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New insights into the environmental photochemistry of common-use antibiotics in ice and in water: A comparison of kinetics and influencing factors

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New insights into the environmental photochemistry of common-use antibiotics in ice and in water: A comparison of kinetics and influencing factors. / Ge, Linke; Wang, Siyuan; Halsall, Crispin et al.
In: Emerging Contaminants, Vol. 10, No. 4, 100382, 31.12.2024.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Ge, L, Wang, S, Halsall, C, Li, X, Bai, D, Cao, S & Zhang, P 2024, 'New insights into the environmental photochemistry of common-use antibiotics in ice and in water: A comparison of kinetics and influencing factors', Emerging Contaminants, vol. 10, no. 4, 100382. https://doi.org/10.1016/j.emcon.2024.100382

APA

Ge, L., Wang, S., Halsall, C., Li, X., Bai, D., Cao, S., & Zhang, P. (2024). New insights into the environmental photochemistry of common-use antibiotics in ice and in water: A comparison of kinetics and influencing factors. Emerging Contaminants, 10(4), Article 100382. https://doi.org/10.1016/j.emcon.2024.100382

Vancouver

Ge L, Wang S, Halsall C, Li X, Bai D, Cao S et al. New insights into the environmental photochemistry of common-use antibiotics in ice and in water: A comparison of kinetics and influencing factors. Emerging Contaminants. 2024 Dec 31;10(4):100382. Epub 2024 Jun 26. doi: 10.1016/j.emcon.2024.100382

Author

Ge, Linke ; Wang, Siyuan ; Halsall, Crispin et al. / New insights into the environmental photochemistry of common-use antibiotics in ice and in water : A comparison of kinetics and influencing factors. In: Emerging Contaminants. 2024 ; Vol. 10, No. 4.

Bibtex

@article{f7fee1b492cb4786baa4eae95681e34a,
title = "New insights into the environmental photochemistry of common-use antibiotics in ice and in water: A comparison of kinetics and influencing factors",
abstract = "The photochemistry of organic contaminants present in ice is receiving growing attention, given the wide presence of ice during winter in temperate regions as well as Polar and mountain environments. Differences between ice photochemistry and aqueous photochemistry, however, influence the quantitative fate and transformation of organic chemicals present in freshwater, marine and ice-cap environments and these differences need to be explored. Here we comparatively studied the ice and aqueous photochemistry of three antibiotics [levofloxacin (LVX), sulfamerazine (SM), and chlortetracycline (CTC)] under the same simulated sunlight (λ > 290 nm). Their photodegradation in ice/water followed pseudo-first-order kinetics, whereby the photolytic rates of LVX in ice and water were found to be similar, SM photodegraded faster in ice, while CTC underwent slower photodegradation in ice. Whether individual antibiotics underwent faster photodegradation in ice or not depends on the specific concentration effect and cage effect coexisting in the ice compartment. In most cases, the fastest photodegradation occurred in freshwater ice or in fresh water, and the slowest photolysis occurred in pure-water ice or in pure water. This can be attributed to the effects of key photochemical reactive constituents of Cl-, HA, NO3 - and Fe(III), that exist in natural waters. These constituents at certain levels showed significant effects (P < 0.1) on the photolysis, not only in ice but also in water. However, these individual constituents at a given concentration, serve to either enhance or suppress the photoreaction, depending on the specific antibiotic and the matrix type (e.g., ice or aqueous solution). Furthermore, extrapolation of the laboratory findings to cold environments indicate that pharmaceuticals present in ice will have a different photofate compared to water. These results are of particular relevance for those regions that experience seasonal ice cover in fresh water and coastal marine systems.",
author = "Linke Ge and Siyuan Wang and Crispin Halsall and Xuanyan Li and Dongxiao Bai and Shengkai Cao and Peng Zhang",
year = "2024",
month = dec,
day = "31",
doi = "10.1016/j.emcon.2024.100382",
language = "English",
volume = "10",
journal = "Emerging Contaminants",
issn = "2405-6650",
publisher = "KeAi Communications Co.",
number = "4",

