金属纳米材料对不同微生物聚集体的毒性研究进展
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摘要
在总结目前污水处理系统和自然水体中典型纳米材料浓度分布的基础上,分析了金属纳米材料对污水处理系统(活性污泥和生物膜)和自然水生态系统(自然生物膜)中微生物聚集体的毒性作用研究现状,提出开展金属纳米材料对自然生物膜微生物群落结构和功能特性影响的研究,通过低浓度长期暴露实验解析其对自然水生态系统的负面效应等,为纳米材料的污染防治提供理论依据。
On the basis of summarizing the concentration distribution of typical nanomaterials in sewage treatment system and natural water body at present,the toxic effects of metal nanomaterials on microbial aggregates in sewage treatment systems( activated sludge and biofilm) and natural aquatic ecosystems( natural biofilm) were analyzed. It is proposed to study the effects of metal nanomaterials on the structure and functional characteristics of microbial communities in natural biofilms. An analysis of the negative effects on natural aquatic ecosystem by long-term exposure to low concentration was made,providing theoretical basis for pollution prevention and control of nano-materials.
On the basis of summarizing the concentration distribution of typical nanomaterials in sewage treatment system and natural water body at present,the toxic effects of metal nanomaterials on microbial aggregates in sewage treatment systems( activated sludge and biofilm) and natural aquatic ecosystems( natural biofilm) were analyzed. It is proposed to study the effects of metal nanomaterials on the structure and functional characteristics of microbial communities in natural biofilms. An analysis of the negative effects on natural aquatic ecosystem by long-term exposure to low concentration was made,providing theoretical basis for pollution prevention and control of nano-materials.
引文
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[21]LI X,LENHART J J. Aggregation and dissolution of silver nanoparticles in natural surface water[J]. Environmental Science and Technology,2012,46(10):5378-5386.
[22]PRAETORIUS A,SCHERINGER M,HUNGERBU HLER K. Development of environmental fate models for engineered nanoparticles:a case study of Ti O2nanoparticles in the Rhine River[J]. Environmental Science and Technology,2012,46(12):6705-6713.
[23]HUYNH K A,MCCAFFERY J M,CHEN K L.Heteroaggregation of multiwalled carbon nanotubes and hematite nanoparticles:rates and mechanisms[J].Environmental Science and Technology,2012,46(11):5912-5920.
[24]KAEGI R,VOEGELIN A,ORT C,et al. Fate and transformation of silver nanoparticles in urban wastewater systems[J]. Water Research,2013,47:3866-3877.
[25]PETERSEN E J,ZHANG L,MATTISON N T,et al.Potential release pathways, environmental fate, and ecological risks of carbon nanotubes[J]. Environmental Science and Technology,2011,45(23):9837-9856.
[26] KUNHIKRISHNAN A,SHON H K,BOLAN N S,et al.Sources,distribution,environmental fate,and ecological effects of nanomaterials in wastewater streams[J]. Critical Reviews in Environmental Science and Technology,2015,45(4):277-318.
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[28]WESTERHOFF P,SONG G,HRISTOVSKI K,et al.Occurrence and removal of titanium at full scale wastewater treatment plants:implications for Ti O2nanomaterials[J]. Journal of Environmental Monitoring,2011,13(5):1195-1203.
[29]BONDARENKO O,IVASK A,KKINEN A,et al. Subtoxic effects of Cu O nanoparticles on bacteria:kinetics,role of Cu ions and possible mechanisms of action[J].Environmental Pollution,2012,169:81-89.
[30]ZHOU D,ABDEL-FATTAH A I,KELLER A A. Clay particles destabilize engineered nanoparticles in aqueous environments[J]. Environmental Science and Technology,2012,46(14):7520-7526.
[31]ZHU X,CAI Z. Behavior and effect of manufactured nanomaterials in the marine environment[J]. Integrated Environmental Assessment and Management,2012,8(3):566-567.
