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Occurrence, dissipation kinetics and environmental risk assessment of antibiotics and their metabolites in agricultural soils

Carmen Mejías, Laura Martín-Pozo, Juan Luís Santos, Julia Martı́n, Irene Aparicio, Esteban Alonso

2024Journal of Hazardous Materials24 citationsDOIOpen Access PDF

Abstract

Antibiotics are among the emerging contaminants of greatest concern to the scientific community. However, the occurrence and behaviour of their metabolites in soils have been scarcely studied. To address this research gap, this study investigates the occurrence, sorption, dissipation kinetics, and environmental risk of highly important antibiotics (sulfamethazine, sulfadiazine, sulfamethoxazole, trimethoprim) and their main metabolites in Mediterranean agricultural soils. Batch experiments were conducted under natural conditions for 120 days. Five different dissipation kinetics models were applied to elucidate antibiotics degradation. The sorption isotherms were evaluated by three different models. Most of the antibiotics and metabolites tested showed a good fit with the Linear Isotherm model (R 2 >0.96) and biphasic dissipation kinetic models (R 2 >0.90). The dissipation and the endpoints values (DT 50 and DT 90 ) depended on the soil type properties. A Lixisol soil demonstrated reduced degradation of the investigated compounds. Trimethoprim showed the highest persistence, followed by sulfamethazine, sulfamethoxazole, and sulfadiazine. Parent compounds exhibited lower degradation rates than their metabolites. Remaining antibiotic concentrations were found to be below the predicted no-effect concentration in soil, suggesting that they may not pose a risk to terrestrial biota. This study provides valuable insights into the behaviour of these antibiotics and their metabolites in soil. Graphical abstract • Experimental data revealed biphasic kinetics for most compounds • Metabolites dissipated more quickly than their parent compounds • Trimethoprim was more persistent in the soils than sulfonamides • DT 50 values were from 0.09 to > 120 days • Environmental risk assessment suggested no risk to terrestrial organisms

Topics & Concepts

Soil waterEnvironmental chemistryKineticsAgricultureEnvironmental risk assessmentEnvironmental scienceAntibioticsChemistryRisk assessmentSoil scienceBiologyEcologyBiochemistryComputer sciencePhysicsQuantum mechanicsComputer securityPharmaceutical and Antibiotic Environmental ImpactsPesticide Residue Analysis and SafetyPesticide and Herbicide Environmental Studies