References

1. Calleja, G.B., Cell aggregation, in The Yeasts, A.H. Rose and J.S. Harrison, Eds, Academic Press Inc., London, UK, pp. 165-237, 1987.

2. Mikkelsen, L.H. and Keiding, K., Equilibrium aspects of the effects of shear and solids content on aggregate deflocculation, Adv. Colloid Interface Sci., 80, 151-182, 1999.

3. Mikkelsen, L.H. and Keiding, K., The shear of activated sludge: an evaluation of the possibility for a standardised floc strength test, Water Res., 36, 2931-2940, 2002.

4. Biggs, C.A. and Lant, P.A., Activated sludge flocculation: on-line determination of floc size and the effect of shear, Water Res., 34(9), 2542-2550, 2000.

5. Chaignon, V., Lartiges, B.S., El Samrani, A., and Mustin, C., Evolution of size distribution and transfer of mineral particles between flocs in activated sludge: an insight into floc exchanges dynamics, Water Res., 36, 676-684, 2002.

6. Glasgow, L.A. and Luecke, R.H., Mechanisms of deaggregation for clay-polymer flocs in turbulent systems, Ind. Eng. Chem. Fundam., 19, 148-156, 1980.

7. Liu, S.X. and Glasgow, L.A., Aggregate disintegration in turbulent jets, Water Air Soil Pollut., 95, 257-275, 1997.

8. Ellis, C.E. and Glasgow, L.A., Deformability and breakage of flocs, Adv. Environ. Res., 3(1), U2-27, 1999.

9. Glasgow, L.A., Deformation of individual aggregates and flocs, J. Disper. Sci. Technol., 24(5), 715-720, 2003.

10. Berkeley, R.C.W., Lynch, J.M., Melling, J., Rutter, P.R., and Vincent, B., Eds., Microbial Adhesion onto Surfaces, Ellis Horwood Ltd., Chichester, West Sussex, England, 1980.

11. Fletcher, M., Bacterial attachment in aquatic environments: a diversity of surfaces and adhesion strategies, in Bacterial Adhesion: Molecular and Ecological Diversity, M. Fletcher, Ed., Wiley-Liss, Inc., New York, pp. 1-24, 1996.

12. Marshall, K.C., Ed., Report on the Dahlem Workshop on Microbial Adhesion and Aggregation, Life Sciences Research Reports, S. Bernhard, Ed., Springer-Verlag, Berlin, Germany, 1984.

13. Irvine, R.L., Wilderer, P.A., andFlemming, H.-C., Controlled unsteady state processes and technologies — An overview, Water Sci. Technol., 35(1), 1-10, 1997.

14. Majone, M., Dircks, K., and Beun, J.J., Aerobic storage under dynamic conditions in an activated sludge processes. The state of the art, Water Sci. Technol., 39(1), 61-73, 1999.

15. Daigger, G.T. and Grady, C.P.L.J., The dynamics of microbial growth on soluble substrates. A unifying theory, Water Res., 16(4), 365-382, 1982.

16. Lishman, L.A., Legge, R.L., and Farquhar, G.J., Temperature effects on wastewater treatment under aerobic and anoxic conditions, Water Res., 34(8), 2263-2276, 2000.

17. Neubauer, P., Haggstrom, L., and Enfors, S.-O., Influence of substrate oscillations on acetate formation and growth yield in Escherichia coli glucose limited fed-batch cultivations, Biotechnol. Bioeng., 47(2), 139-146, 1995.

18. Majone, M., Massanisso, P., and Ramadori, R., Comparison of carbon storage under aerobic and anoxic conditions, Water Sci. Technol., 38(8-9), 77-84, 1998.

19. Barbusinski, K. and Koscielniak, H., Influence of substrate loading intensity on the floc size in activated sludge process, Water Res., 29(7), 1703-1710, 1995.

