Abstract
The aim of our study was to assess the possibility of using the photocatalytic process conducted in the presence of TiO2 to obtain new stable derivatives of antibacterial drugs. The possibility of introducing hydroxyl, chlorine, or bromide groups into antibiotics molecules was investigated. The experiments were conducted in aqueous solutions in the presence of TiO2-P25 as a photocatalyst, Cl− and Br− ions, and antibiotics belonging to eight different chemical classes. All experiments were initiated by UVa radiation. The kinetics of photocatalytic reactions and their quantum yield were determined, and the stable products were identified. All of the antibiotics used in the experiments underwent a photocatalytic transformation, and the quantum yields were in the range from 0.63 to 22.3%. The presence of Br− or FeCl3 significantly increased the efficiency of the photocatalytic process performed in the presence of TiO2, although Br− ion also acted as an inhibitor. Potentially biologically active chlorine derivatives from Trimethoprim, Metronidazole, Chloramphenicol, and bromine derivatives from Trimethoprim, Amoxicillin were obtained under experimental conditions. The potentially inactive halogen derivatives of Sulfamethoxazole and hydroxyl derivatives described in the literature were also identified.
Highlights
Rapid development of medicine and the resultant growth of demand for new antibiotics are the natural consequences of the civilization progress
The removal or substantial modification of the side chain from in CAM molecule caused a similar effect [38]. These results indicate that the derivatives of SMX and CAM obtained by the photocatalytic process were most likely biologically inactive
The heterogeneous photocatalytic process conducted in an acidic environment in the presence of TiO2 -P25, as well as chloride and bromide ions, allowed the formation of stable chlorine derivatives of TMP, MTZ, and CAM and bromine derivatives of TMP, SMX, and AMX
Summary
Rapid development of medicine and the resultant growth of demand for new antibiotics are the natural consequences of the civilization progress Demand for such substances promotes their widespread use in animal husbandry and the simultaneous rapid creation of resistance in the microorganisms, against which they are used [1,2]. The above stimulates an intensive search for new substances with the desired profile of biological activity. For this purpose, substances of natural origin are isolated and researched, new, and previously undescribed chemical compounds, as well as new derivatives based on already existing drugs, are synthesized [2,3].
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