardous materials. As a sustainable technique for removing HMs from industrial effluent, the use of both living and nonliving microalgal cells in microalgae-based bioremediation is investigated in this context. Additionally, it has many advantages over conventional remediation techniques, including being easily accessible, inexpensive, effective at removing hazardous metals, and environmentally friendly. This review seeks to provide exhaustive information to support the development of microalgal-based HMs bioremediation. It includes the selection of suitable microalgae strains for HM removal, the mechanisms involved (biosorption and bioaccumulation), and the factors influencing the removal of HMs from industrial effluent, among other topics. In addition, different types of biosorption models have been addressed to predict the efficiency and effectiveness of HM removal by microalgal biomass. To conclude, this study emphasizes the critical role of microalgae in advancing wastewater treatment technologies and promoting environmental protection.

Abstract Image

利用生物和非生物微藻去除工业废水中重金属的综述
工业的发展导致重金属(HMs)成为最重要的水污染物之一,因为它们具有毒性并对环境造成危害。由于 HMs 污染及其对环境和公众健康的影响,人们越来越希望开发出一种可持续的策略来清除工业废水中的 HMs。人们已经使用多种传统的根除方法对 HMs 进行了封存。遗憾的是,对于大型项目而言,这些方法大多成本高昂,需要严格控制和持续监测,而且去除有害物质的效率低下。作为一种从工业废水中去除 HMs 的可持续技术,本文研究了在基于微藻的生物修复中使用活体和非活体微藻细胞。此外,与传统的修复技术相比,微藻生物修复技术具有许多优点,包括容易获得、成本低廉、能有效去除有害金属以及对环境友好。本综述旨在提供详尽的信息,以支持基于微藻的 HMs 生物修复技术的发展。内容包括去除 HMs 的合适微藻菌株的选择、相关机制(生物吸附和生物累积)以及影响从工业废水中去除 HMs 的因素等。此外,还探讨了不同类型的生物吸附模型,以预测微藻生物质去除 HM 的效率和效果。总之,本研究强调了微藻在推进废水处理技术和促进环境保护方面的关键作用。
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来源期刊
Journal of hazardous materials advances
Journal of hazardous materials advances Environmental Engineering
CiteScore
4.80
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