[32]BRUNETTI G,DONNER E,LAERA G,et al. Fate of zinc and silver engineered nanoparticles in sewerage networks[J]. Water Research,2015,77:72-84.
[33]LIU H H,BILAL M,COHEN Y,et al. Regional multimedia distribution of nanomaterials and associated exposures:a software platform[C]//2014 IEEE International Conference on Bioinformatics and Biomedicine-BIBM. New York:IEEE,2015.
[34]WANG X H,ZHU M H,LI N K,et al. Effects of Ce O2nanoparticles on bacterial community and molecular ecological network in activated sludge system[J].Environmental Pollution,2018,238:516-523.
[35]SONG Y X,CHAI L Y,TANG C J,et al. Influence of Zn O nanoparticles on anammox granules:the inhibition kinetics and mechanism analysis by batch assays[J]. Biochemical Engineering Journal,2018,133:122-129.
[36]GWIN C A,LEFEVRE E,ALITO C L,et al. Microbial community response to silver nanoparticles and Ag+in nitrifying activated sludge revealed by ion semiconductor sequencing[J]. Science of the Total Environment,2018,616:1014-1021.
[37]KAPOOR V,PHAN D,PASHA A B M T. Effects of metal oxide nanoparticles on nitrification in wastewater treatment systems:a systematic review[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances&Environmental Engineering,2018,53(7):659-668.
[38]ZHENG X,SU Y,CHEN Y. Acute and chronic responses of activated sludge viability and performance to silica nanoparticles[J]. Environmental Science and Technology,2012,46(13):7182-7188.
[39]ZHENG X,WU R,CHEN Y. Effects of Zn O nanoparticles on wastewater biological nitrogen and phosphorus removal[J]. Environmental Science and Technology,2011,45(7):2826-2832.
[40]CHEN Y,WANG D,ZHU X,et al. Long-term effects of copper nanoparticles on wastewater biological nutrient removal and N2O generation in the activated sludge process[J]. Environmental Science and Technology,2012,46(22):12452-12458.
[41] CHEN J,TANG Y Q,LI Y,et al. Impacts of different nanoparticles on functional bacterial community in activated sludge[J]. Chemosphere,2014,104:141-148.
[42]HOU L,XIA J,LI K,et al. Removal of Zn O nanoparticles in simulated wastewater treatment processes and its effects on COD and NH+4-N reduction[J]. Water Science and Technology,2012,67(2):254-260.
[43]CHEN Y,SU Y,ZHENG X,et al. Alumina nanoparticlesinduced effects on wastewater nitrogen and phosphorus removal after short-term and long-term exposure[J].Water Research,2012,46(14):4379-4386.
[44]ZHENG X,CHEN Y,WU R. Long-term effects of titanium dioxide nanoparticles on nitrogen and phosphorus removal from wastewater and bacterial community shift in activated sludge[J]. Environmental Science and Technology,2011,45(17):7284-7290.
[45]HOU J,YOU G,XU Y,et al. Effects of Ce O2nanoparticles on biological nitrogen removal in a sequencing batch biofilm reactor and mechanism of toxicity[J]. Bioresource Technology,2015,191:73-78.
[46]PUAY N,QIU G,TING Y. Effect of Zinc oxide nanoparticles on biological wastewater treatment in a sequencing batch reactor[J]. Journal of Cleaner Production,2015,88:139-145.
[47]WU D,SHEN Y,DING A,et al. Effects of nanoscale zerovalent iron particles on biological nitrogen and phosphorus removal and microorganisms in activated sludge[J].Journal of Hazardous Materials,2013,262:649-655.
[48]HOU J,YOU G,XU Y,et al. Impacts of Cu O nanoparticles on nitrogen removal in sequencing batch biofilm reactors after short-term and long-term exposure and the functions of natural organic matter[J]. Environmental Science and Pollution Research,2016,23:22116-22125.