20. Grau, P., Chudoba, J., and Dohanyos, M., Theory and practice of accumulation-regeneration approach to the control of activated sludge filamentous bulking, in Bulking of Activated Sludge: Preventative and Remedial Methods, B. Chambers and

E.J. Tomlinson, Eds, Ellis Horwood Limited, Chichester, West Sussex, England, pp. 111-122, 1982.

21. Farrugia, V.M., The development and properties of biofilms in biofilters, Master of Applied Science thesis, Department of Chemical Engineering and Applied Chemistry, University of Toronto, Ontario, Canada, 1999.

22. LeBlanc, M.-A., Control of filamentous bulking and oxygen transfer in a pulp and paper sequential batch reactor (SBR), in Proc. Int. Environ. Conf. Exhibit, TAPPI Press, Vancouver, British Columbia, 1998.

23. Krishna, C. and Van Loosdrecht, M.C.M., Effect of temperature on storage polymers and settleability of activated sludge, Water Res., 33(10), 2374-2382, 1999.

24. Thompson, G., Swain, J., Kay, M., and Forster, C.F., The treatment of pulp and paper mill effluent: a review, Bioresour. Technol., 77, 275-286, 2001.

25. Borja, R. and Banks, C.J., Response of an anaerobic fluidized bed reactor treating icecream wastewater to organic, hydraulic, temperature and pH shocks, J. Biotechnol., 39, 251-259, 1995.

26. Paula Jr., D.R. and Foresti, E., Kinetic studies on a UASB reactor subjected to increasing COD concentration, Water Sci. Technol., 25(7), 103-111, 1992.

27. Nachaiyasit, S. and Stuckey, D.C., The effect of shock loads on the performance of an anaerobic baffled reactor (ABR). 1. Step changes in feed concentration at constant retention time, Water Res., 31(11), 2737-2746, 1997.

28. Nachaiyasit, S. and Stuckey, D.C., The effect of shock loads on the performance of an anaerobic baffled reactor (ABR). 2. Step and transient hydraulic shocks at constant feed strength, Water Res., 31(11), 2747-2754, 1997.

29. Xing, J., Criddle, C., and Hickey, R., Effects of a long-term periodic substrate perturbation on an anaerobic community, Water Res., 31(9), 2195-2204, 1997.

30. Syutsubo, K., Sinthurat, N., Ohashi, A., and Harada, H., Population dynamics of anaerobic microbial consortia in thermophilic granular sludge in response to feed composition change, Water Sci. Technol., 43(1), 59-66, 2001.

31. Pereira, M.A., Roest, K., Stams, A.J.M., Akkermans, A.D.L., Amaral, A.L., Pons, M.-N., Ferreira, E.C., Mota, M., and Alves, M.M., Image analysis, methanogenic activity measurements, and molecular biological techniques to monitor granular sludge from an EGSB reactor fed with oleic acid, Water Sci. Technol., 47(5), 181-188, 2003.

32. Henriques Callado, N. and Foresti, E., Response of an upflow anaerobic sludge blanket reactor to increasing sulfate concentrations, in Proc. 47th Industr. Waste Conf., Lewis Publishers, Purdue University, West Lafayette, IN, 1992.

33. Hall, E.R., Melcer, H., Cornacchio, L.-A., and Jones, R.M., Anaerobic treatment for pulp and paper wastewaters, in Anaerobic Treatment of Industrial Wastewaters, M.F. Torpy, Ed., Noyes Data Corporation, Park Ridge, NJ, pp. 15-22, 1988.

34. Gross, R.L. and Lanting, J., Anaerobic wastewater treatment of a fuel ethanol facility, in Anaerobic Treatment of Industrial Wastewaters, M.F. Torpy, Ed., Noyes Data Corporation, Park Ridge, NJ, pp. 23-34, 1988.

35. Van Loosdrecht, M.C.M. and Henze, M., Maintenance, endogenous respiration, lysis, decay and predation, Water Sci. Technol., 39(1), 107-117, 1999.

