Transport behavior of microorganism in the porous media
ZHANG Wen-jing1,2, QIN Yun-qi1,2, LIU-Dan1,2, MA Tian-yi1,2, LI Xiao-fei1,2
1. Key Laboratory of Groundwater Resources and Environment, Ministry of Education, Jilin University, Changchun 130021, China; 2. College of New Energy and Environment, Jilin University, Changchun 130021, China
Understanding the fate and transport of pathogenic microorganisms in porous media is of great significance to protect water resources. On the basis of the previous research at home and abroad, the migration behaviour of microorganisms in porous media has been summarized. Several studies have shown that, pathogenic microorganisms as a kind of biocolloid, its transport will be controlled by a series of complex mechanism. In addition to the common hydrodynamic and hydrochemical conditions, microorganisms are also affected by itself characteristics, medium particles and environmental factors during the migration process. On this basis, the migration behaviours of microorganisms in saturated porous media and unsaturated porous media have been discussed, and the research focus in recent years have also been briefly summarized. At present, a great number of related researches about this topic have been published. However, due to the complexity of underground environment and the variability of microorganisms, it is necessary to further discuss the remediation of microorganism pollution in groundwater system.
张文静, 秦运琦, 刘丹, 马添翼, 厉晓飞. 微生物在多孔介质中环境行为研究[J]. 中国环境科学, 2018, 38(10): 3975-3984.
ZHANG Wen-jing, QIN Yun-qi, LIU-Dan, MA Tian-yi, LI Xiao-fei. Transport behavior of microorganism in the porous media. CHINA ENVIRONMENTAL SCIENCECE, 2018, 38(10): 3975-3984.
Zhang W, Li S, Wang S, et al. Transport of Escherichia coli phage through saturated porous media considering managed aquifer recharge[J]. Environmental science and pollution research international, 2018, 25(7):6497-6513.
Ghanem N, Kiesel B, Kallies R, et al. Marine Phages As Tracers:Effects of Size, Morphology, and Physico-Chemical Surface Properties on Transport in a Porous Medium[J]. Environmental science & technology, 2016,50(23):12816-12824.
[7]
Walshe G E, Pang L, Flury M, et al. Effects of pH, ionic strength, dissolved organic matter, and flow rate on the co-transport of MS2bacteriophages with kaolinite in gravel aquifer media[J]. Water Research, 2010,44(4):1255-1269.
Zhong H, Liu G, Jiang Y, et al. Transport of bacteria in porous media and its enhancement by surfactants for bioaugmentation:A review[J]. Biotechnol Adv, 2017,35(4):490-504.
[11]
Ginn T R, Wood B D, Nelson K E, et al. Processes in microbial transport in the natural subsurface[J]. Advances In Water Resources, 2002,25(8-12):1017-1042.
[12]
Foppen J W, Van H M, Schijven J. Measuring and modelling straining of Escherichia coli in saturated porous media.[J]. Journal of Contaminant Hydrology, 2007,93(1):236-254.
[13]
Bradford S A, Simunek J, Walker S L. Transport and straining of E-coli O157:H7in saturated porous media[J]. Water Resources Research, 2006,42(12):150-152.
[14]
Bradford S A, Torkzaban S. Colloid transport and retention in unsaturated porous media:A review of interface-, collector-, and pore-scale processes and models[J]. Vadose Zone Journal, 2008,7(2):667-681.
[15]
Foppen J W A, Mporokoso A, Schijven J F. Determining straining of Escherichia coli from breakthrough curves[J]. Journal of contaminant hydrology, 2005,76(3/4):191-210.
[16]
Porubcan A A, Xu S P. Colloid straining within saturated heterogeneous porous media[J]. Water Research, 2011,45(4):1796-1806.
[17]
Auset M, Keller A A. Pore-scale processes that control dispersion of colloids in saturated porous media[J]. Water Resources Research, 2004,40(3):114-125.
[18]
Bradford S A, Simunek J, Bettahar M, et al. Modeling colloid attachment, straining, and exclusion in saturated porous media[J]. Environmental science & technology, 2003,37(10):2242-2250.
