Removal of Ciprofloxacin from Wastewater by Ultrasound/Electric Field/Sodium Persulfate (US/E/PS)

Ciprofloxacin (CIP), as a common antibiotic used in human clinical and livestock farming, is discharged into natural water bodies and its concentration has increased in the last years. Its stable chemical structure is difficult to remove by conventional techniques. Residual ciprofloxacin in the environment has become an emerging micropollutant that promotes the generation of resistance genes of bacteria and endangers ecosystem balance and human health. Removal of ciprofloxacin from water by the system of ultrasound/electric field/sodium persulfate (US/E/PS) was investigated. Firstly, CIP degradation affects by different oxidation methods, such as ultrasonic oxidation, electro-oxidation, and persulfate oxidation, and their four combined oxidation methods (ultrasound-activated persulfate oxidation, electro-activated persulfate oxidation, ultrasound-enhanced electro-oxidation, and ultrasound-enhanced electro-activated persulfate oxidation), on the target contaminants were compared. Secondly, the influences of parameters on the CIP degradation by an ultrasound-enhanced electro-activation-persulfate reaction system were investigated. Thirdly, the possible free radical species in the ultrasound-enhanced electro-activation-sulfate reaction system were identified and the dominant free radical species in the system were analyzed. Finally, the samples of CIP in the US/E/PS system were tested by liquid mass spectrometry, and the possible intermediate products and degradation path were speculated. The results indicate that the US/E/PS system is of great potential application value in the removal of organic pollution and environmental purification.

Usnic Acid as a Potential Free Radical Scavenger and its Inhibitory Activity Toward SARS-CoV-2 Proteins

The antioxidative activity and free radical scavenging potency of usnic acid towards eight selected free radical species are examined. The thermodynamic parameters in the absence of harmful free radicals are used to predict the most favorable mechanism of antioxidative action. The reaction enthalpies are used to define the most probable mechanism of free radical scavenging in the presence of free radical species. The obtained results indicate that the favorable mechanism of antiradical action is dependent both on the polarity of solvents and the nature of free radical species. From the achieved results, it is clear that Sequential Proton Loss Electron Transfer (SPLET) is the most probable for antioxidative action in water and methanol, while competition between SPLET and Hydrogen Atom Transfer (HAT) is presented in benzene. The free radical scavenging of eight free radical species under investigation is possible, and the most believable mechanism of action is SPLET, in all three investigated solvents. Since usnic acid exhibits significant radical scavenging activity that affects the maintenance of redox hemostasis, its inhibitory potency toward COVID-19 targeted proteins molecular docking study is performed. The obtained results indicate that usnic acid has the potential to inhibit the functional proteins of SARS-CoV-2.

Stimulus-responsive reversible thermochromism and exciplex emission of a Zn(ii) complex and selective sensing of NH3 gas

A Zn(ii) complex exhibits reversible thermochromism and emission switch, and the resulting free radical species responds fast and selectively toward NH3.