Your search keyword '"Yao, Ziwei"' showing total 5 results

1. The importance of reactive oxygen species on the aqueous phototransformation of sulfonamide antibiotics: kinetics, pathways, and comparisons with direct photolysis.

Author

Ge, Linke, Zhang, Peng, Halsall, Crispin, Li, Yanying, Chen, Chang-Er, Li, Jun, Sun, Helin, and Yao, Ziwei

Subjects

*SULFONAMIDES, *ANTIBIOTICS, *HYDROXYL group, *SULFAMETHAZINE, *SULFADIAZINE

Abstract

Abstract Sulfonamide antibiotics (SAs) are increasingly detected as aquatic contaminants and exist as different dissociated species depending on the pH of the water. Their removal in sunlit surface waters is governed by photochemical transformation. Here we report a detailed examination of the hydroxyl radical (•OH) and singlet oxygen (1O 2) mediated photooxidation of nine SAs: sulfamethoxazole, sulfisoxazole, sulfamethizole, sulfathiazole, sulfamethazine, sulfamerazine, sulfadiazine, sulfachloropyridazine and sulfadimethoxine. Both •OH and 1O 2 oxidation kinetics varied depending on the dominant protonated states of the SA in question (H 2 SAs+, HSAs0 and SAs−) as a function of pH. Based on competition kinetic experiments and matrix deconvolution calculations, HSAs0 or SAs− (pH ∼5–8) were observed to be more highly reactive towards •OH, while SAs− (pH ∼8) react the fastest with 1O 2 for most of the SAs tested. Using the empirically derived rates of reaction for the speciated forms at different pHs, the environmental half-lives were determined using typical 1O 2 and •OH concentrations observed in the environment. This approach suggests that photochemical 1O 2 oxidation contributes more than •OH oxidation and direct photolysis to the overall phototransformation of SAs in sunlit waters. Based on the identification of key photointermediates using tandem mass spectrometry, 1O 2 oxidation generally occurred at the amino moiety on the molecule, whereas •OH reaction experienced multi-site hydroxylation. Both these reactions preserve the basic parent structure of the compounds and raise concerns that the routes of phototransformation give rise to intermediates with similar antimicrobial potency as the parent SAs. We therefore recommend that these phototransformation pathways are included in risk assessments concerning the presence and fate of SAs in waste and surface waters. Graphical abstract Image 1 Highlights • Aquatic photooxidation of sulfonamides (SAs) via reactive oxygen species is important. • The kinetics depend on pH and separate reactivities of H 2 SAs+, HSAs0 and SAs−. • 1O 2 plays a key role in aquatic fate of SAs compared with •OH and direct photolysis • Different primary pathways and multiple intermediates occur for the three reactions. [ABSTRACT FROM AUTHOR]

Published

2019

2. Exploring the aquatic photodegradation of two ionisable fluoroquinolone antibiotics – Gatifloxacin and balofloxacin: Degradation kinetics, photobyproducts and risk to the aquatic environment.

Author

Ge, Linke, Halsall, Crispin, Chen, Chang-Er, Zhang, Peng, Dong, Qianqian, and Yao, Ziwei

Subjects

*FLUOROQUINOLONES, *PHOTODEGRADATION, *WATER temperature, *PHOTOCHEMICAL rearrangement, *PHOTOLYSIS (Chemistry)

Abstract

Fluoroquinolone antibiotics (FQs) are ubiquitous and ionisable in surface waters. Here we investigate gatifloxacin (GAT) and balofloxacin (BAL), two widely used FQs, and determine the photochemical reactivity of their respective dissociation species that arise at different pH to understand the relevance and pathways of phototransformation reactions. Simulated-sunlight experiments and matrix calculations showed that neutral forms (HFQs 0 ) of the two antibiotics had the highest apparent photolytic efficiency and hydroxyl-radical oxidation reactivity. Based on the pH-dependent photochemical reactivities, the solar apparent photodegradation half-lives ( t 1/2 ) in sunlit surface waters ranged from 14.5–169 min and was 1–2 orders of magnitude faster than hydroxyl-radical induced oxidation ( t 1/2 = 20.9–29.8 h). The corresponding pathways were proposed based on the identification of key intermediates using HPLC-ESI-MS/MS. The apparent photodegradation induced defluorination, decarboxylation, and piperazinyl oxidation and rearrangement, whereas hydroxyl-radical oxidation caused hydroxylated defluorination and piperazinyl hydroxylation. The photomodified toxicity of GAT and BAL was examined using an Escherichia coli activity assay. E . coli activity was not affected by BAL, but was significantly affected by the photo-modified solutions of GAT, indicating that primary photo-degradates have a comparable or higher antibacterial activity than the parent GAT. In fresh water and seawater this antibacterial activity remained high for up to 24 h, even after GAT had undergone significant photodegradation (>1 half-life), indicating the potential impact of this chemical on microbial communities in aquatic systems. [ABSTRACT FROM AUTHOR]

Published

2018

3. Photochemical degradation of hydroxy PAHs in ice: Implications for the polar areas.

Author

Ge, Linke, Li, Jun, Na, Guangshui, Chen, Chang-Er, Huo, Cheng, Zhang, Peng, and Yao, Ziwei

Subjects

*PHOTODEGRADATION, *HYDROXY acids, *POLYCYCLIC aromatic hydrocarbons, *PHOTOLYSIS (Chemistry), *DYNAMICS

