地表水中典型磺胺类抗生素的自然衰减
Natural attenuation behavior of typical sulfonamides in the surface water
-
摘要: 近年来,磺胺类抗生素因大量使用,在河流等地表水中广泛检出,其环境行为及生态危害,成为备受关注的环境问题.本文以10种常见磺胺类抗生素为研究对象,通过微宇宙实验,模拟其在河流表层水中的自然衰减规律,同时模拟直接光降解、间接光降解、水解、细菌降解和微生物降解等多种条件,以阐明不同环境因素对磺胺类抗生素自然衰减的作用机制.结果显示,10种磺胺类抗生素在168 h内的自然衰减率可达55%—100%,半衰期为14.7—115.5 h,表明磺胺类抗生素在进入河流等地表水后可发生自然衰减.结构方程模型分析表明,直接光降解及间接光降解是磺胺类抗生素自然衰减的主要途径,而水解和微生物降解的作用不大.采用高分辨率质谱,共检出7种降解产物,推测磺胺类抗生素的转化路径主要包括N—S键断裂及羟基化作用.ECOSAR毒性分析结果表明,转化产物毒性多低于母体抗生素,但仍可能存在潜在的环境风险,需进一步深入研究.Abstract: Due to its extensive usage and frequent detection in the surface water, the environmental behavior and ecological toxicity of sulfonamides have received increasing concerns. This study investigated the attenuation pattern and factors influencing the natural attenuation of 10 typical sulfonamides by simulating hydrolysis, direct and indirect photolysis, bacterial degradation and microbial degradation in microcosm. The results showed that 55% to 100% of sulfonamides could be removed under natural attenuation with the half-life from 14.7 h to 115.5 h, which indicated the sulfonamides can be naturally attenuated after entering the river surface water. The structural equation modeling approach demonstrated that the direct and indirect photolysis were the major factors contributing to the natural attenuation of sulfonamides, while hydrolysis, bacterial degradation, and microbial degradation were not effective. Seven transformation products were identified by high resolution mass spectrometry, which suggested that the sulfonamides attenuation mainly occurred through N-S cleavage and hydroxylation. The toxicity evaluation based on ECOSAR showed that the toxicity of the transformation products was lower than the parent compounds. However, the transformation products might still have potential environmental risks and further studies should be conducted.
-
-
[1] QIAO M, YING G G, SINGER A C, et al. Review of antibiotic resistance in China and its environment[J]. Environment International, 2018, 110:160-172. [2] NYGAARD K, LUNESTAD B T, HEKTOEN H, et al. Resistance to oxytetracycline, oxolinic acid and furazolidone in bacteria from marine sediments[J]. Aquaculture, 1992, 104(1):31-36. [3] GOTHWAL R, SHASHIDHAR T. Antibiotic pollution in the environment:A review[J]. Clean-Soil, Air, Water, 2015, 43(4):479-489. [4] LIU X, STEELE J C, MENG X Z. Usage, residue, and human health risk of antibiotics in Chinese aquaculture:A review[J]. Environmental Pollution, 2017, 223:161-169. [5] XU Y, GUO C, LUO Y, et al. Occurrence and distribution of antibiotics, antibiotic resistance genes in the urban rivers in Beijing, China[J]. Environmental Pollution, 2016, 213:833-840. [6] BARRA CARACCIOLO A, TOPP E, GRENNI P. Pharmaceuticals in the environment:Biodegradation and effects on natural microbial communities. A review[J]. Journal of Pharmaceutical and Biomedical Analysis, 2015, 106:25-36. [7] BLETSOU A A, JEON J, HOLLENDER J, et al. Targeted and non-targeted liquid chromatography-mass spectrometric workflows for identification of transformation products of emerging pollutants in the aquatic environment[J]. Trac-Trends in Analytical Chemistry, 2015, 66:32-44. [8] JIANG M, WANG L, JI R. Biotic and abiotic degradation of four cephalosporin antibiotics in a lake surface water and sediment[J]. Chemosphere, 2010, 80(11):1399-1405. [9] MITCHELL S M, ULLMAN J L, TEEL A L, et al. Hydrolysis of amphenicol and macrolide antibiotics:Chloramphenicol, florfenicol, spiramycin, and tylosin[J]. Chemosphere, 2015, 134:504-511. [10] WANG J, WANG S. Microbial degradation of sulfamethoxazole in the environment[J]. Applied Microbiology Biotechnology, 2018, 102(8):3573-3582. [11] BAI X, ACHARYA K. Removal of trimethoprim, sulfamethoxazole, and triclosan by the green alga Nannochloris sp.