Structural dependent degradation of histamine H2-receptor antagonists by UV/NH2Cl: Reactive species contribution and the role of carbonate ions on ?NO generation

Histamine H2-receptor antagonists (HRAs) are a group of widely used gastrointestinal drugs that have been frequently detected in natural environments. UV/chloramine (NH2Cl) is a widely used disinfection process in water treatment, while the performance of HRAs degradation by UV/NH2Cl is still unclear. In this work, the degradation kinetics, mechanism and disinfection byproducts formation of HRAs by UV/NH2Cl were studied. The degradation of HRAs, including ranitidine (RNTD), nizatidine (NZTD), roxatidine (RXTD), cimetidine (CMTD) and famotidine (FMTD) was fast in the UV/NH2Cl process, and center dot OH, Cl center dot and center dot NO contributed to their degradation. CMTD had the highest rate constants with center dot OH, Cl center dot and center dot NO. RXTD, NZTD and FMTD were more reactive with center dot OH, while RNTD was more selective towards Cl center dot. The contribution of center dot OH, Cl center dot and reactive nitrogen species to HRAs degradation in water matrices was further quantified by kinetic modeling. Interestingly, carbonate species were found to promote the yield of center dot NO. Further investigation through sensitivity analysis of the modeling re-actions concluded the sensitive reactions for center dot NO promotion. The structure-activity assessment domenstrated that the reactivity of thioether sulfur, CMTD-C3 and RXTD-N48 and piperidine rings resulted in the difference of degradation rates. Hydroxylation, nitrosation, chlorine substitution and oxygen atom transfer were the primary pathways for HRAs degradation. The formation of NDMA might be a prevalent problem along HRAs' degradation in the UV/NH2Cl process, and the formation potential of NDMA is dependent on the types of amine groups in HRAs. This work provides an effective strategy to eliminate HRAs, revealed the NDMA formation potential in HRAs, and emphasized the role of carbonate species in center dot NO generation.