}

RIS

TY - JOUR

T1 - New insights into the environmental photochemistry of common-use antibiotics in ice and in water

T2 - A comparison of kinetics and influencing factors

AU - Ge, Linke

AU - Wang, Siyuan

AU - Halsall, Crispin

AU - Li, Xuanyan

AU - Bai, Dongxiao

AU - Cao, Shengkai

AU - Zhang, Peng

PY - 2024/12/31

Y1 - 2024/12/31

N2 - The photochemistry of organic contaminants present in ice is receiving growing attention, given the wide presence of ice during winter in temperate regions as well as Polar and mountain environments. Differences between ice photochemistry and aqueous photochemistry, however, influence the quantitative fate and transformation of organic chemicals present in freshwater, marine and ice-cap environments and these differences need to be explored. Here we comparatively studied the ice and aqueous photochemistry of three antibiotics [levofloxacin (LVX), sulfamerazine (SM), and chlortetracycline (CTC)] under the same simulated sunlight (λ > 290 nm). Their photodegradation in ice/water followed pseudo-first-order kinetics, whereby the photolytic rates of LVX in ice and water were found to be similar, SM photodegraded faster in ice, while CTC underwent slower photodegradation in ice. Whether individual antibiotics underwent faster photodegradation in ice or not depends on the specific concentration effect and cage effect coexisting in the ice compartment. In most cases, the fastest photodegradation occurred in freshwater ice or in fresh water, and the slowest photolysis occurred in pure-water ice or in pure water. This can be attributed to the effects of key photochemical reactive constituents of Cl-, HA, NO3 - and Fe(III), that exist in natural waters. These constituents at certain levels showed significant effects (P < 0.1) on the photolysis, not only in ice but also in water. However, these individual constituents at a given concentration, serve to either enhance or suppress the photoreaction, depending on the specific antibiotic and the matrix type (e.g., ice or aqueous solution). Furthermore, extrapolation of the laboratory findings to cold environments indicate that pharmaceuticals present in ice will have a different photofate compared to water. These results are of particular relevance for those regions that experience seasonal ice cover in fresh water and coastal marine systems.

AB - The photochemistry of organic contaminants present in ice is receiving growing attention, given the wide presence of ice during winter in temperate regions as well as Polar and mountain environments. Differences between ice photochemistry and aqueous photochemistry, however, influence the quantitative fate and transformation of organic chemicals present in freshwater, marine and ice-cap environments and these differences need to be explored. Here we comparatively studied the ice and aqueous photochemistry of three antibiotics [levofloxacin (LVX), sulfamerazine (SM), and chlortetracycline (CTC)] under the same simulated sunlight (λ > 290 nm). Their photodegradation in ice/water followed pseudo-first-order kinetics, whereby the photolytic rates of LVX in ice and water were found to be similar, SM photodegraded faster in ice, while CTC underwent slower photodegradation in ice. Whether individual antibiotics underwent faster photodegradation in ice or not depends on the specific concentration effect and cage effect coexisting in the ice compartment. In most cases, the fastest photodegradation occurred in freshwater ice or in fresh water, and the slowest photolysis occurred in pure-water ice or in pure water. This can be attributed to the effects of key photochemical reactive constituents of Cl-, HA, NO3 - and Fe(III), that exist in natural waters. These constituents at certain levels showed significant effects (P < 0.1) on the photolysis, not only in ice but also in water. However, these individual constituents at a given concentration, serve to either enhance or suppress the photoreaction, depending on the specific antibiotic and the matrix type (e.g., ice or aqueous solution). Furthermore, extrapolation of the laboratory findings to cold environments indicate that pharmaceuticals present in ice will have a different photofate compared to water. These results are of particular relevance for those regions that experience seasonal ice cover in fresh water and coastal marine systems.

U2 - 10.1016/j.emcon.2024.100382

DO - 10.1016/j.emcon.2024.100382

M3 - Journal article

VL - 10

JO - Emerging Contaminants

JF - Emerging Contaminants

SN - 2405-6650

IS - 4

M1 - 100382

ER -