36. Archibald, F. and Young, F. Common stresses affecting activated sludge health and performance — What the four-assay set can tell us, in Proc. Int. Environ. Conf. Exhibit, TAPPI Press, Montreal, Quebec, Canada, 2002.

37. Dikshitulu, S., Baltzis, B.C., and Lewandowski, G.A., Competition between two microbial populations in a sequencing fed-batch reactor: theory, experimental verification, and implications for waste treatment applications, Biotechnol. Bioeng., 42(5), 643-656, 1993.

Lenas, P., Baltzis, B.C., Lewandowski, G.A., and Ko, Y.-F., Biodegradation of wastes in a cyclically operated reactor: theory, experimental verification and optimization studies, Chem. Eng. Sci., 49(24A), 4547-4561, 1994.

Stephanopoulos, G., Fredrickson, A.G., and Aris, R., The growth of competing microbial populations in a CSTR with periodically varying inputs, AIChEJ., 25(5), 863-872, 1979.

Fernandez, A.S., Hashsham, S.A., Dollhopf, S.L., Raskin, L., Glagoleva, O., Dazzo, F.B., Hickey, R.F., Criddle, C.S., and Tiedje, J.M., Flexible community structure correlates with stable community function in methanogenic bioreactor communities perturbed by glucose, Appl. Environ. Microbiol., 66(9), 4058-4067, 2000.

Hashsham, S.A., Fernandez, A.S., Dollhopf, S.L., Dazzo, F.B., Hickey, R.F., Tiedje, J.M., and Criddle, C.S., Parallel processing of substrate correlates with greater function stability in methanogenic bioreactor communities perturbed by glucose, Appl. Environ. Microbiol., 66(9), 4050-4057, 2000.

Pernelle, J.-J., Gaval, G., Cotteux, É., and Duchene, P., Influence of transient substrate overloads on the proliferation of filamentous bacterial populations in an activated sludge pilot plant, Water Res., 35(1), 129-134, 2001.

González-Martínez, S., Staud, R., Wilderer, P.A., Hartman, L., and Norouzian, M., Alternating aerobic and anaerobic operation of an activated sludge plant, J. WPCF, 59(2), 65-71, 1987.

Horntvedt, B.R., Rambekk, M., and Bakke, R., Oscillating conditions for influencing the composition of mixed biological cultures, Water Sci. Technol., 37(4-5), 259-262, 1998.

Galil, N.I., Schwartz-Mittelman, A., and Saroussi-Zohar, O., Biomass deflocculation and process disturbances exerted by phenol induced transient load conditions, Water Sci. Technol., 38(8-9), 105-112, 1998.

Archibald, F., Méthot, M., Young, F., and Paice, M.G., A simple system to rapidly monitor activated sludge health and performance, Water Res., 35(10), 2543-2553, 2001.

Larisch, B.C. and Duff, S.J.B., Effect of H2O2 and DTPA on the characteristics and treatment of TCF (totally chlorine-free) and ECF (elementally chlorine-free) kraft pulping effluents, Water Sci. Technol., 35(2-3), 163-171, 1997.

Karthikeyan, S., Wolfaardt, G.M., Korber, D.R., and Caldwell, D.E., Functional and structural responses of a degradative microbial community to substrates with varying degrees of complexity in chemical structure, Microb. Ecol., 38, 215-224, 1999.

Keech, G.W., Whiting, P., and Allen, D.G., Effect of paper machine additives on the health of activated sludge, TAPPIJ., 83(3), 86-93, 2000.

Sarlin, T., Halttunen, S., Vuoriranta, P., and Puhakka, J., Effects of chemical spills on activated sludge treatment performance in pulp and paper mills, Water Sci. Technol., 40(11-12), 319-325, 1999.

Bergeron, J. and Paice, M., Monitoring of activated sludge systems using a combination of specific oxygen uptake rates and specific adenosine triphosphate measurements, Water Qual. Res. J. Canada, 36(4), 659-685, 2001.

