Repeated photocatalytic inactivation of E. coli by UV + Ni foam@TiO2: Performance and photocatalyst deactivation

[Display omitted] •Fresh UV/NF@TiO2 can effectively inactivate E. coli.•Obvious photocatalyst deactivation occurred during repeated bacterial inactivation.•The OH and O2− were primary ROS for E. coli inactivation.•E. coli released DNA, LPS and proteins were key species for photocatalyst deactivation...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2023-07, Vol.468, p.143680, Article 143680
Main Authors: Wang, Miao, Xu, Zhe, Qi, Zhenlian, Cai, Yiwei, Li, Guiying, Choi, Wonyong, An, Taicheng
Format: Article
Language:English
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Bacterial inactivation
Biomolecule
Photocatalysis
Photocatalyst deactivation
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cited_by cdi_FETCH-LOGICAL-c212t-39ee8746109b23925039531f605824cca5a85016a35b65ffa7d923a31dd381993
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container_title Chemical engineering journal (Lausanne, Switzerland : 1996)
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creator Wang, Miao
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Choi, Wonyong
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description [Display omitted] •Fresh UV/NF@TiO2 can effectively inactivate E. coli.•Obvious photocatalyst deactivation occurred during repeated bacterial inactivation.•The OH and O2− were primary ROS for E. coli inactivation.•E. coli released DNA, LPS and proteins were key species for photocatalyst deactivation. Photocatalysis (PC) has exhibited a bright prospect in the inactivation of waterborne pathogens. However, the deactivation of photocatalysts during PC bacterial inactivation has not been systematically studied so far. In this study, we investigated the performance of a PC system nickel foam-loaded TiO2 (NF@TiO2) during a 70-cycle of bacterial inactivation focusing on the photocatalyst deactivation mechanism, where E. coli DH5α was employed as the model photocatalyst and bacteria, respectively. Our results showed that the UV + NF@TiO2 process could effectively inactivate E. coli. Approximately 1 × 108 cfu mL−1 of E. coli could be completely inactivated within 4 h using a fresh NF@TiO2 photocatalyst. However, the inactivation efficiency substantially declined with the increase in cycle number, and NF@TiO2 was almost poisoned after 70 cycles. Through the characterization of scanning electron microscope, atomic force microscope, UV–vis diffuse reflectance spectroscopy, and electron paramagnetic resonance, as well as other experiments, a deactivation mechanism of NF@TiO2 was proposed: The PC-generated reactive oxygen species (ROS) fragmented E. coli to excrete a myriad of biomolecules that subsequently adhered to the surface of NF@TiO2. This accelerated the deterioration of PC inactivation by impeding light harvest and reactive species utilization. Moreover, biomolecules were found to play a pivotal role in photocatalyst deactivation, following the order of lipopolysaccharide ≈ DNA > proteins. This study could provide a fundamental view of the deactivation of photocatalysts during bacterial inactivation.
doi_str_mv 10.1016/j.cej.2023.143680
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Photocatalysis (PC) has exhibited a bright prospect in the inactivation of waterborne pathogens. However, the deactivation of photocatalysts during PC bacterial inactivation has not been systematically studied so far. In this study, we investigated the performance of a PC system nickel foam-loaded TiO2 (NF@TiO2) during a 70-cycle of bacterial inactivation focusing on the photocatalyst deactivation mechanism, where E. coli DH5α was employed as the model photocatalyst and bacteria, respectively. Our results showed that the UV + NF@TiO2 process could effectively inactivate E. coli. Approximately 1 × 108 cfu mL−1 of E. coli could be completely inactivated within 4 h using a fresh NF@TiO2 photocatalyst. However, the inactivation efficiency substantially declined with the increase in cycle number, and NF@TiO2 was almost poisoned after 70 cycles. Through the characterization of scanning electron microscope, atomic force microscope, UV–vis diffuse reflectance spectroscopy, and electron paramagnetic resonance, as well as other experiments, a deactivation mechanism of NF@TiO2 was proposed: The PC-generated reactive oxygen species (ROS) fragmented E. coli to excrete a myriad of biomolecules that subsequently adhered to the surface of NF@TiO2. This accelerated the deterioration of PC inactivation by impeding light harvest and reactive species utilization. Moreover, biomolecules were found to play a pivotal role in photocatalyst deactivation, following the order of lipopolysaccharide ≈ DNA &gt; proteins. 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Photocatalysis (PC) has exhibited a bright prospect in the inactivation of waterborne pathogens. However, the deactivation of photocatalysts during PC bacterial inactivation has not been systematically studied so far. In this study, we investigated the performance of a PC system nickel foam-loaded TiO2 (NF@TiO2) during a 70-cycle of bacterial inactivation focusing on the photocatalyst deactivation mechanism, where E. coli DH5α was employed as the model photocatalyst and bacteria, respectively. Our results showed that the UV + NF@TiO2 process could effectively inactivate E. coli. Approximately 1 × 108 cfu mL−1 of E. coli could be completely inactivated within 4 h using a fresh NF@TiO2 photocatalyst. However, the inactivation efficiency substantially declined with the increase in cycle number, and NF@TiO2 was almost poisoned after 70 cycles. 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Through the characterization of scanning electron microscope, atomic force microscope, UV–vis diffuse reflectance spectroscopy, and electron paramagnetic resonance, as well as other experiments, a deactivation mechanism of NF@TiO2 was proposed: The PC-generated reactive oxygen species (ROS) fragmented E. coli to excrete a myriad of biomolecules that subsequently adhered to the surface of NF@TiO2. This accelerated the deterioration of PC inactivation by impeding light harvest and reactive species utilization. Moreover, biomolecules were found to play a pivotal role in photocatalyst deactivation, following the order of lipopolysaccharide ≈ DNA &gt; proteins. 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subjects Bacterial inactivation
Biomolecule
Photocatalysis
Photocatalyst deactivation
title Repeated photocatalytic inactivation of E. coli by UV + Ni foam@TiO2: Performance and photocatalyst deactivation
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