[49]CHEN Y,CHEN H,ZHENG X,et al. The impacts of silver nanoparticles and silver ions on wastewater biological phosphorous removal and the mechanisms[J]. Journal of Hazardous Materials,2012,239/240:88-94.
[50]张磊,郎建峰,牛姗姗.生物膜法在污水处理中的研究进展[J].水科学与工程技术,2010(5):38-41.(ZHANG Lei,LANG Jianfeng,NIU Shanshan. Biofilm research progress in wastewater treatment[J]. Water Sciences and Engineering Technology,2010(5):38-41.(in Chinese))
[51]HENZE M,Van LOOSDRECHT M C,EKAMA G A.Biological wastewater treatment[M]. Boca Raton:CRC Press,2008.
[52]SHENG Z,LIU Y. Effects of silver nanoparticles on wastewater biofilms[J]. Water Research,2011,45(18):6039-6050.
[53]HOU J,MIAO L,WANG C,et al. Inhibitory effects of Zn O nanoparticles on aerobic wastewater biofilms from oxygen concentration profiles determined by microelectrodes[J].Journal of Hazardous Materials,2014,276:164-170.
[54]MIAO L,WANG C,HOU J,et al. Response of wastewater biofilm to Cu O nanoparticle exposure in terms of extracellular polymeric substances and microbial community structure[J]. Science of the Total Environment,2017,579:588-597.
[55] BATTIN T J,BESEMER K,BENGTSSON M M,et al. The ecology and biogeochemistry of stream biofilms[J]. Nature Reviews Microbiology,2016,14(4):251-263.
[56]FLEMMING H C,WINGENDER J,SZEWZYK U,et al.Biofilms:an emergent form of bacterial life[J]. Nature Reviews Microbiology,2016,14(9):563-575.
[57] GIL-ALLUE C,SCHIRMER K,TLILI A,et al. Silver nanoparticle effects on stream periphyton during short-term exposures[J]. Environmental Science and Technology,2015,49(2):1165-1172.
[58]LIU J,TANG J,WAN J,et al. Functional sustainability of periphytic biofilms in organic matter and Cu2+removal during prolonged exposure to Ti O2nanoparticles[J].Journal of Hazardous Materials,2017,279:68.
[59]TANG J,ZHU N Y,ZHU Y,et al. Responses of periphyton to Fe2O3nanoparticles:a physiological and ecological basis for defending nanotoxicity[J]. Environmental Science and Technology,2017,51(18):10797-10805.
[2]高濂,孙静,刘阳桥.纳米粉体的分散及表面改性[M].北京:化学工业出版社,2003.
[3]夏俊,陆光华,赵海洲,等.人工纳米材料在流动水域中的环境行为与生物效应[J].水资源保护,2013,29(6):1-5.(XIA Jun,LU Guanghua,ZHAO Haizhou,et al.Environmental behaviors and biological effects of manufactured nanomaterials in flowing waters[J]. Water Resources Protection,2013,29(6):1-5.(in Chinese))
[4] NOWACK B,BUCHELI T D. Occurrence,behavior and effects of nanoparticles in the environment[J].Environmental Pollution,2007,150(1):5-22.
[5] GOTTSCHALK F,SONDERER T,SCHOLZ R W,et al.Modeled environmental concentrations of engineered nanomaterials(Ti O2,Zn O,Ag,CNT,fullerenes)for different regions[J]. Environmental Science&Technology,2009,43(24):9216-9222.
[6] KELLER A A,MCFERRAN S,LAZAREVA A,et al.Global life cycle releases of engineered nanomaterials[J].Journal of Nanoparticle Research,2013,15(6):1692.
[7]MEESTERS J A J,QUIK J T K,KOELMANS A A,et al.Multimedia environmental fate and speciation of engineered nanoparticles:a probabilistic modeling approach[J].Environmental Science:Nano,2016,3(4):715-727.