Dalzell, D.J.B., Alte, S., Aspichueta, E., de la Sota, A., Etxebarria, J., Gutierrez, M., Hoffmann, C.C., Sales, D., Obst, U., and Christofi, N., A comparison of five rapid direct toxicity assessment methods to determine toxicity of pollutants to activated sludge, Chemosphere, 47, 535-545, 2002.

53. Carvalho, G., Paul, E., Novais, J.M., and Pinheiro, H.M., Studies on activated sludge response to variations in the composition of a synthetic surfactant-containing feed effluent, WaterSci. Technol., 42(5-6), 135-143, 2000.

54. Madigan, M.T., Martinko, J.M., and Parker, J., Brock Biology of Microorganisms, 8th ed., Prentice-Hall Inc., Upper Saddle River, NJ, 1997.

55. Yu, Z. and Mohn, W.W., Bioaugmentation with the resin acid-degrading bacterium Zoogloea resiniphila DhA-35 to counteract pH stress in an aerated lagoon treating pulp and paper mill effluent, Water Res., 36, 2793-2801, 2002.

56. Pohland, F.G., Anaerobic treatment: fundamental concepts, applications, and new horizons, in Design of Anaerobic Process for the Treatment of Industrial and Municipal Wastes, J.F. Malina and F.G. Pohland, Eds, Technomic Publishing Company, Inc., Lancaster, Pennsylvania, pp. 1-40, 1992.

57. Hall, E.R., Anaerobic treatment of wastewaters in suspended growth and fixed film processes, in Design of Anaerobic Processes for the Treatment of Industrial and Municipal Waste, J.F. Malina and F.G. Pohland, Eds, Technomic Publishing Company, Inc., Lancaster, Pennsylvania, pp. 41-118, 1992.

58. Carpenter, W.L., Vamvakias, J.G., and Gellman, I., Temperature relationships in aerobic treatment and disposal of pulp and paper wastes, J. WPCF. 40(5), 733-741, 1968.

59. Flippin, T.H. and Eckenfelder, W.W., Effects of elevated temperature on the activated sludge process, in Proc. Int. Environ. Conf. Exhibit, TAPPI Press, Portland, Oregon, 1994.

60. Cocci, A.A. and McCarthy, P.J. Sequencing batch reactors in the pulp and paper industry. A bench-marking study, in Proc. Int. Envir. Conf. Exhibit,TAPPI Press, Vancouver, British Columbia, 1998.

61. Lescure, J.P., Delannoy, D., Verrier, D., and Albgnac, G. Consequence of a thermal accident on the microbial activity of an industrial anaerobic filter, in Proc. Fifth Int. Symp. Anaerobic Digest., Bologna, Italy, 1988.

62. Visser, A., Gao, Y., and Lettinga, G., Effects of short-term temperature increases on the mesophilic anaerobic breakdown of sulfate containing synthetic wastewater, Water Res., 27(4), 541-550, 1993.

63. Uemura, S., Tseng, I.-C., and Harada, H., Effect of temperature elevation from 55°C to 65°C on the performance of a thermophilic UASB reactor and characteristics of methanogenic granular sludge, Environ. Technol. 16, 987-994, 1995.

64. Van Lier, J.B., Rintala, J., Sanz Martin, J.L., and Lettinga, G., Effect of short-term temperature increase on the performance of a mesophilic UASB reactor, Water Sci. Technol., 22(9), 183-190, 1990.

65. Ahring, B.K., Ibrahim, A.A., and Mladenovska, Z., Effect of temperature increase from 55 °C to 65 °C on performance and microbial population dynamics of anaerobic reactor treating cattle manure, Water Res., 35(10), 2446-2452, 2001.

66. van Lier, J.B., Grolle, K.C.F., Stams, A.J.M., de Macario, E.C., and Lettinga, G., Startup of a thermophilic upflow anaerobic sludge bed (UASB) reactor with mesophilic granular sludge, Appl. Microbiol. Biotech., 37, 130-135, 1992.

