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Removal efficiencies of natural and synthetic progesterones in hospital wastewater treated by different disinfection processes
Jinhui Liang, Yuchen Luo, Benhang Li, Shiqi Liu, Liansheng Yang, Peng Gao, Li Feng, Yongze Liu, Ziwen Du, Liqiu Zhang
PDF(3499 KB)
PDF(3499 KB)
Removal efficiencies of natural and synthetic progesterones in hospital wastewater treated by different disinfection processes
● The concentrations of 61 progesterones in HWW, PFTE, SBTE were evaluated.
● The removal efficiencies of progesterones by PFT and SBT were identified.
● Compared the removal efficiencies of progeste rones in five disinfection processes.
Progesterones are ubiquitous in hospital wastewater (HWW) with concentrations much higher than those of estrogens and androgens. To ensure that these water systems are safe to use, disinfection is crucial during HWW treatment by providing “front line” defense against biological contaminations. Here, five disinfection processes, namely, chlorine (Cl2), chlorine dioxide (ClO2), ozone (O3), ultraviolet (UV)), and UV/chlorine (UV/Cl2), were selected to investigate their removal efficiencies for progesterones in primary filtration and secondary biological treatment effluents. There were 61 natural and synthetic progesterones detected in HWW, with the natural progesterones being the main components with a concentration of 845.51 ng/L and contributing to 75.08% of the total progesterones. The primary filtration treatment presented insignificant removal effects on the progesterones, while the secondary biological treatment significantly reduced the progesterone content by biodegradation. The order of removal efficiencies of total progesterones by different disinfection processes was UV/Cl2 > Cl 2 > O 3 > ClO 2 > UV. UV/Cl 2 showed the highest removal efficiency against progesterones mainly due to the activation of Cl2 by ultraviolet (UV) photolysis, which helps open the heterocyclic, aromatic, and phenolic rings, thus accelerating progesterone degradation. In addition, the removal efficiencies of natural progesterones in the five disinfection processes were higher than those of synthetic progesterones (progesterone derivatives, 19-nortestosterone derivatives, and 17α-hydroxyprogesterone derivatives).
Progesterones / Hospital wastewater / Primary filtration treatment effluent / Secondary biological treatment effluent / Disinfection process
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