[8]侯俊,次瀚林,吕博文,等.典型人工纳米材料的水环境行为研究进展[J].水资源保护,2017,33(6):1-8.(HOU Jun,CI Hanlin,LYU Bowen,et al. Review of behaviors of engineered nanomaterials in aquatic environment[J]. Water Resources Protection,2017,33(6):1-8.(in Chinese))
[9]SCOWN T M,VAN AERLE R,TYLER C R. Review:do engineered nanoparticles pose a significant threat to the aquatic environment?[J]. Critical Reviews in Toxicology,2010,40(7):653-670.
[10] FINDLAY S,SINSABAUGH R L. Aquatic ecosystems:interactivity of dissolved organic matter[M]. Pittsburgh:Academic Press,2003.
[11]BATTIN T J,KAPLAN L A,NEWBOLD J D,et al.Contributions of microbial biofilms to ecosystem processes in stream mesocosms[J]. Nature,2003,426:439.
[12]HOLDEN P A,KLAESSIG F,TURCO R F,et al.Evaluation of exposure concentrations used in assessing manufactured nanomaterial environmental hazards:are they relevant?[J]. Environmental Science&Technology,2014,48(18):10541-10551.
[13]PEREZ S,FARRE M L,BARCELO D. Analysis,behavior and ecotoxicity of carbon-based nanomaterials in the aquatic environment[J]. Trac-trends in Analytical Chemistry,2009,28(6):820-832.
[14]MUSEE N. Nanowastes and the environment:potential new waste management paradigm[J]. Environ Int,2011,37(1):112-128.
[15]PEIJNENBURG W J G M,BAALOUSHA M,CHEN J,et al. A review of the properties and processes determining the fate of engineered nanomaterials in the aquatic environment[J]. Critical Reviews in Environmental Science and Technology,2015,45(19):2084-2134.
[16]GARNER K L,KELLER A A. Emerging patterns for engineered nanomaterials in the environment:a review of fate and toxicity studies[J]. Journal of Nanoparticle Research,2014,16(8):
[17]KLAINE S J,ALVAREZ P J J,BATLEY G E,et al.Nanomaterials in the environment:behavior, fate,bioavailability,and effects[J]. Environmental Toxicology and Chemistry,2008,27(9):1825-1851.
[18]BOUR A, MOUCHET F, SILVESTRE J, et al.Environmentally relevant approaches to assess nanoparticles ecotoxicity:a review[J]. Journal of Hazardous Materials,2015,283:764-775.
[19]SAJID M,ILYAS M,BASHEER C,et al. Impact of nanoparticles on human and environment:review of toxicity factors,exposures,control strategies,and future prospects[J]. Environmental Science and Pollution Research,2015,22(6):4122-43.
[20]李定龙,朱宏飞,关小红.吸附法去除饮用水中砷的研究进展[J].水资源保护,2007,23(6):44-47.(LI Dinglong,ZHU Hongfei,GUAN Xiaohong. Advances in research of arsenic removal from drinking water by adsorption[J]. Water Resources Protection,2007,23(6):44-47.(in Chinese))
[21]LI X,LENHART J J. Aggregation and dissolution of silver nanoparticles in natural surface water[J]. Environmental Science and Technology,2012,46(10):5378-5386.
[22]PRAETORIUS A,SCHERINGER M,HUNGERBU HLER K. Development of environmental fate models for engineered nanoparticles:a case study of Ti O2nanoparticles in the Rhine River[J]. Environmental Science and Technology,2012,46(12):6705-6713.
[23]HUYNH K A,MCCAFFERY J M,CHEN K L.Heteroaggregation of multiwalled carbon nanotubes and hematite nanoparticles:rates and mechanisms[J].Environmental Science and Technology,2012,46(11):5912-5920.
[24]KAEGI R,VOEGELIN A,ORT C,et al. Fate and transformation of silver nanoparticles in urban wastewater systems[J]. Water Research,2013,47:3866-3877.