67. van Lier, J.B., Lettinga, G., Macario, A.J.L., and de Macario, E.C., Permanent increase of the process temperature of mesophilic upflow anaerobic sludge bed (UASB) reactors to 46, 55, 64 and 75°C, in Proc. 47thIndustrial Waste Conf., R.F. Wukasch, Ed., Lewis Publishers, Purdue University, West Lafayette, IN, 1992.

Borja, R. and Banks, C.J., Response of an anaerobic fluidized bed reactor treating icecream wastewater to organic, hydraulic, temperature, and pH shocks, J. Biotechnol., 39, 251-259, 1995.

Lee, E.G.-H., Mueller, J.C., and Walden, C.C., Effect of temperature and sludge loading on BOD5 removal and sludge settleability in activated sludge systems treating bleached kraft effluent, TAPPIJ, 58(6), 100-103, 1975.

Prensner, D.S., Muchmore, C.B., Gilmore, R.A., and Qazi, A.N., Wastewater treatment by heated rotating biological discs, Biotechnol. Bioeng., 28, 1615-1621, 1976.

Sakka, K., Endo, T., and Watanabe, M., Deoxyribonuclease-susceptible floc forming Pseudomonas sp., Agric. Biol. Chem., 45(2), 497-504, 1981.

Barr, T.A., Taylor, J.M., and Duff, S.J.B., Effect of HRT, SRT and temperature on the performance of activated sludge reactors treating bleached kraft mill effluent, Water Res., 30(4), 799-810, 1996.

Rinkus, K.M., Lin, W., Jha, A., and Reed, B.E., Investigation of microbial temperature sensitivity and effect of microorganisms on the integrity of a commercial metalworking fluid, in Proc. Hazard. Ind. Wastes 29th Mid-Atlantic Ind. Hazard. Waste Conf., 1997. Kriebitzsch, K., Adamietz, E., Schiegl, C., Helmreich, B., Wilderer, P.A., and Wuertz, S., Assessment of biological activity during temperature changes in a bench-scale sequencing batch reactor fed with synthetic medium containing lignin, Water Sci. Technol., 37(4-5), 251-254, 1998.

Tripathi, C., Thermophilic aerobic biological treatment of bleached kraft pulp mill effluent and its effects on floc formation and settleability, Ph.D. thesis, Department of Chemical Engineering and Applied Chemistry, University of Toronto, Ontario, Canada, 1999.

Norris, P., Marshall, R., and Richard, M., High temperature effects on activated sludge treatment performance and sludge quality in a recycle mill, in Proc. TAPPIInt. Environ. Conf. Exhibit, TAPPI Press, Denver, CO, 2000.

Vogelaar, J.C.T., Bouwhuis, E., Klapwijk, A., Spanjers, H., and van Lier, J.B., Meso-philic and thermophilic activated sludge post-treatment of paper mill process water, WaterRes, 36, 1869-1879, 2002.

Fernandez-Galiano, D., The ammoniacal silver carbonate method as a general procedure in the study of protozoa from sewage (and other) waters,Water Res., 28(2), 495-496, 1994.

Starkey, J.E. and Karr, J.E., Effect of low dissolved oxygen concentration on effluent turbidity, J. WaterPollut. Control. Fed., 56(7), 837-843, 1984.

Wilen, B.-M. and Balmer, P., Short-term effects of dissolved oxygen concentration on the turbidity of the supernatant of activated sludge, Water Sci. Technol., 38(3), 25-33, 1998.

Wilen, B.-M., Keiding, K., and Nielsen, P.H., Anaerobic deflocculation and aerobic reflocculation of activated sludge, Water Res., 34(16), 3933-3942, 2000. Rasmussen, H., Bruus, J.H., Keiding, K., and Nielsen, P.H., Observations on dewaterability and physical, chemical and microbiological changes in anaerobic-ally stored activated sludge from a nutrient removal plant, Water Res., 28(2), 417-425, 1994.

