Abstract
Bacterial antibiotic resistance has been deemed one of the largest modern threats to human health. One of the root causes of antibiotic resistance is the inability of traditional wastewater management techniques, such as filtration and disinfection, to completely eliminate residual antibiotics from domestic and industrial effluents. In this study, we examine the ability of UiO-66; a metal-organic framework (MOF); in removing the antibiotic Doxycycline from aqueous environments. This study’s findings suggest that UiO-66 was able to remove nearly 90% of the initial Doxycycline concentration. To correlate the isothermal data, Langmuir and Freundlich models were used. It was determined that the Langmuir model was best suited. Pseudo-first and -second order models were examined for kinetic data, where the pseudo-second order model was best suited—consistent with the maximum theoretical adsorption capacity found by the Langumir model. Thermodynamic analysis was also examined by studying UiO-66 adsorption under different temperatures. Mechanisms of adsorption were also analyzed through measuring adsorption at varying pH levels, thermogravimetric analysis (TGA), Infrared spectroscopy (IR) and Brunauer–Emmet–Teller (BET). This study also explores the possibility of recycling MOFs through exposure to gamma radiation, heat, and heating under low pressure, in order for UiO-66 to be used in multiple, consecutive cycles of Doxycycline removal.
Highlights
Antibiotics are widely used in human and veterinary pharmaceuticals, agriculture and farming to fight diseases caused by bacteria
The main goal of the study is to demonstrate that metal-organic framework (MOF), UiO-66, achieve high
The study proves that UiO-66 is able to remove up to 90% of the initial concentration of Doxycycline in an aqueous environment under optimized conditions
Summary
Antibiotics are widely used in human and veterinary pharmaceuticals, agriculture and farming to fight diseases caused by bacteria. The administered doses are not completely consumed and about 30–90% of them are released into the environment in their active forms due to runoff effluents. The over-abundant use and improper disposal of antibiotics cause bacteria to develop antibiotic resistance that hinders the ability of antibiotics to effectively cure bacterial diseases. Organization (WHO) classified antibiotic-resistant bacteria as one of the more prominent threats to public health, food security and economic development [1,2,3,4]. Antibiotics are considered persistent contaminants due to their incessant presence in the ecosystem. Residual antibiotics are continuously detected worldwide in effluents of wastewater [5,6]
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