[19]
Keller A A, Auset M. A review of visualization techniques of biocolloid transport processes at the pore scale under saturated and unsaturated conditions[J]. Advances In Water Resources, 2007,30(6/7):1392-1407.
[20]
Xu S P, Liao Q, Saiers J E. Straining of nonspherical colloids in saturated porous media[J]. Environmental science & technology, 2008,42(3):771-778.
[21]
Santos A, Barros P H L. Multiple Particle Retention Mechanisms during Filtration in Porous Media[J]. Environmental science & technology, 2010,44(7):2515-2521.
[22]
Bradford S A, Torkzaban S, Walker S L. Coupling of physical and chemical mechanisms of colloid straining in saturated porous media[J]. Water Research, 2007,41(13):3012-3024.
[23]
Stevik T K, Aa K, Ausland G, et al. Retention and removal of pathogenic bacteria in wastewater percolating through porous media:a review[J]. Water Research, 2004,38(6):1355-1367.
[24]
Zhong H, Zeng G M, Liu J X, et al. Adsorption of monorhamnolipid and dirhamnolipid on two Pseudomonas aeruginosa strains and the effect on cell surface hydrophobicity[J]. Applied Microbiology & Biotechnology, 2008,79(4):671-677.
[25]
Chakraborty S, Mukherji S, Mukherji S. Surface hydrophobicity of petroleum hydrocarbon degrading Burkholderia strains and their interactions with NAPLs and surfaces[J]. Colloids And Surfaces B-Biointerfaces, 2010,78(1):101-108.
[26]
Nascimento A G, Totola M R, Souza C S, et al. Temporal and spatial dynamics of blocking and ripening effects on bacterial transport through a porous system:A possible explanation for CFT deviation[J]. Colloids And Surfaces B-Biointerfaces, 2006,53(2):241-244.
[27]
Schinner T, Letzner A, Liedtke S, et al. Transport of selected bacterial pathogens in agricultural soil and quartz sand[J]. Water Research, 2010,44(4):1182-1192.
[28]
Camesano T A, Unice K M, Logan B E. Blocking and ripening of colloids in porous media and their implications for bacterial transport[J]. Colloids & Surfaces A Physicochemical & Engineering Aspects, 1999,160(3):291-307.
Torkzaban S, Hassanizadeh S M, Schijven J F, et al. Virus Transport in Saturated and Unsaturated Sand Columns[J]. Vadose Zone Journal, 2006,5(3):877-885.
[31]
Park J A, Kim S B. DLVO and XDLVO calculations for bacteriophage MS2 adhesion to iron oxide particles[J]. Journal of Contaminant Hydrology, 2015,181:131-140.
[32]
Mitropoulou P N, Syngouna V I, Chrysikopoulos C V. Transport of colloids in unsaturated packed columns:Role of ionic strength and sand grain size[J]. Chemical Engineering Journal, 2013,232(232):237-248.
[33]
于喜鹏.人工回灌条件下病毒在饱和多孔介质中的迁移规律研究[D]. 长春:吉林大学, 2016.
[34]
Dong Z, Yang H, Wu D, et al. Influence of silicate on the transport of bacteria in quartz sand and iron mineral-coated sand[J]. Colloids & Surfaces B Biointerfaces, 2014,123:995-1002.
[35]
Sutton G, Kiyosaki R T. Rich Dad's Advisors®:The ABC's of Writing Winning Business Plans:How to Prepare a Business Plan That Others[J]. Environmental science & technology, 1991,25(1):178-85.
[36]
Syngouna V I, Chrysikopoulos C V, Kokkinos P, et al. Cotransport of human adenoviruses with clay colloids and TiO2 nanoparticles in saturated porous media:Effect of flow velocity.[J]. Science of the Total Environment, 2017,598:160-167.
[37]
Sasidharan S, Bradford S A, Torkzaban S, et al. Unraveling the complexities of the velocity dependency of E. coli retention and release parameters in saturated porous media.[J]. Science of the Total Environment, 2017,603-604:406-415.
[38]
Hong Z, Zhao G, Chen W, et al. Effects of solution chemistry on bacterial adhesion with phyllosilicates and goethite explained by the extended DLVO theory[J]. Geomicrobiology Journal, 2014,31(5):419-430.
[39]
Syngouna V I, Chrysikopoulos C V. Interaction between viruses and clays in static and dynamic batch systems[J]. Environmental science & technology, 2010,44(12):4539-4544.
[40]
Eric M V Hoek, Subir Bhattacharjee, Menachem Elimelech. Effect of membrane surface roughness on colloid-membrane DLVO interactions[J]. Langmuir, 2003,19(11):4836-4847.
[41]
Attinti R, Wei J, Kniel K, et al. Virus' (MS2, phiX174, and Aichi) attachment on sand measured by atomic force microscopy and their transport through sand columns[J]. Environmental science & technology, 2010,44(7):2426.
[42]
Bai H, Cochet N, Pauss A, et al. DLVO, hydrophobic, capillary and hydrodynamic forces acting on bacteria at solid-air-water interfaces:Their relative impact on bacteria deposition mechanisms in unsaturated porous media[J]. Colloids & Surfaces B Biointerfaces, 2016,150:41-49.
[43]
Olson M S, Ford R M, Smith J A, et al. Quantification of bacterial chemotaxis in porous media using magnetic resonance imaging[J]. Environmental science & technology, 2004,38(14):3864-3870.
Wang K, Zhao Y, Yang Z, et al. Concentration and characterization of groundwater colloids from the northwest edge of Sichuan basin, China[J]. Colloids & Surfaces A Physicochemical & Engineering Aspects, 2018:537:85-91.
Kvitsand H M L, Ilyas A, ØSTERHUS S W. Rapid bacteriophage MS2transport in an oxic sandy aquifer in cold climate:Field experiments and modeling[J]. Water Resources Research, 2015,51(12):9725-9745.
[53]
Gannon J T, Manilal V B, Alexander M. Relationship between cell surface properties and transport of bacteria through soil[J]. Applied & Environmental Microbiology, 1991,57(1):190-193.
[54]
Brusseau M L. Factors influencing the transport and fate of contaminants in the subsurface[J]. Journal of Hazardous Materials, 2015,32(2/3):137-143.
[55]
Pelley A J, Tufenkji N. Effect of particle size and natural organic matter on the migration of nano-and microscale latex particles in saturated porous media[J]. Journal of Colloid & Interface Science, 2008,321(1):74-83.
[56]
Knappett P S, Emelko M B, Zhuang J, et al. Transport and retention of a bacteriophage and microspheres in saturated, angular porous media:effects of ionic strength and grain size[J]. Water Research, 2008, 42(16):4368-4378.
[57]
Haznedaroglu B Z, Zorlu O, Hill J E, et al. Identifying the role of flagella in the transport of motile and nonmotile Salmonella enterica serovars[J]. Environmental science & technology, 2010,44(11):4184-4190.
[58]
Kokkinos P, Syngouna V I, Tselepi M A, et al. Transport of Human Adenoviruses in Water Saturated Laboratory Columns[J]. Food & Environmental Virology, 2015,7(2):122-131.
[59]
Vasiliadou I A, Chrysikopoulos C V. Cotransport of Pseudomonas putida and kaolinite particles through water-saturated columns packed with glass beads[J]. Water Resources Research, 2011,47(2):2144-2150.
[60]
Masciopinto C, Visino F. Strong release of viruses in fracture flow in response to a perturbation in ionic strength:Filtration/retention tests and modeling.[J]. Water Research, 2017:126:240-251.
[61]
Sasidharan S, Bradford S A, Torkzaban S, et al. Unraveling the complexities of the velocity dependency of E. coli retention and release parameters in saturated porous media.[J]. Science of the Total Environment, 2017,603-604:406-415.
[62]
Kim H N, Bradford S A, Walker S L. Escherichia coli O157:H7Transport in Saturated Porous Media:Role of Solution Chemistry and Surface Macromolecules[J]. Environmental science & technology, 2009,43(12):4340-4347.
[63]
Zhang H, Nordin N A, Olson M S. Evaluating the effects of variable water chemistry on bacterial transport during infiltration[J]. Journal of contaminant hydrology, 2013,150(150C):54-64.
[64]
And G C, Walker S L. Role of solution chemistry and ion valence on the adhesion kinetics of groundwater and marine bacteria[J]. Langmuir, 2007,23(13):7162-7169.
[65]
Kerchove A J D, Elimelech M. Formation of polysaccharide gel layers in the presence of Ca2+ and K+ ions:measurements and mechanisms[J]. Biomacromolecules, 2007,8(1):113-121.
[66]
Kim H N, Walker S L. Escherichia coli transport in porous media:influence of cell strain, solution chemistry, and temperature[J]. Colloids & Surfaces B Biointerfaces, 2009,71(1):160-167.
[67]
Chrysikopoulos C V, Aravantinou A F. Virus attachment onto quartz sand:Role of grain size and temperature[J]. Journal of Environmental Chemical Engineering, 2014,2(2):796-801.
[68]
Yang H, Kim H, Tong M. Influence of humic acid on the transport behavior of bacteria in quartz sand[J]. Colloids & Surfaces B Biointerfaces, 2012,91(3):122-129.
[69]
Dong Z, Yang H, Wu D, et al. Influence of silicate on the transport of bacteria in quartz sand and iron mineral-coated sand[J]. Colloids & Surfaces B Biointerfaces, 2014,123:995-1002.
[70]
Bozorg A, Gates I D, Sen A. Impact of biofilm on bacterial transport and deposition in porous media[J]. Journal of Contaminant Hydrology, 2015,183:109-120.
[71]
Vasiliadou I A, Chrysikopoulos C V. Co-transport of Pseudomonas putida and kaolinite colloid particles through water saturated columns packed with glass beads[J]. Water Resources Research, 2011, 47(2):2144-2150.
[72]
Chattopadhyay S, Puls R W. Forces dictating colloidal interactions between viruses and soil[J]. Chemosphere, 2000,41(8):1279-1286.
[73]
Balkhair K S. Modeling fecal bacteria transport and retention in agricultural and urban soils under saturated and unsaturated flow conditions[J]. Water Research, 2017,110:313-320.
[74]
Haznedaroglu B Z, Kim H N, Bradford S A, et al. Relative transport behavior of Escherichia coli O157:H7 and Salmonella enterica serovar pullorum in packed bed column systems:influence of solution chemistry and cell concentration[J]. Environmental science & technology, 2009,43(6):1838-1844.
[75]
Zhang W, Morales V L, Cakmak M E, et al. Colloid transport and retention in unsaturated porous media:effect of colloid input concentration[J]. Environmental science & technology, 2010,44(13):4965-4972.
[76]
Gharabaghi B, Safadoust A, Mahboubi A A, et al. Temperature effect on the transport of bromide and E. coli, NAR in saturated soils[J]. Journal of Hydrology, 2015,522:418-427.
[77]
Drobek T, And N D S, Heuberger M. Compressing PEG Brushes[J]. Macromolecules, 2005,38(12):5254-5259.
[78]
Grna H, Lawniczak L, Zgo?a-grze?kowiak A, et al. Differences and dynamic changes in the cell surface properties of three Pseudomonas aeruginosa strains isolated from petroleum-polluted soil as a response to various carbon sources and the external addition of rhamnolipids[J]. Bioresource Technology, 2011,102(3):3028-3033.
[79]
Zhang Y, Miller R M. Effect of a Pseudomonas rhamnolipid biosurfactant on cell hydrophobicity and biodegradation of octadecane[J]. Applied & Environmental Microbiology, 1994,60(6):2101-2106.
[80]
Chen G, Qiao M, Zhang H, et al. Bacterial desorption in water-saturated porous media in the presence of rhamnolipid biosurfactant[J]. Research in Microbiology, 2004,155(8):655-661.
Anders R, Chrysikopoulos C V. Transport of viruses through saturated and unsaturated columns packed with sand[J]. Transport in Porous Media, 2009,76(1):121-138.
[84]
Sadeghi G, Schijven J F, Behrends T, et al. Systematic Study of Effects of pH and Ionic Strength on Attachment of Phage PRD1[J]. Groundwater, 2011,49(1):12-19.
[85]
Baygents J C, Jr J R G, Albinger O, et al. Variation of Surface Charge Density in Monoclonal Bacterial Populations:Implications for Transport through Porous Media[J]. Environmental science & technology, 1998,32(11):1596-1603.
[86]
Schinner T, Letzner A, Liedtke S, et al. Transport of selected bacterial pathogens in agricultural soil and quartz sand[J]. Water Research, 2010,44(4):1182-1192.
[87]
Huysman F, Verstraete W. Water-facilitated transport of bacteria in unsaturated soil columns:Influence of cell surface hydrophobicity and soil properties[J]. Soil Biology & Biochemistry, 1993,25(1):83-90.
[88]
Brown D G, Al Nuaimi K S. Nonionic surfactant sorption onto the bacterial cell surface:a multi-interaction isotherm[J]. Langmuir the Acs Journal of Surfaces & Colloids, 2005,21(24):11368-11372.
[89]
Zevi Y, Dathe A, Gao B, et al. Transport and retention of colloid particles in partially saturated porous media:effect of ionic strength[J]. Water Resources Research, 2009,45(12):69-76.
[90]
Zhuang J, Jin Y. Interactions between viruses and goethite during saturated flow:effects of solution pH, carbonate, and phosphate[J]. Journal of contaminant hydrology, 2008,98(1/2):15-21.
Wan J, Wilson J L. Visualization of the role of the gas-water interface on the fate and transport of colloids in porous media[J]. Water Resources Research, 1994,30(1):11-23.
[94]
Sim Y, Chrysikopoulos C V. Analytical models for virus adsorption and inactivation in unsaturated porous media[J]. Colloids & Surfaces A Physicochemical & Engineering Aspects, 1999,155(2/3):189-97.
[95]
And J W, Tokunaga T K. Film Straining of Colloids in Unsaturated Porous Media:Conceptual Model and Experimental Testing[J]. Environmental science & technology, 1997,31(8):2413-2420.
[96]
Veerapaneni S, Jiamin WAN A, Tokunaga T K. Motion of Particles in Film Flow[J]. Environmental science & technology, 2000,34(12):2465-2471.
[97]
Torkzaban S, Hassanizadeh S M, Schijven J F, et al. Role of air-water interfaces on retention of viruses under unsaturated conditions[J]. Water Resources Research, 2006,42(12):2526-2528.
[98]
Kim M Y, Kim S, Park S I. Bacteria transport in an unsaturated porous media:incorporation of air-water interface area model into transport modelling[J]. Hydrological Processes, 2010,22(13):2370-2376.
[99]
Schäfer A, Ustohal P, Harms H, et al. Transport of bacteria in unsaturated porous media[J]. Journal of Contaminant Hydrology, 1998,33(1/2):149-169.
[100]
Gómezsuárez C, Busscher H J, Mei H C V D. Analysis of bacterial detachment from substratum surfaces by the passage of air-liquid interfaces[J]. Applied & Environmental Microbiology, 2001,67(6):2531-2537.
[101]
Zhong H, Liu G, Jiang Y, et al. Effect of low-concentration rhamnolipid on transport of Pseudomonas aeruginosa ATCC 9027in an ideal porous medium with hydrophilic or hydrophobic surfaces[J]. Colloids and surfaces B, Biointerfaces, 2016,139(2):244-248.
[102]
Dan W, Lei H, Sun R, et al. Influence of Bisphenol A on the transport and deposition behaviors of bacteria in quartz sand[J]. Water Research, 2017,121:1-10.
Hornstra L M, Schijven J, Waade A, et al. Transport of bacteriophage MS2 and PRD1 in saturated dune sand under suboxic conditions[J]. Water Research, 2018,139:158-167.
[105]
Sanya S, Arturo K. Transport of colloids in saturated porous media:A pore-scale observation of the size exclusion effect and colloid acceleration[J]. Water Resources Research, 2003,39(39):1255-1256.
[106]
Huang C T, Peretti S W, Bryers J D. Use of flow cell reactors to quantify biofilm formation kinetics[J]. Biotechnology Techniques, 1992,6(3):193-198.
[107]
García López L A, Veiga M C, Nogueira R, et al. A technique using a membrane flow cell to determine average mass transfer coefficients and tortuosity factors in biofilms[J]. Water Science & Technology A Journal of the International Association on Water Pollution Research, 2003,47(5):61-67.