[J]. Journal of Hazardous Materials, 2016, 315:70-75. [12] NAVARRO A E, LIM H, CHANG E, et al. Uptake of sulfa drugs from aqueous solutions by marine algae[J]. Separation Science and Technology, 2014, 49(14):2175-2181. [13] 陈姗,许凡,张玮,等. 磺胺类抗生素污染现状及其环境行为的研究进展[J]. 环境化学,2019,38(7):1557-1569. CHEN S, XU F, ZHANG W, et al. Research progress in pollution situation and environmental behavior of sulfonamides[J]. Environmental Chemistry, 2019, 38(7):1557-1569(in Chinese).
[14] 黄宏,李圆杏,杨红伟. 水环境中抗生素的光降解研究进展[J]. 环境化学,2013,32(7):1335-1341. HUANG H, LI Y X, YANG H W, et al. Research progress on photodegration of antibiotics in water environment[J]. Environmental Chemistry, 2013, 32(7):1335-1341(in Chinese).
[15] CHALLIS J K, HANSON M L, FRIESEN K J, et al. A critical assessment of the photodegradation of pharmaceuticals in aquatic environments:Defining our current understanding and identifying knowledge gaps[J]. Environmental Science Process and Impacts, 2014, 16(4):672-696. [16] BATCHU S R, PANDITI V R, GARDINALI P R. Photodegradation of sulfonamide antibiotics in simulated and natural sunlight:Implications for their environmental fate[J]. Journal of Environmental Science and Health, Part B, 2014, 49(3):200-211. [17] GARCIA-RODRIGUEZ A, MATAMOROS V, FONTAS C, et al. The influence of light exposure, water quality and vegetation on the removal of sulfonamides and tetracyclines:A laboratory-scale study[J]. Chemosphere, 2013, 90(8):2297-2302. [18] WILKINSON J, HOODA P S, BARKER J, et al. Occurrence, fate and transformation of emerging contaminants in water:An overarching review of the field[J]. Environmental Pollution, 2017, 231(Pt 1):954-970. [19] PAL A, HE Y, JEKEL M, et al. Emerging contaminants of public health significance as water quality indicator compounds in the urban water cycle[J]. Environment International, 2014, 71:46-62. [20] XU J, HAO Z, GUO C, et al. Photodegradation of sulfapyridine under simulated sunlight irradiation:Kinetics, mechanism and toxicity evolvement[J]. Chemosphere, 2014, 99:186-191. [21] CHEN K, ZHOU J L. Occurrence and behavior of antibiotics in water and sediments from the Huangpu River, Shanghai, China[J]. Chemosphere, 2014, 95:604-612. [22] HU Y, YAN X, SHEN Y, et al. Antibiotics in surface water and sediments from Hanjiang River, Central China:Occurrence, behavior and risk assessment[J]. Ecotoxicology and Environmental Safety, 2018, 157:150-158. [23] SUN Q, LI Y, LI M, et al. PPCPs in Jiulong River estuary (China):Spatiotemporal distributions, fate, and their use as chemical markers of wastewater[J]. Chemosphere, 2016, 150:596-604. [24] LI Y, RASHID A, WANG H, et al. Contribution of biotic and abiotic factors in the natural attenuation of sulfamethoxazole:A path analysis approach[J]. Science of The Total Environment, 2018, 633:1217-1226. [25] CHEN L, XU Y, WANG W, et al. Degradation kinetics of a