Pollution Characteristics of Typical Antibiotic Resistance Genes in Sludge Treatment Wetlands

Zhuma Luosang; Wanjun Zhang; Junwen Ma; fengying Huang; Yubo Cui

doi:10.1051/e3sconf/202019404010

All issues

Volume 194 (2020)

E3S Web Conf., 194 (2020) 04010

References

Open Access

Issue		E3S Web Conf. Volume 194, 2020 2020 5^th International Conference on Advances in Energy and Environment Research (ICAEER 2020)


Article Number		04010
Number of page(s)		4
Section		Environmental Protection and Pollution Control
DOI		https://doi.org/10.1051/e3sconf/202019404010
Published online		15 October 2020

B.J. XU, Y. LUO, Q. ZHOU, et al. Journal of Enviro nmental Science, Antibiotic resistance gene: a new e nvironmental pollutant, 28, 1499-1505, (2019) [Google Scholar]
X.X. YUAN, J.Y. LIANG, L.X. FAN, et al. Acta Pedologica Sinica, Effects of Manure Application on Source and Transport of Antibiotic Resistant Genes in Soil and Their Affecting Factors, 57, 36-47, (2020) [Google Scholar]
H.E. HOLGER, S.L.H.T. QODIAH, Z.M.L. UTE, et al. Environ. Microbiol, Accumulation of sulphonamide resistance genes in arable soils due to repeated application of manure containing sulfadiazine, 77, 2527-2530 [Google Scholar]
P.R.D. AMY, P. RUOTING, S.T.B. HEATHER, et al. , Environmental Science & Technology, Antibiotic resistance genes as emerging contaminants: studies in northern Colorado, 40, 7445-7450(2006) [Google Scholar]
J. XU, P. HU, J.P. LU, et al. , Science & Technology Review, Characteristics and control measures of antibiotic and resistance gene pollution in water environment, 36, 13-23(2018) [Google Scholar]
Y.B. CUI, Z.Q. GUO, Y.H. LIU, et al. Journal of Chongqing Jianzhu University, Study on ecological stabilization of excess sludge, 33, 151-156(2011) [Google Scholar]
Y.B. CUI, Journal of Jilin Agricultural University, Research progress of sludge treatment technology in Constructed Wetland, 39, 1-9(2017) [Google Scholar]
J.W. MA, Y.B. CUI, A.M. LI, et al. Science of the total environment, Evaluation of the fate of nutrients, antibiotics, and antibiotic resistance genes in sludge treatment wetlands, 712, 13-63+70(2020) [Google Scholar]
J.H. MILLER, J.T. NOVAK, W.R. KNOCKE, et al. Water Environment Research A Research Publication of the Water Environment Federation, Effect of silver nanoparticles and antibiotics on antibiotic resistance genes in anaerobic digestion, 85, 411(2013) [Google Scholar]
P. WEI, F.Y. HUANG, J.Q. SU, et al. Journal of Environmental Engineering, Effects of composting on tetracycline antibiotics and resistance genes in sludge, 8, 5431-5438 (2014) [Google Scholar]
C. WANG, Dalian University of Technology, Removal Efficiency and Correlation Study of Antibiotics and Related Resistance Genes in Sludge Drying Reed Beds (2018) [Google Scholar]
S.F. LI, Dalian Minzu University, Study on Removal Efficiency of Quinolone Antibiotics and Resistance Genes in Sludge Treatment of Wetland Stabilized Sludge (2020) [Google Scholar]
A. CRISTINA, J. MARAIA, G. GALAN, et al. Journal of Hazardous Materials, New insights on the combined removal of antibiotics and ARG inurban wastewater through the use of two configurations f verticalsubsurface flow constructed wetlands, 03, 163(2020) [Google Scholar]
G. VACCA, H. WAND, M. NIKOLAUSE, et al. , Water Research, Effect of plants and filter materials on bacteria removalin pilot-scale constructed wetlands, 39, 1361(2005) [Google Scholar]
W.J. ZHANG, Y.B. CUI, Y. WANG, et al. Journal of safety and environment, Study on the diversity of Endophytes in reed bed with sludge drying, 17, 1407-1412(2017) [Google Scholar]
S.Q. WANG, Y.B. CUI, A.M. LI, et al. Journal of Environmental Management, Deciphering of organic matter and nutrient removal and bacterial community in three sludge treatment wetlands under different operating conditions, 260, 11-01+59(2020) [Google Scholar]