[25]PETERSEN E J,ZHANG L,MATTISON N T,et al.Potential release pathways, environmental fate, and ecological risks of carbon nanotubes[J]. Environmental Science and Technology,2011,45(23):9837-9856.
[26] KUNHIKRISHNAN A,SHON H K,BOLAN N S,et al.Sources,distribution,environmental fate,and ecological effects of nanomaterials in wastewater streams[J]. Critical Reviews in Environmental Science and Technology,2015,45(4):277-318.
[27] KELLER A A,MCFERRAN S,LAZAREVA A,et al.Global life cycle releases of engineered nanomaterials[J].Journal of Nanoparticle Research,2013,15:1692
[28]WESTERHOFF P,SONG G,HRISTOVSKI K,et al.Occurrence and removal of titanium at full scale wastewater treatment plants:implications for Ti O2nanomaterials[J]. Journal of Environmental Monitoring,2011,13(5):1195-1203.
[29]BONDARENKO O,IVASK A,KKINEN A,et al. Subtoxic effects of Cu O nanoparticles on bacteria:kinetics,role of Cu ions and possible mechanisms of action[J].Environmental Pollution,2012,169:81-89.
[30]ZHOU D,ABDEL-FATTAH A I,KELLER A A. Clay particles destabilize engineered nanoparticles in aqueous environments[J]. Environmental Science and Technology,2012,46(14):7520-7526.
[31]ZHU X,CAI Z. Behavior and effect of manufactured nanomaterials in the marine environment[J]. Integrated Environmental Assessment and Management,2012,8(3):566-567.
[32]BRUNETTI G,DONNER E,LAERA G,et al. Fate of zinc and silver engineered nanoparticles in sewerage networks[J]. Water Research,2015,77:72-84.
[33]LIU H H,BILAL M,COHEN Y,et al. Regional multimedia distribution of nanomaterials and associated exposures:a software platform[C]//2014 IEEE International Conference on Bioinformatics and Biomedicine-BIBM. New York:IEEE,2015.
[34]WANG X H,ZHU M H,LI N K,et al. Effects of Ce O2nanoparticles on bacterial community and molecular ecological network in activated sludge system[J].Environmental Pollution,2018,238:516-523.
[35]SONG Y X,CHAI L Y,TANG C J,et al. Influence of Zn O nanoparticles on anammox granules:the inhibition kinetics and mechanism analysis by batch assays[J]. Biochemical Engineering Journal,2018,133:122-129.
[36]GWIN C A,LEFEVRE E,ALITO C L,et al. Microbial community response to silver nanoparticles and Ag+in nitrifying activated sludge revealed by ion semiconductor sequencing[J]. Science of the Total Environment,2018,616:1014-1021.
[37]KAPOOR V,PHAN D,PASHA A B M T. Effects of metal oxide nanoparticles on nitrification in wastewater treatment systems:a systematic review[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances&Environmental Engineering,2018,53(7):659-668.
[38]ZHENG X,SU Y,CHEN Y. Acute and chronic responses of activated sludge viability and performance to silica nanoparticles[J]. Environmental Science and Technology,2012,46(13):7182-7188.
[39]ZHENG X,WU R,CHEN Y. Effects of Zn O nanoparticles on wastewater biological nitrogen and phosphorus removal[J]. Environmental Science and Technology,2011,45(7):2826-2832.
[40]CHEN Y,WANG D,ZHU X,et al. Long-term effects of copper nanoparticles on wastewater biological nutrient removal and N2O generation in the activated sludge process[J]. Environmental Science and Technology,2012,46(22):12452-12458.
[41] CHEN J,TANG Y Q,LI Y,et al. Impacts of different nanoparticles on functional bacterial community in activated sludge[J]. Chemosphere,2014,104:141-148.
[42]HOU L,XIA J,LI K,et al. Removal of Zn O nanoparticles in simulated wastewater treatment processes and its effects on COD and NH+4-N reduction[J]. Water Science and Technology,2012,67(2):254-260.
