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Advanced adsorbents for ibuprofen removal from aquatic environments: a review

Environmental Chemistry Letters 2023 94 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 65 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Ahmed I. Osman, Ahmed I. Osman, Ahmed I. Osman, Ahmed I. Osman, Ahmed I. Osman, Ahmed I. Osman, Mika Sillanpää Ahmed I. Osman, Ali Ayati, Mika Sillanpää Mohamed Farghali, Mohamed Farghali, Mika Sillanpää Mika Sillanpää Ahmed I. Osman, Mika Sillanpää Mika Sillanpää Ahmed I. Osman, Mika Sillanpää Mika Sillanpää Ahmed I. Osman, Mika Sillanpää Pavel V. Krivoshapkin, Mika Sillanpää Ahmed S. Al‐Fatesh, Ahmed S. Al‐Fatesh, Ahmed S. Al‐Fatesh, Mika Sillanpää Bahareh Tanhaei, Bahareh Tanhaei, Ahmed I. Osman, Hassan Karimi‐Maleh, Ahmed I. Osman, Ahmed I. Osman, Ahmed I. Osman, Mohamed Farghali, Mohamed Farghali, Mika Sillanpää Mika Sillanpää Mika Sillanpää Mika Sillanpää Hassan Karimi‐Maleh, David W. Rooney, David W. Rooney, David W. Rooney, David W. Rooney, Mika Sillanpää Mohamed Farghali, Ahmed I. Osman, Hassan Karimi‐Maleh, Mika Sillanpää Ahmed I. Osman, Hassan Karimi‐Maleh, Mika Sillanpää Ikko Ihara, Ahmed I. Osman, Ahmed I. Osman, Elena F. Krivoshapkina, Mohamed Farghali, Parsana Taheri, David W. Rooney, Parsana Taheri, Mohamed Farghali, David W. Rooney, Hassan Karimi‐Maleh, Chantal Tracey, Ahmed S. Al‐Fatesh, Mika Sillanpää David W. Rooney, Ikko Ihara, Mika Sillanpää Ikko Ihara, David W. Rooney, David W. Rooney, David W. Rooney, Mika Sillanpää

Summary

This review examines advanced methods for removing ibuprofen, a common painkiller, from water systems using materials like activated carbon, biochar, and metal-organic frameworks. Ibuprofen is widespread in waterways and poses risks to aquatic life and potentially human health. Carbon-based materials showed the highest removal capacity, offering promising solutions for cleaning pharmaceutical pollution from drinking water sources.

Study Type Environmental

Abstract The presence of pharmaceuticals in ecosystems is a major health issue, calling for advanced methods to clean wastewater before effluents reach rivers. Here, we review advanced adsorption methods to remove ibuprofen, with a focus on ibuprofen occurrence and toxicity, adsorbents, kinetics, and adsorption isotherms. Adsorbents include carbon- and silica-based materials, metal–organic frameworks, clays, polymers, and bioadsorbents. Carbon-based adsorbents allow the highest adsorption of ibuprofen, from 10.8 to 408 mg/g for activated carbon and 2.5–1033 mg/g for biochar. Metal–organic frameworks appear promising due to their high surface areas and tunable properties and morphology. 95% of published reports reveal that adsorption kinetics follow the pseudo-second-order model, indicating that the adsorption is predominantly governed by chemical adsorption. 70% of published reports disclose that the Langmuir model describes the adsorption isotherm, suggesting that adsorption involves monolayer adsorption.

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