Abstract

Hydroxyl polycyclic aromatic hydrocarbons (OH-PAHs) are derived from hydroxylated PAHs as contaminants of emerging concern. They are ubiquitous in the aqueous and atmospheric environments and may exist in the polar snow and ice, which urges new insights into their environmental transformation, especially in ice. In present study the simulated-solar ( λ > 290 nm) photodegradation kinetics, products and pathways of four OH-PAHs (9-Hydroxyfluorene, 2-Hydroxyfluorene, 1-Hydroxypyrene and 9-Hydroxyphenanthrene) in ice were investigated, and the corresponding implications for the polar areas were explored. It was found that the kinetics followed the pseudo-first-order kinetics with the photolysis quantum yields ( Φ s ) ranging from 7.48 × 10 −3 (1-Hydroxypyrene) to 4.16 × 10 −2 (2-Hydroxyfluorene). These 4 OH-PAHs were proposed to undergo photoinduced hydroxylation, resulting in multiple hydroxylated intermediates, particularly for 9-Hydroxyfluorene. Extrapolation of the lab data to the real environment is expected to provide a reasonable estimate of OH-PAH photolytic half-lives ( t 1/2,E ) in mid-summer of the polar areas. The estimated t 1/2,E values ranged from 0.08 h for 1-OHPyr in the Arctic to 54.27 h for 9-OHFl in the Antarctic. In consideration of the lower temperature and less microorganisms in polar areas, the photodegradation can be a key factor in determining the fate of OH-PAHs in sunlit surface snow/ice. To the best of our knowledge, this is the first report on the photodegradation of OH-PAHs in polar areas. [ABSTRACT FROM AUTHOR]

Published

2016

4. Aqueous photochemical degradation of hydroxylated PAHs: Kinetics, pathways, and multivariate effects of main water constituents.

Author

Ge, Linke, Na, Guangshui, Chen, Chang-Er, Li, Jun, Ju, Maowei, Wang, Ying, Li, Kai, Zhang, Peng, and Yao, Ziwei

Subjects

*PHOTOCHEMISTRY, *PHOTODEGRADATION, *POLYCYCLIC aromatic hydrocarbons, *HYDROXYLATION kinetics, *MULTIVARIATE analysis, *WATER pollution

Abstract

Hydroxylated polycyclic aromatic hydrocarbons (OH-PAHs) are contaminants of emerging concern in the aquatic environment, so it is of great significance to understand their environmental transformation and toxicity. This study investigated the aqueous photochemical behavior of four OH-PAHs, 9-Hydroxyfluorene (9-OHFL), 2-Hydroxyfluorene, 9-Hydroxyphenanthrene and 1-Hydroxypyrene, under simulated sunlight irradiation ( λ > 290 nm). It was observed that their photodegradation followed the pseudo-first-order kinetics. Based on the determined quantum yields, their calculated solar apparent photodegradation half-lives in surface waters at 45° N latitude ranged from 0.4 min for 9-Hydroxyphenanthrene to 7.5 × 10 3 min for 9-OHFL, indicating that the OH-PAHs would intrinsically photodegrade fast in sunlit surface waters. Furthermore, 9-OHFL as an example was found to undergo direct photolysis, and self-sensitized photooxidation via OH rather than 1 O 2 in pure water. The potential photoreactions involved photoinduced hydroxylation, dehydrogenation and isomerization based on product identification by GC–MS/MS. 9-OHFL photodegraded slower in natural waters than in pure water, which was attributed to the integrative effects of the most photoreactive species, such as Fe(III), NO 3 − , Cl − and humic acid. The photomodified toxicity was further examined using Vibrio fischeri , and it was found that the toxicity of photolyzed 9-OHFL did not decrease significantly ( p > 0.05) either in pure water or in seawater, implying the comparable or higher toxicity of some intermediates. These results are important for assessing the fate and risks of OH-PAHs in surface waters. [ABSTRACT FROM AUTHOR]

Published

2016

5. New insights into the aquatic photochemistry of fluoroquinolone antibiotics: Direct photodegradation, hydroxyl-radical oxidation, and antibacterial activity changes.

Author

Ge, Linke, Na, Guangshui, Zhang, Siyu, Li, Kai, Zhang, Peng, Ren, Honglei, and Yao, Ziwei

Subjects

*PHOTOCHEMISTRY, *FLUOROQUINOLONES, *ANTIBIOTICS, *PHOTODEGRADATION, *HYDROXYL group, *OXIDATION, *ANTIBACTERIAL agents

Abstract

The ubiquity and photoreactivity of fluoroquinolone antibiotics (FQs) in surface waters urge new insights into their aqueous photochemical behavior. This study concerns the photochemistry of 6 FQs: ciprofloxacin, danofloxacin, levofloxacin, sarafloxacin, difloxacin and enrofloxacin. Methods were developed to calculate their solar direct photodegradation half-lives ( t d,E ) and hydroxyl-radical oxidation half-lives ( t OH,E ) in sunlit surface waters. The t d,E values range from 0.56 min to 28.8 min at 45° N latitude, whereas t OH,E ranges from 3.24 h to 33.6 h, suggesting that most FQs tend to undergo fast direct photolysis rather than hydroxyl-radical oxidation in surface waters. However, a case study for levofloxacin and sarafloxacin indicated that the hydroxyl-radical oxidation induced risky photochlorination and resulted in multi-degradation pathways, such as piperazinyl hydroxylation and clearage. Changes in the antibacterial activity of FQs caused by photodegradation in various waters were further examined using Escherichia coli , and it was found that the activity evolution depended on primary photodegradation pathways and products. Primary intermediates with intact FQ nuclei retained significant antibacterial activity. These results are important for assessing the fate and risk of FQs in surface waters. [ABSTRACT FROM AUTHOR]

Published

2015