Variations in the fate and biological effects of sulfamethoxazole, norfloxacin and doxycycline in different vegetable-soil systems following manure application

文献类型: 外文期刊

第一作者: Wang, Jianmei

作者: Wang, Jianmei;Wu, Huizhen;Qian, Mingrong;Lin, Hui;Sun, Wanchun;Xia, Yun;Ma, Junwei;Fu, Jianrong;Zhang, Zulin

作者机构:

关键词: Veterinary antibiotics;Vegetable planting;Bioaccumulation;Antibiotic dissipation;Soil microbial community

期刊名称:JOURNAL OF HAZARDOUS MATERIALS ( 影响因子:10.588; 五年影响因子:10.129 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: The fate of sulfamethoxazole (SMZ), norfloxacin (NOR) and doxycycline (DOX) and their biological effects in radish and pakchoi culture systems were investigated. DOX dissipated more rapidly than SMZ and NOR, while radish and pakchoi cultivation increased the removal of residual DOX in soils. Dissipation of NOR was accelerated in radish soils but was slowed down slightly in pakchoi soils. Vegetable cultivation exerted an insignificant effect on SMZ removal. Investigation of antibiotic bioaccumulation showed that the uptake of DOX by radish and pakchoi was undetectable, but the radish accumulated more SMZ and NOR than pakchoi. Among the three antibiotics, only SMZ use exhibited an apparent suspension of plant seed germination, up-ground plant growth and soil microbial diversity. Pakchoi responded more sensitively to SMZ than did the radish. Principal component analysis (PCA) based on MicroRESP (TM) indicated that the sampling time and antibiotic treatments could influence the soil microbial community. Only in the pakchoi soils did antibiotic application exert a more robust effect on the microbial community than the sampling time; SMZ treatments and DOX treatments could be clearly discriminated from the control treatments. These results are crucial for an assessment of the potential risks of antibiotics to culture system practices and suggest that good agricultural practices help to limit or even reduce antibiotic pollution. (C) 2015 Elsevier B.V. All rights reserved.

分类号: TB1

  • 相关文献

[1]Simultaneous determination of 38 veterinary antibiotic residues in raw milk by UPLC-MS/MS. Zheng, N.,Xu, X. M.,Qu, X. Y.,Li, S. L.,Zhang, Y. D.,Wang, J. Q.,Han, R. W.,Yu, Z. N.,Wang, J.,Zheng, N.,Xu, X. M.,Qu, X. Y.,Li, S. L.,Zhang, Y. D.,Wang, J. Q.,Zheng, N.,Xu, X. M.,Qu, X. Y.,Li, S. L.,Zhang, Y. D.,Wang, J. Q..

[2]Soil microbial systems respond differentially to tetracycline, sulfamonomethoxine, and ciprofloxacin entering soil under pot experimental conditions alone and in combination. Ma, Junwei,Lin, Hui,Sun, Wanchun,Wang, Qiang,Yu, Qiaogang,Fu, Jianrong,Zhao, Yuhua.

[3]Effects of the bioconcentration and parental transfer of environmentally relevant concentrations of difenoconazole on endocrine disruption in zebrafish (Danio rerio). Teng, Miaomiao,Zhu, Wentao,Wang, Yao,Wang, Dezhen,Wang, Chengju,Qi, Suzhen,Dong, Kai. 2018

[4]Spiders as excellent experimental models for investigation of heavy metal impacts on the environment: a review. Yang, Huilin,Peng, Yuande,Tian, Jianxiang,Yang, Huilin,Wang, Juan,Hu, Jilin,Wang, Zhi. 2016

[5]Bioaccumulation and Biodegradation of Sulfamethazine in Chlorella pyrenoidosa. Sun Ming,Lin Hong,Sun Ming,Guo Wen,Li Jian,Zhao Fazhen. 2017

[6]Antioxidant Responses and Bioaccumulation in Green-lipped Mussels (Perna Viridis) Under Acute Tributyltin Chloride Exposure. Chen, Hai-Gang,Jia, Xiao-Ping,Cai, Wen-Gui,Lin, Qin,Ma, Sheng-Wei,Chen, Hai-Gang. 2011

[7]Threshold of Soil Olsen-P in Greenhouses for Tomatoes and Cucumbers. Wu, Xue-Ping,Wu, Hui-Jun,Wang, Xiao-Bin,Li, Yin-Kun,Zhang, Yan-Cai,Li, Ruo-Nan,Wang, Li-Ying,Zhai, Cai-Xia,Chen, Li-Li,Wu, Xue-Ping,Wu, Hui-Jun,Wang, Xiao-Bin.

