Analysis and Change in Concentration of Micropollutants in Stream Affected by WWTP Effluents using Portable Composite Sampler and LC-HRMS

Journal of Environmental Analysis, Health and Toxicology Pub Date : 2023-06-30 DOI:10.36278/jeaht.26.2.55

Heelyeon Heelyeon, Daeho Kang, Younghun Choi, Junho Jeon

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Abstract

With the increase of manufacturing and use of chemicals, an increasing amount of chemicals enters surface water through various pathways. Their concentrations range from ng/L to mg/L, and they are recognized as micropollutants that pose potential risks to human health and aquatic ecosystems. This study quantitatively analyzed the diverse micropollutants in a stream affected by effluents from a waste-water treatment plant (WWTP) and demonstrated the changes in concentration over time. To capture temporal trends, water samples were collected using a portable composite sampler. For a comprehensive chemical analysis of the 148 species, target screening was conducted using liquid chromatography with high resolution mass spectrometer (LC-HRMS). As a result of the quantitative analysis, a total of 71 substances were detected at concentrations higher than the limit of quantification (LOQ). Pharmaceuticals accounted for the highest proportion among the detected substances. Tris (2-butoxyethyl) phosphate (tbep), which is used as an organophosphate flame retardant (OPFRs), was detected as a major pollutant at a maximum of 14,000 ng/L. Metformin, Pentaethylene glycol, cetirizine, galaxolidone, acetaminophen, heptaethylene glycol, carbamazepine-10,11-epoxide, sulfapyridine, valsartan acid, telmisartan, fluconazole, benzotriazole, olmesartan, 4-Methyl-1H-benzotriazole, sitagliptin, and perfluorohexanoic acid (PFHxA) were detected at concentrations of 1,000 ng/L or higher. As a unique temporal trend in the concentration, per-and polyfluoroalkyl substances (PFAS) and benzotriazoles exhibited the highest concentrations from 00:30 to 02:00 on 5/10 with a gradual decrease thereafter. The main factor responsible for this change in concentration was the effluent from the WWTP located upstream of the sampling point. In addition, the substance used in a nearby large-scale industrial complex is considered a significant factor.

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利用便携式复合采样器和LC-HRMS分析污水处理厂污水对河流微污染物浓度的影响

随着化学品生产和使用的增加，越来越多的化学品通过各种途径进入地表水。它们的浓度从纳克/升到毫克/升不等，被认为是对人类健康和水生生态系统构成潜在风险的微污染物。本研究定量分析了受污水处理厂(WWTP)流出物影响的河流中的各种微污染物，并展示了浓度随时间的变化。为了捕捉时间趋势，使用便携式复合采样器收集水样。采用液相色谱-高分辨率质谱联用技术(LC-HRMS)对148种植物进行了综合化学分析。定量分析结果显示，共有71种物质的浓度高于定量限(LOQ)。在检测到的物质中，药品所占比例最高。作为有机磷酸盐阻燃剂(OPFRs)的三(2-丁氧乙基)磷酸(tbep)被检测为主要污染物，最高可达14,000 ng/L。二甲双胍、五乙二醇、西替利嗪、galaxolidone、对乙酰氨基酚、七乙二醇、卡马西平-10,11-环氧化物、磺胺吡啶、缬沙坦酸、替米沙坦、氟康唑、苯并三唑、奥美沙坦、4-甲基- 1h -苯并三唑、西格列汀和全氟己酸(PFHxA)的浓度为1,000 ng/L或更高。5/10日00:30 - 02:00间，全氟烷基、多氟烷基物质和苯并三唑浓度最高，此后逐渐降低，具有独特的时间趋势。造成这种浓度变化的主要因素是位于采样点上游的污水处理厂的污水。此外，附近大型工业园区使用的物质被认为是一个重要因素。

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Journal of Environmental Analysis, Health and Toxicology

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