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[1] B.J. XU, Y. LUO, Q. ZHOU, et al. Journal of Enviro nmental Science, Antibiotic resistance gene: a new e nvironmental pollutant, 28, 1499-1505, (2019) [Google Scholar]

[2] X.X. YUAN, J.Y. LIANG, L.X. FAN, et al. Acta Pedologica Sinica, Effects of Manure Application on Source and Transport of Antibiotic Resistant Genes in Soil and Their Affecting Factors, 57, 36-47, (2020) [Google Scholar]

[3] H.E. HOLGER, S.L.H.T. QODIAH, Z.M.L. UTE, et al. Environ. Microbiol, Accumulation of sulphonamide resistance genes in arable soils due to repeated application of manure containing sulfadiazine, 77, 2527-2530 [Google Scholar]

[4] P.R.D. AMY, P. RUOTING, S.T.B. HEATHER, et al. , Environmental Science & Technology, Antibiotic resistance genes as emerging contaminants: studies in northern Colorado, 40, 7445-7450(2006) [Google Scholar]

[5] J. XU, P. HU, J.P. LU, et al. , Science & Technology Review, Characteristics and control measures of antibiotic and resistance gene pollution in water environment, 36, 13-23(2018) [Google Scholar]

[6] Y.B. CUI, Z.Q. GUO, Y.H. LIU, et al. Journal of Chongqing Jianzhu University, Study on ecological stabilization of excess sludge, 33, 151-156(2011) [Google Scholar]

[7] Y.B. CUI, Journal of Jilin Agricultural University, Research progress of sludge treatment technology in Constructed Wetland, 39, 1-9(2017) [Google Scholar]

[8] J.W. MA, Y.B. CUI, A.M. LI, et al. Science of the total environment, Evaluation of the fate of nutrients, antibiotics, and antibiotic resistance genes in sludge treatment wetlands, 712, 13-63+70(2020) [Google Scholar]

[9] J.H. MILLER, J.T. NOVAK, W.R. KNOCKE, et al. Water Environment Research A Research Publication of the Water Environment Federation, Effect of silver nanoparticles and antibiotics on antibiotic resistance genes in anaerobic digestion, 85, 411(2013) [Google Scholar]

[10] P. WEI, F.Y. HUANG, J.Q. SU, et al. Journal of Environmental Engineering, Effects of composting on tetracycline antibiotics and resistance genes in sludge, 8, 5431-5438 (2014) [Google Scholar]

[11] C. WANG, Dalian University of Technology, Removal Efficiency and Correlation Study of Antibiotics and Related Resistance Genes in Sludge Drying Reed Beds (2018) [Google Scholar]

[12] S.F. LI, Dalian Minzu University, Study on Removal Efficiency of Quinolone Antibiotics and Resistance Genes in Sludge Treatment of Wetland Stabilized Sludge (2020) [Google Scholar]

[13] A. CRISTINA, J. MARAIA, G. GALAN, et al. Journal of Hazardous Materials, New insights on the combined removal of antibiotics and ARG inurban wastewater through the use of two configurations f verticalsubsurface flow constructed wetlands, 03, 163(2020) [Google Scholar]

[14] G. VACCA, H. WAND, M. NIKOLAUSE, et al. , Water Research, Effect of plants and filter materials on bacteria removalin pilot-scale constructed wetlands, 39, 1361(2005) [Google Scholar]

[15] W.J. ZHANG, Y.B. CUI, Y. WANG, et al. Journal of safety and environment, Study on the diversity of Endophytes in reed bed with sludge drying, 17, 1407-1412(2017) [Google Scholar]

[16] S.Q. WANG, Y.B. CUI, A.M. LI, et al. Journal of Environmental Management, Deciphering of organic matter and nutrient removal and bacterial community in three sludge treatment wetlands under different operating conditions, 260, 11-01+59(2020) [Google Scholar]