[8]Environmental mercury concentrations in cultured low-trophic-level fish using food waste-based diets. Cheng, Zhang,Wong, Ming Hung,Cheng, Zhang,Man, Yu Bon,Wong, Ming Hung,Man, Yu Bon,Wong, Ming Hung,Cheng, Zhang,Mo, Wing Yin,Man, Yu Bon,Lam, Cheung Lung,Choi, Wai Ming,Wong, Ming Hung,Nie, Xiang Ping,Liu, Yi Hui.

[9]Steroid bioaccumulation profiles in typical freshwater aquaculture environments of South China and their human health risks via fish consumption. Liu, Shan,Xu, Xiang-Rong,Chen, Hui,Hao, Qin-Wei,Hu, Yong-Xia,Qi, Zhan-Hui,Qi, Zhan-Hui,Hu, Yong-Xia,Zhao, Jian-Liang,Ying, Guang-Guo.

[10]Chiral bioaccumulation behavior of tebuconazole in the zebrafish (Danio rerio). Liu, Na,Dong, Fengshou,Xu, Jun,Liu, Xingang,Zheng, Yangquan.

[11]Bioaccumulation of trace metals by the live macroalga Gracilaria lemaneiformis. Wang, Zenghuan,Wang, Xunuo,Ke, Changliang,Wang, Zenghuan,Wang, Zenghuan,Wang, Xunuo,Ke, Changliang.

[12]The bioaccumulation of Cd in rice grains in paddy soils as affected and predicted by soil properties. Ye, Xinxin,Wu, Liang,Sun, Bo,Ye, Xinxin,Li, Hongying,Ma, Yibing,Wu, Liang. 2014

[13]Capability of Pentavalent Arsenic Bioaccumulation and Biovolatilization of Three Fungal Strains under Laboratory Conditions. Zeng, Xibai,Jiang, Xiliang. 2010

[14]Analysis of Cry1Ab toxin bioaccumulation in a food chain of Bt rice, an herbivore and a predator. Ye, Gong-yin,Fang, Qi,Hu, Cui,Liu, Zhi-cheng,Peng, Yu-fa. 2009

[15]Replacing fish meal by food waste in feed pellets to culture lower trophic level fish, containing acceptable levels of organochlorine pesticides: Health risk assessments. Cheng, Zhang,Mo, Wing-Yin,Man, Yu-Bon,Wong, Ming-Hung,Cheng, Zhang,Mo, Wing-Yin,Man, Yu-Bon,Wong, Ming-Hung,Cheng, Zhang,Man, Yu-Bon,Wong, Ming-Hung,Nie, Xiang-Ping,Li, Kai-Bing.

[16]Bioaccumulation of cadmium bound to ferric hydroxide and particulate organic matter by the bivalve M. meretrix. Wu, Xing,Jia, Yongfeng,Zhu, Huijie,Wu, Xing.

[17]Levels, tissue distribution, and age-related accumulation of synthetic musk fragrances in Chinese sturgeon (Acipenser sinensis): Comparison to organochlorines. Wan, Yi,Wei, Qiwei,Hu, Jianying,Jin, Xiaohui,Zhang, Zhaobin,Zhen, Huajun,Liu, Jianyi.

[18]Trace elements in farmed fish (Cyprinus carpio, Ctenopharyngodon idella and Oncorhynchus mykiss) from Beijing: implication from feed. Jiang, Haifeng,Qin, Dongli,Mou, Zhenbo,Zhao, Jiwei,Tang, Shizhan,Wu, Song,Gao, Lei.

[19]Soil calcium significantly promotes uptake of inorganic arsenic by garland chrysanthemum (ChrysanthemumL coronarium) fertilized with chicken manure bearing roxarsone and its metabolites. Bai, Cuihua,Huang, Lianxi,He, Zhaohuan,Zhou, Changmin.

[20]Arsenic contamination in the freshwater fish ponds of Pearl River Delta: bioaccumulation and health risk assessment. Cheng, Zhang,Wu, Sheng Chun,Wong, Chris Kong-Chu,Wong, Ming-Hung,Cheng, Zhang,Wu, Sheng Chun,Wong, Chris Kong-Chu,Wong, Ming-Hung,Chen, Kun-Ci,Li, Kai-Bin,Nie, Xiang-Ping,Wu, Sheng Chun,Wong, Ming-Hung,Wu, Sheng Chun,Wong, Ming-Hung.

作者其他论文 更多>>

微信小程序