[43]CHEN Y,SU Y,ZHENG X,et al. Alumina nanoparticlesinduced effects on wastewater nitrogen and phosphorus removal after short-term and long-term exposure[J].Water Research,2012,46(14):4379-4386.
[44]ZHENG X,CHEN Y,WU R. Long-term effects of titanium dioxide nanoparticles on nitrogen and phosphorus removal from wastewater and bacterial community shift in activated sludge[J]. Environmental Science and Technology,2011,45(17):7284-7290.
[45]HOU J,YOU G,XU Y,et al. Effects of Ce O2nanoparticles on biological nitrogen removal in a sequencing batch biofilm reactor and mechanism of toxicity[J]. Bioresource Technology,2015,191:73-78.
[46]PUAY N,QIU G,TING Y. Effect of Zinc oxide nanoparticles on biological wastewater treatment in a sequencing batch reactor[J]. Journal of Cleaner Production,2015,88:139-145.
[47]WU D,SHEN Y,DING A,et al. Effects of nanoscale zerovalent iron particles on biological nitrogen and phosphorus removal and microorganisms in activated sludge[J].Journal of Hazardous Materials,2013,262:649-655.
[48]HOU J,YOU G,XU Y,et al. Impacts of Cu O nanoparticles on nitrogen removal in sequencing batch biofilm reactors after short-term and long-term exposure and the functions of natural organic matter[J]. Environmental Science and Pollution Research,2016,23:22116-22125.
[49]CHEN Y,CHEN H,ZHENG X,et al. The impacts of silver nanoparticles and silver ions on wastewater biological phosphorous removal and the mechanisms[J]. Journal of Hazardous Materials,2012,239/240:88-94.
[50]张磊,郎建峰,牛姗姗.生物膜法在污水处理中的研究进展[J].水科学与工程技术,2010(5):38-41.(ZHANG Lei,LANG Jianfeng,NIU Shanshan. Biofilm research progress in wastewater treatment[J]. Water Sciences and Engineering Technology,2010(5):38-41.(in Chinese))
[51]HENZE M,Van LOOSDRECHT M C,EKAMA G A.Biological wastewater treatment[M]. Boca Raton:CRC Press,2008.
[52]SHENG Z,LIU Y. Effects of silver nanoparticles on wastewater biofilms[J]. Water Research,2011,45(18):6039-6050.
[53]HOU J,MIAO L,WANG C,et al. Inhibitory effects of Zn O nanoparticles on aerobic wastewater biofilms from oxygen concentration profiles determined by microelectrodes[J].Journal of Hazardous Materials,2014,276:164-170.
[54]MIAO L,WANG C,HOU J,et al. Response of wastewater biofilm to Cu O nanoparticle exposure in terms of extracellular polymeric substances and microbial community structure[J]. Science of the Total Environment,2017,579:588-597.
[55] BATTIN T J,BESEMER K,BENGTSSON M M,et al. The ecology and biogeochemistry of stream biofilms[J]. Nature Reviews Microbiology,2016,14(4):251-263.
[56]FLEMMING H C,WINGENDER J,SZEWZYK U,et al.Biofilms:an emergent form of bacterial life[J]. Nature Reviews Microbiology,2016,14(9):563-575.
[57] GIL-ALLUE C,SCHIRMER K,TLILI A,et al. Silver nanoparticle effects on stream periphyton during short-term exposures[J]. Environmental Science and Technology,2015,49(2):1165-1172.
[58]LIU J,TANG J,WAN J,et al. Functional sustainability of periphytic biofilms in organic matter and Cu2+removal during prolonged exposure to Ti O2nanoparticles[J].Journal of Hazardous Materials,2017,279:68.
[59]TANG J,ZHU N Y,ZHU Y,et al. Responses of periphyton to Fe2O3nanoparticles:a physiological and ecological basis for defending nanotoxicity[J]. Environmental Science and Technology,2017,51(18):10797-10805.