Pharmaceuticals as emerging contaminants and their removal from water. A review
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The main objective of this study was to conduct an exhaustive review of the literature on the presence of pharmaceutical-derived compounds in water and on their removal. The most representative pharmaceutical families found in water were described and related water pollution issues were analyzed. The performances of different water treatment systems in the removal of pharmaceuticals were also summarized. The water treatment technologies were those based on conventional systems (chlorine, chlorine dioxide, wastewater treatment plants), adsorption/bioadsorption on activated carbon (from lotus stalks, olive-waste cake, coal, wood, plastic waste, cork powder waste, peach stones, coconut shell, rice husk), and advanced oxidation processes by means of ozonation (O3, O3/H2O2, O3/activated carbon, O3/biological treatment), photooxidation (UV, UV/H2O2, UV/K2S2O8, UV/TiO2, UV/H2O2/TiO2, UV/TiO2/activated carbon, photo-Fenton), radiolysis (e-Beam, 60Co, 137Cs. Additives used: H2O2, SO32-, HCO3-, CH3OH, CO32-, or NO3-), and electrochemical processes (Electrooxidation without and with active chlorine generation). The effect of these treatments on pharmaceutical compounds and the advantages and disadvantages of different methodologies used were described. The most important parameters of the above water treatment systems (experimental conditions, removal yield, pharmaceutical compound mineralization, TOC removal, toxicity evolution) were indicated. The key publications on pharmaceutical removal from water were summarized. © 2013 Elsevier Ltd.
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Adsorption; Ozonation; Pharmaceuticals; Photodegradation; Radiolysis; Removal Activated carbon; Activated carbon treatment; Additives; Adsorption; Drug products; Electrooxidation; Oxidation; Ozone; Ozone water treatment; Ozonization; Petroleum tar; Photodegradation; Photooxidation; Radiation chemistry; Radiolysis; Removal; Waste treatment; Wastewater treatment; Water pollution; Advanced Oxidation Processes; Conventional systems; Electrochemical process; Experimental conditions; Pharmaceutical compounds; Wastewater treatment plants; Water treatment systems; Water treatment technologies; Chemicals removal (water treatment); acetylsalicylic acid; amphetamine; amphetamine derivative; atenolol; barbituric acid derivative; benzodiazepine derivative; beta lactam antibiotic; carbamazepine; chemical compound; chloramphenicol; diclofenac; famotidine; fibric acid derivative; ibuprofen; imidazole derivative; macrolide; metoprolol; metronidazole; naproxen; penicillin derivative; pharmaceutical compound; propranolol; quinolone derivative; ranitidine; sotalol; sulfamethoxazole; sulfathiazole; tetracycline derivative; unclassified drug; unindexed drug; water; activated carbon; adsorption; drug; mineralization; photodegradation; plastic waste; toxicity; water pollution; water treatment; absorption spectroscopy; adsorption; adsorption kinetics; alkylation; bioaccumulation; chemical structure; chlorination; coconut; diffusion; drug degradation; drug industry; effluent; gamma radiation; human; hydrolysis; ionization; ionizing radiation; Lotus; metabolite; mineralization; molecular weight; nonhuman; olive; oxidation; ozonation; photochemistry; photodegradation; photooxidation; powder; precipitation; radiolysis; review; rice husk; sludge treatment; total organic carbon; waste water management; water contamination; water pollution; wood; Prunus persica; Adsorption; Ozonation; Pharmaceuticals; Photodegradation; Radiolysis; Removal; Pharmaceutical Preparations; Waste Disposal, Fluid; Water Pollutants, Chemical; Water Pollution; Water Purification
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