Occurrence and fate of pharmaceutical pollutants in wastewater: Insights on ecotoxicity, health risk, and state–of–the-art removal

Pharmaceutical active compound (PhAC) residues are considered an emerging micropollutant that enters the aquatic environment and causes harmful ecotoxicity. The significant sources of PhACs in the environment include the pharmaceutical industry, hospital streams, and agricultural wastes (animal husb...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2024-04, Vol.354, p.141678-141678, Article 141678
Main Authors: Nguyen, Minh-Ky, Lin, Chitsan, Bui, Xuan-Thanh, Rakib, Md. Refat Jahan, Nguyen, Hoang-Lam, Truong, Quoc-Minh, Hoang, Hong-Giang, Tran, Huu-Tuan, Malafaia, Guilherme, Idris, Abubakr M.
Format: Article
Language:English
Subjects:
Advanced oxidation processes
Constructed wetland
Eco-friendly pharmaceuticals
Membrane bioreactors
Microalgae-based treatment
Sustainable engineering
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Summary:Pharmaceutical active compound (PhAC) residues are considered an emerging micropollutant that enters the aquatic environment and causes harmful ecotoxicity. The significant sources of PhACs in the environment include the pharmaceutical industry, hospital streams, and agricultural wastes (animal husbandry). Recent investigations demonstrated that wastewater treatment plants (WWTPs) are an important source of PhACs discharging ecosystems. Several commonly reported that PhACs are detected in a range level from ng L−1 to μg L−1 concentration in WWTP effluents. These compounds can have acute and chronic adverse impacts on natural wildlife, including flora and fauna. The approaches for PhAC removals in WWTPs include bioremediation, adsorption (e.g., biochar, chitosan, and graphene), and advanced oxidation processes (AOPs). Overall, adsorption and AOPs can effectively remove PhACs from wastewater aided by oxidizing radicals. Heterogeneous photocatalysis has also proved to be a sustainable solution. Bioremediation approaches such as membrane bioreactors (MBRs), constructed wetlands (CWs), and microalgal-based systems were applied to minimize pharmaceutical pollution. Noteworthy, applying MBRs has illustrated high removal efficiencies of up to 99%, promising prospective future. However, WWTPs should be combined with advanced solutions, e.g., AOPs/photodegradation, microalgae–bacteria consortia, etc., to treat and minimize their accumulation. More effective and novel technologies (e.g., new generation bioremediation) for PhAC degradation must be investigated and specially designed for a low-cost and full-scale. Investigating green and eco-friendly PhACs with advantages, e.g., low persistence, no bioaccumulation, less or non-toxicity, and environmentally friendly, is also necessary. [Display omitted] •PhACs are found in the range from ng to μg L−1 concentration in WWTPs effluents•Pharmaceuticals have both acute and chronic harmful impacts•AOPs reach high effective removal of pharmaceuticals from wastewater owing to oxidizing radicals•The high removal efficiency of up to 99% and MBRs indicate prospective treatment•Microalgal-based technologies were applied to minimize pharmaceuticals effectively
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2024.141678