Introduction to Antibiotic Pollutants

What is/are Antibiotic Pollutants?

Antibiotic Pollutants - Herein, the synergistic effect of adsorption and peroxydisulfate (PS) activation on kinetics and mechanism of removing single and binary antibiotic pollutants, sulfamethoxazole (SMX) and ibuprofen (IBP), from water by biomass-derived N-doped porous carbon was investigated. ^[1] Antibiotic pollutants are a serious and growing threat to human health and the environment that efficient measures must be taken to eliminate them. ^[2] This work contributes a highly efficient and environmentally friendly catalyst and provides a clear mechanistic explanation for the removal of antibiotic pollutants in environmental remediation. ^[3] This study is a comprehensive investigation of emerging antibiotic pollutants and its resistance in bacteria associated with factors integrons-integrase responsible for its dissemination. ^[4] These antibiotic pollutants can increase rates of mutation and lateral transfer events, and continue to exert selection pressure even at sub-inhibitory concentrations. ^[5] Antibiotic pollutants discharged from pharmaceutical industries are often present in the aquaticenvironment due to ineffective treatment of pharmaceutical wastewater and are hazardous tohuman and aquatic life. ^[6] Advanced oxidation processes involving the visible-light-assisted peroxymonosulfate (PMS) are emerging as promising approaches for treating antibiotic pollutants. ^[7] Antibiotic pollutants discharged from pharmaceutical industries are often present in the aquatic environment due to ineffective treatment of pharmaceutical wastewater and are hazardous to human and aquatic life. ^[8] The WRG composites exhibited excellent photocatalytic activity for decomposing organic dye Rhodamine B (RhB) & antibiotic pollutants like Ciprofloxacin (CIP) under visible light irradiation. ^[9] These excellent characteristics strongly suggest that the prepared m-BiVO4 may serve as better photocatalyst for the removal of antibiotic pollutants from wastewater. ^[10] Furthermore, ·OH radicals were confirmed as the dominant reactive species roles for the degradation of antibiotic pollutants through EPR and ·OH−trapping fluorescence spectral tests, and a plausible catalytic degradation mechanism was proposed. ^[11] Conclusions These results provide a new method for bio-degrading of penicillin or other antibiotic pollutants using photoaccelerating biocatalysts with greater efficiency and more environmentally friendly conditions. ^[12] It provided a scientific theoretical basis for systematically evaluating the biological toxicity of antibiotic pollutants. ^[13] Considering the high environmental risk, the remediation of antibiotic pollutants attracted numerous attentions. ^[14] Antibiotic pollutants have posed a huge threat to the ecological environment and human health. ^[15] To improve the adsorption speed and capacity of adsorbents is essential for the removal of antibiotic pollutants in water. ^[16] Radical trapping control experiments and photocatalytic degradation experiments confirmed that the WOQD/CN nanocomposites display high activities in the photo-degradation of ciprofloxacin (CIP) and tetracycline (TC) in antibiotic pollutants in the presence of hydroxyl(·OH) and superoxide radicals(·O2−),and the photo-degradation activities of the optimized WOQD(3)–CN sample are seven times higher than those of CN under Xe light irradiation. ^[17] Electrocatalytic hydrodechlorination is deemed as a promising environmental remediation technology for fast and effective detoxification of halogenated antibiotic pollutants. ^[18] This finding indicates that GH may be an efficient adsorbent for antibiotic pollutants removal in water purification. ^[19] This photocatalytic process is an excellent practical alternative for the removal of MNZ and similar antibiotic pollutants from various wastewaters. ^[20] Hence, the effective removal of antibiotic pollutants has become a hot topic in environmental research. ^[21] Antibiotic pollutants have been constantly detected in the water environment. ^[22] The optimized 60% g-C3N4-agar sample exhibited preferable simulated-sunlight photocatalytic degradation efficiency towards the dye and antibiotic pollutants, as well as excellent recycle performance. ^[23] This work provides a simple method to design the core/shell structure photocatalysts with excellent photocatalytic performance and adsorption capability for removal antibiotic pollutants. ^[24] Antibiotic concentrations in surface waters far exceed the pollution limit due to the abuse of pharmaceuticals, resulting in an urgent need for an approach with potential efficiency, sustainability and eco-friendliness to remove antibiotic pollutants. ^[25] These findings not only provided an efficient and economic zero-valent iron technique for eliminating the antibiotic pollutants in water, but also made important contributions to better understand the removal mechanism. ^[26] Photo-bioelectrochemical fuel cell (PBFC) represents a promising technology for enhancing removal of antibiotic pollutants while simultaneously sustainable transformation of organic wastes and solar energy into electricity. ^[27] These results demonstrate our MMIP networks, which offered high binding capacity and selectivity as well as recyclability, can be used for both removal and monitoring hazardous antibiotic pollutants in different sources/samples and food products. ^[28] These results demonstrate that this planar waveguide immunosensor is capable of simultaneous screening and quantification of multi-class antibiotic pollutants and is expected to be applied for practical environmental monitoring. ^[29] Semiconductor heterostructures have attracted extensive interest in photocatalytic degradation of antibiotic pollutants. ^[30] The proposed 3D printed chitosan scaffolds may be used as reusable substrate for the TiO2 photocatalytic degradation of antibiotic pollutants in wastewater. ^[31] The development of inorganic membranous catalysts with both large mesopores and superb flexibility is extremely favorable for the enhancement of their catalytic oxidation activity for the degradation of antibiotic pollutants in wastewater via sulfate radical-based advanced oxidation processes; however, there still exists a huge challenge for inorganic materials to simultaneously realize these two properties. ^[32] We believe that the developed CoO/g-C3N4 could be a potential adsorptive photocatalyst for antibiotic pollutants removal from wastewater. ^[33] Herein, we prepared ternary AgBr/Ag3PO4@natural hematite (AgBr/Ag3PO4@NH) heterojunction composite via a simple route for the photocatalytic degradation of antibiotic pollutants. ^[34] These results indicate that GH may be an efficient adsorbent for antibiotic pollutants removal in water purification. ^[35] Utilizing highly efficient and stable photocatalysts to treat residual antibiotic pollutants in water is of great significance. ^[36]

antibiotic pollutants removal

This finding indicates that GH may be an efficient adsorbent for antibiotic pollutants removal in water purification. ^[1] We believe that the developed CoO/g-C3N4 could be a potential adsorptive photocatalyst for antibiotic pollutants removal from wastewater. ^[2] These results indicate that GH may be an efficient adsorbent for antibiotic pollutants removal in water purification. ^[3]

antibiotic pollutants discharged

Antibiotic pollutants discharged from pharmaceutical industries are often present in the aquaticenvironment due to ineffective treatment of pharmaceutical wastewater and are hazardous tohuman and aquatic life. ^[1] Antibiotic pollutants discharged from pharmaceutical industries are often present in the aquatic environment due to ineffective treatment of pharmaceutical wastewater and are hazardous to human and aquatic life. ^[2]