Abstract
One of the most serious effects of micropollutants in the environment is biological magnification, which causes adverse effects on humans and the ecosystem. Among all of the micro-pollutants, antibiotics are commonly present in the aquatic environment due to their wide use in treating or preventing various diseases and infections for humans, plants, and animals. Therefore, an aluminum-based electrocoagulation unit has been used in this study to remove cephalexin antibiotics, as a model of the antibiotics, from water. Computational and statistical models were used to optimize the effects of key parameters on the electrochemical removal of cephalexin, including the initial cephalexin concentration (15–55 mg/L), initial pH (3–11), electrolysis time (20–40 min), and electrode type (insulated and non-insulated). The response surface methodology-central composite design (RSM-CCD) was used to investigate the dependency of the studied variables, while the artificial neural network (ANN) and adaptive neuro-fuzzy inference system (ANFIS) methods were applied for predicting the experimental training data. The results showed that the best experimental and predicted removals of cephalexin (CEX) were 88.21% and 93.87%, respectively, which were obtained at a pH of 6.14 and electrolysis time of 34.26 min. The results also showed that the ANFIS model predicts and interprets the experimental results better than the ANN and RSM-CCD models. Sensitivity analysis using the Garson method showed the comparative significance of the variables as follows: pH (30%) > electrode type (27%) > initial CEX concentration (24%) > electrolysis time (19%).
Highlights
Diverse micro-pollutants entered the environment by disposing improperly of various ‘industries’ wastewater, including textiles, plastics, paper, pharmaceutical and health care products, detergents, etc
This study aims to optimize the electrocoagulation process for CEX removal by optimizing the effective parameters using the response surface method (RSM) with the central composite design (CCD)
The outcomes of this study demonstrated that the RSM model is excellent in explaining the interaction of the parameters
Summary
Diverse micro-pollutants entered the environment by disposing improperly of various ‘industries’ wastewater, including textiles, plastics, paper, pharmaceutical and health care products, detergents, etc. Among all of these micro-pollutants, pharmaceutical substances have been recognized as an essential issue due to their widespread usage for humans, animals, and plants and their high potential to reach water sources. The prolonged remaining of some pharmaceutical substances in the environment cause bacterial resistance because of their non-biodegradability characteristics This can be transmitted to humans and can manifest in diseases. Antibiotics are among the most widely used pharmaceuticals that destroy bacteria or reduce their growth rate [1]. Cephalexin (CEX) is one of the cephalosporin antibiotics with antimicrobial properties, and it is used to treat a variety of diseases caused by gram-negative and gram-positive organisms, including various infectious diseases [3]
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