Fan Jing-Jing, Wang Sai, Tang Jin-Peng, Dai Yu-Nü, Wang Lin, Long Sheng-Xing, He Wen-Xiang, Liu Shuai-Lei, Wang Jia-Xi, Yang Yang
Research Center of Hydrobiology, College of Life Science and Technology, Jinan University, Guangzhou 510632, China.
Engineering Research Center of Tropic and Subtropic Aquatic Ecological Engineering, Ministry of Education, Guangzhou 510632, China.
Huan Jing Ke Xue. 2018 Mar 8;39(3):1053-1064. doi: 10.13227/j.hjkx.201708145.
This study aimed to investigate the occurrence and spatio-temporal distribution of 4--octylphenol (4--OP), 4-nonylphenol (4-NP), triclosan (TCS), estrone (E1), 17-estradiol (E2), and bisphenol-A (BPA) as endocrine disrupting chemicals (EDCs) in the water of the Liuxi River and to evaluate the risks for estrogenic activity. The results showed that EDCs had been detected at the 14 monitoring sites and the total concentration ranged from 26.07 ng·L to 7109.5 ng·L, with the highest contribution rate coming from 4-NP (78.62%), followed by BPA (11.91%), and the other four EDCs (≤ 4.92%). On a spatial and temporal scale, the EDC contents increased longitudinally from upstream to downstream, especially in the heavily-polluted Baiyun section where the water quality was lower than level Ⅴ. The EDC contents in the tributaries were much higher than those in the main channels. Influenced by the monsoon precipitation, the contents of 4-NP, 4--OP, and total EDCs in the rainy season were significantly (<0.05) higher than those in the dry season, while the seasonal changes of E1 and E2 followed the opposite tendency. A Pearson correlation analysis showed that DO was significantly negatively correlated with all the EDCs, suggesting that the EDCs and reductive organic pollutants might coexist. As TN, TP, NH-N, permanganate index, and EC were significantly positively correlated with E1, E2, BPA, and TCS but not obviously correlated with 4-NP (>0.05), we presumed that the pollution source of E1, E2, BPA, and TCS might be the same with nitrogen and phosphorus nutrition, originating from the point source emission of the domestic sewage, industrial, and agricultural wastewater. In contrast, 4-NP and 4--OP more likely originated from the non-point source pollution from agriculture. RDA results showed that the variation of the EDCs contents by season was more obvious than that in space (RDA1 56.14%>RDA2 14.20%), which was much more influenced by 4-NP in the rainy season and by BPA in the dry season. As E1, E2, and TCS were positively correlated with the Cu, Zn, cyanide, and fecal coliform, these three target compounds could be used to indicate the multiple pollution components for water quality. Compared with the worldwide reported EDC contents in waters, 4-NP, BPA, and TCS contents in the middle and lower reaches of the Liuxi River were at higher levels, while E1, E2, and 4--OP were at the middle and lower levels. The risk assessment for estrogenic activity showed that the RQ values in the middle and lower reaches of the Liuxi River were all greater than 1, indicating that the downstream river sections were under high risk for estrogenic activity. As a result, appropriate precautions are needed to improve environmental management.
本研究旨在调查作为内分泌干扰物(EDCs)的4-辛基酚(4-OP)、4-壬基酚(4-NP)、三氯生(TCS)、雌酮(E1)、17-β-雌二醇(E2)和双酚A(BPA)在流溪河水中的发生情况和时空分布,并评估其雌激素活性风险。结果表明,在14个监测点位均检测到了EDCs,总浓度范围为26.07 ng·L至7109.5 ng·L,贡献率最高的是4-NP(78.62%),其次是BPA(11.91%),其他四种EDCs(≤4.92%)。在时空尺度上,EDCs含量沿程从上游向下游增加,尤其是在污染严重的白云段,该段水质低于Ⅴ类。支流中的EDCs含量远高于主河道。受季风降水影响,雨季时4-NP、4-OP和总EDCs的含量显著(<0.05)高于旱季,而E1和E2的季节变化趋势则相反。Pearson相关性分析表明,溶解氧(DO)与所有EDCs均呈显著负相关,这表明EDCs与还原性有机污染物可能共存。由于总氮(TN)、总磷(TP)、氨氮(NH₃-N)、高锰酸盐指数和电导率(EC)与E1、E2、BPA和TCS呈显著正相关,但与4-NP无明显相关性(>0.05),我们推测E1、E2、BPA和TCS的污染源可能与氮磷营养相同,源自生活污水、工农业废水的点源排放。相比之下,4-NP和4-OP更可能源自农业面源污染。冗余分析(RDA)结果表明,EDCs含量随季节的变化比空间变化更明显(RDA1 56.14%>RDA2 14.20%),雨季受4-NP影响较大,旱季受BPA影响较大。由于E1、E2和TCS与铜、锌、氰化物和粪大肠菌群呈正相关,这三种目标化合物可用于指示水质的多种污染成分。与全球报道的水体中EDCs含量相比,流溪河中下游的4-NP、BPA和TCS含量处于较高水平,而E1、E2和4-OP处于中低水平。雌激素活性风险评估表明,流溪河中下游的风险商(RQ)值均大于1,表明下游河段存在较高的雌激素活性风险。因此,需要采取适当的预防措施来改善环境管理。