potent antifouling agent, butenolide, under various environmental conditions[J]. Chemosphere, 2015, 119:1075-1083. [26] JASPER J T, JONES Z L, SHARP J O, et al. Biotransformation of trace organic contaminants in open-water unit process treatment wetlands[J]. Environmental Science & Technology, 2014, 48(9):5136-5144. [27] BARBIERI Y, MASSAD W A, DIAZ D J, et al. Photodegradation of bisphenol A and related compounds under natural-like conditions in the presence of riboflavin:Kinetics, mechanism and photoproducts[J]. Chemosphere, 2008, 73(4):564-571. [28] CHIN Y P, MILLER P L, ZENG L, et al. Photosensitized degradation of bisphenol a by dissolved organic matter[J]. Environmental Science & Technology, 2004, 38(22):5888-5894. [29] HELBLING D E, HOLLENDER J, KOHLER H-P E, et al. High-throughput identification of microbial transformation products of organic micropollutants[J]. Environmental Science & Technology, 2010, 44(17):6621-6627. [30] LBM ELLIS L W. Use of the University of Minnesota Biocatalysis/Biodegradation Database for study of microbial degradation[J]. Microbial Informatics and Experimentation, 2012, 2:1. [31] KIM I, TANAKA H. Photodegradation characteristics of PPCPs in water with UV treatment[J]. Environment International, 2009, 35(5):793-802. [32] STURINI M, SPELTINI A, MARASCHI F, et al. Photolytic and photocatalytic degradation of fluoroquinolones in untreated river water under natural sunlight[J]. Applied Catalysis B:Environmental, 2012, 119/120:32-39. [33] WU J T, WU C H, LIU C Y, et al. Photodegradation of sulfonamide antimicrobial compounds (sulfadiazine, sulfamethizole, sulfamethoxazole and sulfathiazole) in various UV/oxidant systems[J]. Water Science & Technology, 2015, 71(3):412-417. [34] SUN W J, ABURUB A, SUN C C. Particle engineering for enabling a formulation platform suitable for manufacturing low-dose tablets by direct compression[J]. Journal of Pharmaceutical Sciences, 2017, 106(7):1772-1777. [35] FENG Y, HU X, ZHAO F, et al. Fe3 O4/reduced graphene oxide-carbon nanotubes composite for the magnetic solid-phase extraction and HPLC determination of sulfonamides in milk[J]. Journal of Separation Science, 2019, 42(5):1058-1066. [36] 东天,马溪平,王闻烨,等. 抗生素光降解研究进展[J]. 环境科学与技术,2014, 37(6N):108-113. DONG T, MA X, WANG W, et al. Research progress on photodegradation of antibiotics[J]. Environmental Science & Technology, 2014, 37(6N):108-113(in Chinese).
[37] SIRTORI C, AGUERA A, GERNJAK W, et al. Effect of water-matrix composition on Trimethoprim solar photodegradation kinetics and pathways[J]. Water Research, 2010, 44(9):2735-2744. [38] VIONE D, BAGNUS D, MAURINO V, et al. Quantification of singlet oxygen and hydroxyl radicals upon UV irradiation of surface water[J]. Environmental Chemistry Letters, 2009, 8(2):193-198. [39] GE L, ZHANG P, HALSALL C, et al. The importance of reactive oxygen species on the aqueous phototransformation of sulfonamide antibiotics:Kinetics, pathways, and comparisons with direct photolysis[J]. Water Research, 2019, 149:243-250. [40] GAO Y Q, GAO N Y, CHU W H, et al. UV-activated persulfate oxidation of sulfamethoxypyridazine:Kinetics, degradation pathways and impact on DBP formation during subsequent chlorination[J]. Chemical Engineering Journal, 2019, 370:706-715. -
点击查看大图
计量
- 文章访问数: 2597
- HTML全文浏览数: 2597
- PDF下载数: 103
- 施引文献: 0
下载:
