Tài liệu hạn chế xem trước, để xem đầy đủ mời bạn chọn Tải xuống
1
/ 199 trang
THÔNG TIN TÀI LIỆU
Thông tin cơ bản
Định dạng
Số trang
199
Dung lượng
1,91 MB
Nội dung
BIOFILM FORMATION AND CONTROL IN A MODEL DRINKING WATER DISTRIBUTION SYSTEM WITH PHOSPHORUS ADDITION FANG WEI NATIONAL UNIVERSITY OF SINGAPORE 2010 BIOFILM FORMATION AND CONTROL IN A MODEL DRINKING WATER DISTRIBUTION SYSTEM WITH PHOSPHORUS ADDITION FANG WEI (B.ENG) A THESIS SUBMITTED FOR THE DEGREE OF PHILOSOPHIAE DOCTOR DEPARTMENT OF CIVIL ENGINEERING NATIONAL UNIVERSITY OF SINGAPORE 2010 ACKNOWLEDGEMENT I would like to express my gratitude and sincere appreciation to my supervisors, Associate Professor Hu Jiangyong and Professor Ong Say Leong for their outstanding guidance, invaluable encouragement, consistent understanding, caring and patience throughout my Ph.D study Many thanks go to all technicians, staff and students, especially Mr S.G Chandrasegaran, Ms Lee Leng Leng, Ms Tan Xiaolan at the Environmental Engineering Laboratory of Division of Environmental Science and Engineering, National University of Singapore, for their assistance and cooperation in the many ways that made this research study possible My deepest gratitude is also expressed to all my family members, especially my wife Shi Rui, who gave me endless love and support; and my parents, who gave me invaluable life and edification i TABLE OF CONTENTS Pages ACKNOWLEDGEMENT i TABLE OF CONTENTS ii SUMMARY vii NOMENCLATURE xi LIST OF FIGURES xii LIST OF TABLES xv LIST OF PLATES xvi CHAPTER ONE INTRODUCTION 1.1 Background 1.2 Objective and Scope of Study .5 1.3 Outline of Thesis CHAPTER TWO LITERATURE REVIEW .8 2.1 Overview of Biofilm Community 2.1.1 Biofilm Formation 2.1.2 Biofilm Compositions .12 2.1.3 Exopolysaccharides (EPS) and Biofilm Structure 14 2.2 Biofilm Formation in Drinking Water Distribution System (DWDS) 19 2.2.1 Development of Biofilm in DWDS 20 2.2.2 Biofilm-related Problems in DWDS 22 2.3 Biofilm Control in DWDS 23 ii 2.3.1 Mechanisms of Disinfection .25 2.3.2 Free Chlorine and Monochloramine Disinfections 27 2.3.3 Efficacies of Free Chlorine and Monochloramine Disinfections 28 2.3.4 Disinfection Resistance of Biofilm Cells 31 2.4 Effects of Nutrient Condition on Biofilm Formation in DWDS .33 2.4.1 Carbon-limiting and Phosphorus-limiting DWDS 34 2.4.2 Use of Orthophosphate as Corrosion Inhibitor 37 2.4.3 Potential Biological Effects of Addition of Phosphorus in DWDS 38 2.5 Current Status and Research Needs 43 CHAPTER THREE MATERIALS AND METHODS 49 3.1 Introduction 49 3.2 Experimental Setup .50 3.2.1 Annular Reactor System 50 3.2.2 Feed Water 52 3.2.3 Nutrient Stock 53 3.2.4 Free Chlorine Disinfection 53 3.2.5 Monochloramine Disinfection 53 3.3 Sampling and Analysis 54 3.3.1 Sampling Method 54 3.3.1.1 Water Sample 54 iii 3.3.1.2 Biofilm Sample .55 3.3.2 Water Sample Analysis .56 3.3.2.1 Heterotrophic Plate Count (HPC) 56 3.3.2.2 Free Chlorine 57 3.3.2.3 Monochloramine .57 3.3.2.4 pH and Temperature 57 3.3.2.5 Assimilable Organic Carbon (AOC) .57 3.3.2.6 Ion 58 3.3.3 Biofilm Sample Analysis 59 3.3.3.1 HPC 59 3.3.3.2 Total Carbohydrate Content (TCC) .59 3.3.3.3 Confocal Laser Scanning Microscopy (CLSM) .60 3.3.3.4 GN2 Microplate Community Level Assay .62 3.3.3.5 Fluorescence in Situ Hybridization (FISH) 66 3.3.3.6 Terminal Restriction Fragment Length Polymorphism (TRFLP) 68 3.3.4 Statistical Analysis 73 CHAPTER FOUR RESULTS AND DISCUSSIONS .74 4.1 Introduction 74 4.2 Effects of Phosphorus Addition on Microbial Growth .74 4.2.1 Biofilm and Planktonic Cell Growth 74 4.2.2 Biofilm EPS Quantity .80 iv 4.2.3 Biofilm Morphology and Structure 84 4.3 Effects of Phosphorus Addition on Disinfection Efficacy 90 4.3.1 Biofilm Development before Disinfections 90 4.3.2 Effects of Disinfection on Biofilm Cell Number 90 4.3.3 Effects of Disinfection on Biofilm EPS Quantity .96 4.3.4 Effects of Disinfection on Biofilm Morphology and Structure 101 4.3.5 Effects of Disinfection on Planktonic Growth 113 4.4 Effects of Phosphorus Addition on Biofilm Metabolic Potential 116 4.4.1 Substrate Utilization Pattern (SUP) 116 4.4.1.1 Phosphorus Addition 116 4.4.1.2 Free Chlorine Disinfection 119 4.4.1.3 Monochloramine Disinfection 123 4.4.2 Substrate Utilization Diversity 126 4.4.3 Metabolic Potential 128 4.4.4 Similarity of Metabolic Activity .129 4.5 Effects of Phosphorus Addition on Biofilm Community Structure 131 4.5.1 FISH 131 4.5.2 TRFLP .136 4.5.2.1 TRLFP Profiles .136 4.5.2.2 Phylogenetic Assignments 143 CHAPTER FIVE CONCLUSIONS AND RECOMMENDATIONS 147 v 5.1 Conclusions .147 5.2 Recommendations .149 REFFERENCES 151 PUBLICATIONS 180 vi SUMMARY Microbial regrowth is an important issue in drinking water distribution system (DWDS) management Biofilm formation on the internal surface of pipeline becomes a great concern as the majority of the microbial growth in DWDS is associated with biofilm development and biofilms are much more disinfectant resistant than their planktonic counterparts Biofilm formation in DWDS can be affected by various factors such as availability of nutrients, presence of disinfectants, pipeline materials, temperature and water flow rate, etc Phosphorus has been recently identified as another limiting nutrient other than organic carbon to microbial growth in DWDS As a commonly used corrosion inhibitor, phosphate is frequently introduced into DWDS and causes the increase of phosphorus concentration Phosphorus addition to DWDS has potential to increase the microbial growth and change the community structure However, the effects of phosphorus on biofilm formation in DWDS are still not well understood The purpose of this study is to provide an in-depth understanding of the biofilm formation and control in DWDS when phosphorus addition is implemented Annular reactors were used to simulate DWDS Phosphorus addition (3 µg l-1, 30 µg l-1 and 300 µg l-1 of phosphorus) was found to have a complicated effect on biofilm formation (especially for 30 µg l-1 and 300 µg l-1 of phosphorus vii additions) Phosphorus addition can promote the biofilm cell growth (cell count increased by about log with addition of 30 µg l-1 and 300 µg l-1 of phosphorus.) However, the addition of 30 µg l-1 and 300 µg l-1 of phosphorus caused decrease in exopolysaccharides (EPS) quantity by 81% and 77%, respectively The results of biofilm structure analysis showed that the addition of 30 µg l-1 and 300 µg l-1 of phosphorus induced thicker and less homogeneous biofilms with more biomass The addition of µg l-1 of phosphorus, on the other hand, was found to have minor effects on the above parameters examined The results in this study confirmed that the addition of phosphorus to DWDS has a potential to increase the bacterial cell number and deteriorate the drinking water quality In the biofilm control study, free chlorine and monochloramine were used as disinfectants The disinfection efficacies of both free chlorine and monochloramine were increased when phosphorus was added into the reactor systems At the same disinfectant dosages, monochloramine showed greater biofilm removal efficiency than free chlorine (0.86 and 1.32 log cell number reduction for 0.5 mg l-1 and mg l-1 free chlorine disinfections and 2.13 and 2.96 log cell number reduction for 0.5 mg l-1 and mg l-1 monochloramine disinfections) Except the control conditions with free chlorine disinfection, EPS quantities were generally increased when disinfectants were applied (13 and 22 times increases for phosphorus treatment condition with 0.5 mg l-1 and viii References Lu C., Biswas, P and Clark, R.M (1995) Simultaneous transport of substrates, disinfectants and microorganisms in water pipes Wat Res., 29(3), 881-894 Lu, W., Kiêné, L and Levi, Y (1999) Chlorine demand of biofilms in water distribution systems Water Res 33(3), 827-835 Mah, T.C., and O’Toole, G.A (2001) Mechanisms of biofilm resistance to antimicrobial agents Trends in Microbiology 9(1), 34-39 Mallory, L.M., and Saylor, G S (1984) Application of FAME (fatty acid methyl ester) analysis in the numerical taxonomic determination of bacterial guild structure Microb Ecol 10(3), 283-296 Manz, W., Szewzyk, U., Ericsson, P., Amann, R., Schleifer, K.H and Stenstrom, T.A (1993) In situ identification of bacteria in drinking water and adjoining biofilms by hybridization with 16S and 23S rRNA-directed fluorescent oligonucleotide probes Appl Environ Microbiol., 59(7), 2293-2298 Martiny, A.C., Jorgensen, T.M., Albrechtsen, H.-J., Arvin, E and Molin, S (2003) Long-term succession of structure and diversity of a biofilm formed in a model drinking water distribution system Appl Environ Microbiol 69(11), 167 References 6899-6907 McCann M.P., Kidwell, J.P and Matin, A (1991) The putative sigma factor KatF has a central role in development of starvation-mediated general resistance in Escherichia coli., J Bacteriol., 173(13), 4188-4194 McLean, R.J.C., Whiteley, M., Stickler, D.J and Fuqua, W.C (1997) Evidence of autoinducer activity in naturally occurring biofilms FEMS Microbiology Letters 154(2), 259-263 McNeill, L and Edwards, M (2002) Phosphate inhibitor use at US utilities J Am Water Works Assoc 94(7), 57-63 Merritt, K and An, Y.H (2000) Factors influencing bacterial adhesion In Handbook of Bacterial Adhesion: Principles, Methods and Applications, eds An, Y.H and Friedman, R.J, Humana Press: Totowa, NJ, 1-27 Meyer, B (2003) Approaches to prevention, removal and killing of biofilms International Biodeterioration & Biodegradation 51(4), 249-253 Miettinen, I.T., Vartiainen, T and Martikainen, P.J (1997) Phosphorus and bacterial growth in drinking water Appl Environ Microbiol 63(8), 3242-3245 168 References Møller, S., Korber, D.R., Wolfaardt, G.M., Molin, S and Caldwell, D.E (1997) Impact of nutrient composition on a degradative biofilm community Appl Environ Microbiol 63(6), 2432-2438 Momba, M.N.B., Cloete, T.E., Venter, S.N and Kfir, R (1999) Examination of the behaviour of Escherichia coli in biofilms established in laboratory-scale units receiving chlorinated and chloraminated water Wat Res 33(13), 2937-2940 Morin, P., Gauthier, V., Saby, S and Block, J.–C (1999) Bacterial resistance to chlorine through attachment to particles and pipe surfaces in drinking water distribution systems In Biofilms in the aquatic environment ed by C.W Kevil et al., Cambridge university press 171-190 Mott, I.E.C., Stickler, D.J., Coakley, W.T and Bott, T.R (1998) The removal of bacterial biofilm from water-filled tubes using axially propagated ultrasound Journal of Applied Microbiology 84(4), 509-514 Nagy, L.A., Kelly, A.J., Thun, M.A and Olson, B.H (1982) Biofilm composition, formation and control in the Los Angeles aqueduct system In Proceedings of the American Water Works Association Water Quality Technology Conference, pp.141-160 169 References Nagy, L.A., and Olson, B.H (1985) Occurrence and significance of bacteria, fungi and yeasts associated with distribution pipe surfaces In Proceedings of the American Water Works Association Water Quality Technology Conference, pp 213-238 Nielsen, A.T., Tolker-Nielsen, T., Barken, K.B and Molin, S (2000) Role of commensal relationships on the spatial structure of a surface-attached microbial consortium Environ Microbiol 2(1), 59-68 Norton, C.D and LeChevallier, M.W (2000) A pilot study of bacteriological population changes through potable water treatment and distribution Appl Environ Microbiol., 66(1), 268-276 Norton, C.D., LeChevallier, M.W., Falkinham III, J.O (2004) Survival of Mycobacterium avium in a model distribution system Water Res 38(6), 1457-1466 Nyvad, B and Fejerskov, O (1997) Assessing the stage of caries lesion activity on the basis of clinical and microbiological examination, Commun Dent Oral Epidem., 25(1), 69-75 O'Toole, G.A and Kolter, R (1998) Flagellar and twitching motility are 170 References necessary for Pseudomonas aeruginosa biofilm development Mol Microbiol 30(2), 295-305 Oliver, J.D (1993) Formation of viable but nonculturable cells In: Starvation in Bacteria Plenum Press, New York, 239-272 Ollos, P.J., Slawson, R.M and Huck, P.M (1998) Bench scale investigations of bacterial regrowth in drinking water distribution systems, Wat Sci Tech., 38(8-9), 275-282 Park, S.K and Kim, Y.K (2008) Effect of chloramine concentration on biofilm maintenance on pipe surfaces exposed to nutrient-limited drinking water Water SA, 34(3), 337-380 Park, S.K., Lee, S.H., Choi, S.C and Kim, Y.K (2006) Characteristics of biofilm community formed in the chlorinated biodegradable organic matter-limited tap water Environmental Technology 27(4), 377-386 Percival, S.L and Walker, J.T (1999) Potable water and biofilms: A review of public health implications Biofouling 14(2), 99-115 Pfiffner, S.M., Palumbo, A.V., Phelps, T.J and Hazen, T.C (1997) Effects of 171 References nutrients dosing on subsurface methanotrophic populations and trichloroethylene degradation Journal of Industrial Microbiology and Biotechnology 18(2-3), 204-212 Pratt, L.A and Kolter, R (1998) Genetic analysis of Escherichia coli biofilm formation: roles of flagella, motility, chemotaxis and type I pili Mol Microbiol 30(2), 285-293 Rao, T.S., Nancharaiah, Y.V and Nair, K.V.K (1998) Biocidal efficacy of monochloramine against biofilm bacteria Biofouling, 12(4), 321-332 Ridgway, H.F., Justice, C.A., Whittaker, C., Argo, D.G and Olson, B.H (1984) Biofilm fouling of RO membranes – its nature and effect on treatment of water for reuse., J Am Water Works Assoc., 76(6), 94-102 Roberson, E.B and Firestone, M.K (1992) Relationship between desiccation and exopolysaccharide production in a soil Pseudomonas sp., Appl Environ Microbiol., 58(4), 1284-1291 Robinson, J.A., Trulear, M.G and Characklis, W.G (1984) Cellular reproduction and extracellular polymer formation by Pseudomonas aeruginosa in continuous culture Biotechnol Bioeng 26(12), 1409-1417 172 References Rompre, A., Prevost, M., Coallier, J., Brisebois, P and Lavole, J (2000) Impacts of implementing a corrosion strategy on biofilm growth Wat Sci Tech 41(4-5), 287-294 Rosenberg, H (1987) Phosphate transport in prokaryotes In: Rosen BP, Silver S, editors Ion transport in prokaryotes New York: Academic Press Rowbotham, T.J (1980) Preliminary report on the pathogenicity of Legionella pneumophila for freshwater and soil amoeba J Clin Pathol 33, 1179-1183 Samrakandi, M.M., Roques, C and Michel, G (1997) Influence of trophic conditions on exopolysaccharide production: bacterial biofilm susceptibility to chlorine and monochloramine Canadian Journal of Microbiology, 43(8), 751-758 Sathasivan, A and Ohgaki, S (1999) Application of new bacterial growth potential method for drinking water distribution system-a clear evidence of phosphorus Water Research 33(1), 137-144 Seidler, R.J., Morrow, J.E and Bagley, S.T (1977) Klebsielleae in drinking water emanating from redwood tanks, Appl Environ Microbiol, 33(4), 893-900 173 References Servais, P., Laurent, P and Randon, G (1995) Comparison of the bacterial dynamics in various french distribution systems J Water SRT Aqua 44(1), 10–17 Sibille, I., Mathieu, L., Paquin, J.L., Gatel, D and Block, J.C (1997) Microbial characteristics of a distribution system fed with nanofiltered drinking water Water Res., 31(9), 2318-2326 Simoes, M., Pereira, M.O and Vieira M.J (2005) Action of a cationic surfactant on the activity and removal of bacterial biofilms formed under different flow regimes Water Res., 39(2-3), 478-486 Steinert, M., Hentschel, U and Hacker, J (2002) Legionella pneumophila: an aquatic microbe goes astray FEMS Microbiol Rev 26(2), 149-162 Stickler, D (1999) Biofilms Current Opinion in Microbiology 2(3), 270-275 Storey, M.V and Ashbolt, N.J (2001) A Comparison of Methods and Models for Analysis of Water Distribution Pipe Biofilm, IWA 2nd world water congress, Berline, 15-19 Stringer R and Johnston, P (eds) (2001) Chlorine and the environment green 174 References peace research laboratories, University of Exeter, Exeter, U.K, pp.53 Sutherland, I.W (1999) Polysaccharases for microbial exopolysaccharides Carbohydrate Polymers 38(4), 319-328 Sutherland, I.W (2001) Biofilm exopolysaccharides: a strong and sticky framework Microbiology 147, 3-9 Turakhia, M.H and Characklis, W.G (1988) Activity of Pseudomonas aeruginosa in biofilms: effect of calcium Biotechnol Bioeng 33(4), 406-414 Turetgen, I (2004) Comparison of the efficacy of free residual chlorine and monochloramine against biofilms in model and full scale cooling towers Biofouling, 20(2), 81-85 United States Environmental Protection Agency (USEPA) (1992) Seminar publication: Control of biofilm growth in drinking water distribution systems EPA/625/R-92/001, Office of Research and Development, Washington, D.C USEPA (1999) Alternative disinfectants and oxidants guidance manual Van der Kooij, D (1990) Assimilable organic carbon (AOC) in drinking water 175 References In: McFeters, G.A (Ed.), Drinking Water Microbiology Springer-Verlay, New York 57-87 Van der Wende, E., Characklis, W.G and Smith, D.B (1989) Biofilms and bacterial drinking water quality Water Res 23(10), 1313–1322 Van Loosdrecht, M.C.M., Eikelboom, D., Gjaltema, A., Mulder, A., Tijhuis, L and Heijnen, J.J (1995) Biofilm structures Water Sci Technol 32(8), 35-43 Volk, C.J and LeChevallier, M.W (1999) Impacts on the reduction of nutrient levels on bacterial water quality in distribution systems Appl Environ Microbiol., 65(11), 4957-4966 Watnick, P and Kolter, R (2000) Biofilm, city of microbes J Bacteriol 182(10), 2675-2679 Watnick, P.I and Kolter, R (1999) Steps in the development of a Vibrio cholerae biofilm Mol Microbiol 34(3), 586-595 White, G.C (1972) Handbook of chlorination for potable water, wastewater, cooling water, industrial processes, and swimming pools, Van Nostrand Reinhold, New York 176 References Wimpenny, J (2000) An overview of biofilms as functional communities In Community structure and co-operation in biofilms, ed by D.G Allison, P Gilbert, H.M Lappin-Scott and M Wilson, Camvbridge university press, 1-24 Wimpenny, J., Manz, W., Szewzyk, U (2000) Heterogeneity in biofilms FEMS Microbiology Reviews 24(5), 661-671 Wimpenny, J.W.T and Colasanti, R (1997) A unifying hypothesis for the structure of microbial biofilms based on cellular automaton models FEMS Microbiology Ecology 22(1), 1-16 Wolfaardt, G.M., Lawrence, J.R., Robarts, R.D., Caldwell, S.J and Caldwell, D.E (1994) Multicellular organization in a degradative biofilm community Appl Environ Microbiol 60(2), 434-446 Wood, P., Caldwell, D.E., Evans, E., Jones, M., Korber, D.R., Wolfhaardt, G.M., Wilson, M and Gilbert, P (1998) Surface-catalysed disinfection of thick Pseudomonas aeruginosa biofilms Journal of Applied Microbiology 84(6), 1092-1098 Wood, P., Jones, M., Bhakoo, M and Gilbert, P (1996) A novel strategy for 177 References control of microbial biofilms through generation of biocide at the biofilm-surface interface Appl Environ Microbiol 62(7) 2598-2602 Wünsche L., Brüggemann L and Babel W (1995) Determination of substrate utilization patterns of soil microbial communities: an approach to assess population changes after hydrocarbon pollution FEMS Microbiol Ecol 17(4), 295-306 Xue, G.B (ed) (1986) Practical disinfection method (SHIYONG XIAODUXUE) Beijing: People’s Surgical publisher Yun, M.A., Yeon, K.M., Park, J.S., Lee, C.H., Chun, J and Lim, D.J (2006) Characterization of biofilm structure and its effect on membrane permeability in MBR for dye wastewater treatment Water Res., 40(1), 45-52 Zak, J.C., Willig, M.R., Moorhead, D.L and Wildman, H.G (1994) Functional diversity of microbial communities: a quantitative approach Soil Biol Biochem., 26(9), 1101-1108 Zhang, X.Q., Bishop, P.L and Kupferle, M (1998) Measurement of polysaccharides and protein in biofilm extracellular polymers Wat Sci Tech., 37(4), 345-348 178 References Zhou, L.L., Zhang, Y.J and Li, G.B (2009) Effects of pipe materials and low level disinfectants on biofilm development in a simulated drinking water distribution system Journal of Zhejiang University Science A, 10(5), 725-731 179 Publications PUBLICATIONS Hu, J.Y., Yu, B and Fang, W (2006) Use of Live/Dead staining for quantifying biofilm bacterial viability Advances in Asian Environmental Engineering, 5(1), 25-30 Fang, W., Hu, J.Y and Ong, S.L (2007) Effects of environmental stress conditions on Pseudomonas Aeruginosa biofilm Advances in Asian Environmental Engineering, 6(1), 25-30 Hu, J.Y., Fang, W and Yu, B (2008) Biofilm control using chlorine-based disinfectants in model drinking water distribution systems Water Science and Technology: Water Supply, 8(5), 489-497 Fang, W., Hu, J.Y and Ong, S.L (2009) Influence of phosphorus on biofilm formation in model drinking water distribution systems Journal of Applied Microbiology, 106(4), 1328-1335 Fang, W., Hu, J.Y and Ong, S.L (2010) Effects of phosphorus on biofilm disinfections in model drinking water distribution systems Journal of Water and Health, 8(3), 446-454 Hu, J.Y., Fang, W and Ong, S.L (2011) Evaluation of metabolic activity and 180 Publications community structure of drinking water biofilm with the addition of phosphorus and disinfection treatments In preparation 181 ... formation of microbial aggregates, attachment to surfaces, structural stability and spatial arrangement of biofilm structure and serve as a protective barrier against desiccation and retards access... Biofilm formation begins with the attachment of free-floating bacterial cells to a surface And this attachment is followed by growth into a mature, structurally complex biofilm and culminates in the... of phosphorus to DWDS has a potential to increase the bacterial cell number and deteriorate the drinking water quality In the biofilm control study, free chlorine and monochloramine were used as