Schwartz-Mittelmann, A. and Galil, N.I., Biological mechanisms involved in bioflocculation disturbances caused by phenol, Water Sci. Technol., 42(1-2), 105-110, 2000.

84. Wilen, B.-M., Nielsen, J.L., Keiding, K., and Nielsen, P.H., Influence of microbial activity on the stability of activated sludge flocs, Colloid Surf. B: Biointerfaces, 18, 145-156, 2000.

85. Chudoba, P. and Pujol, R., Activated sludge plant facing grape harvest period — a case study, Water Sci. Technol., 34(11), 25-32, 1996.

86. Keiding, K. and Nielsen, P.H., Desorption of organic macromolecules from activated sludge: effect of ionic composition, Water Res., 31(7), 1665-1672, 1997.

87. Zita, A. and Hermansson, M., Effects of ionic strength on bacterial adhesion and stability of flocs in a wastewater activated sludge system, Appl. Environ. Microbiol., 60(9), 3041-3048, 1994.

88. Neufeld, R.D., Heavy metals-induced deflocculation of activated sludge, J. WPCF, 48(8), 1940-1947, 1976.

89. Stasinakis, A.S., Thomaidis, N.S., Mamais, D., Papanikolaou, E.C., Tsakon, A., and Lekkas, T.D., Effects of chromium (VI) addition on the activated sludge process, Water Res., 37(9), 2140-2148, 2003.

90. Nielsen, P.H. and Keiding, K., Disintegration of activated sludge flocs in presence of sulfide, Water Res., 32(2), 313-320, 1998.

91. Higgins, M.J. and Novak, J.T., Characterization of exocellular protein and its role in bioflocculation, J. Environ. Eng., May, 479-485, 1997.

92. Müller, E., Kriebitzsch, K., Wilderer, P.A., and Wuertz, S., Community structure of micro- and macroflocs in pin-point sludge and the influence of sludge age and potassium addition on microfloc formation, Water Sci. Technol., 46(1-2), 405-412, 2002.

93. Olofsson, A.-C., Zita, A., and Hermansson, M., Floc stability and adhesion of green-fluorescent-protein-marked bacteria to flocs in activated sludge, Microbiology, 144, 519-528, 1998.

94. Heine, W., Sekoulov, I., Burkhardt, H., Bergen, L., and Behrendt, J., Early warning system for operation failures in biological stages of WWTPs by on-line image analysis, Water Sci. Technol., 46(4-5), 117-124, 2002.

95. Caccavo, F.J., Frolund, B., Kloeke, F.v.O., and Nielsen, P.H., Deflocculation of activated sludge by the dissimilatory Fe(II)-reducing bacterium Shewanella alga BrY, Appl. Environ. Microbiol., 62(4), 1487-1490, 1996.

96. Bruus, J.H., Nielsen, P.H., and Keiding, K., On the stability of activated sludge flocs with implications to dewatering, Water Res., 26(12), 1597-1604, 1992.

97. Govoreanu, R., Seghers, D., Nopens, I., De Clercq, B., Saveyn, H., Capalozza, C., Va der Meeren, P., Verstraete, W., Top, E., and Vanrolleghem, P.A., Linking floc structure and settling properties to activated sludge population dynamics in an SBR, Water Sci. Technol., 47(12), 9-18, 2003.

98. Nielsen, P.H., Fr0lund, B., and Keiding, K., Changes in the composition of extracellular polymeric substances in activated sludge during anaerobic storage, Appl. Microbiol. Biotechnol., 44, 823-830, 1996.

99. Bott, C.B. and Love, N.G., The immunochemical detection of stress proteins in activated sludge exposed to toxic chemicals, Water Res., 35(1), 91-100, 2001.

100. Love, N.G. andBott, C.B., Evaluating the role ofmicrobial stress response mechanisms in causing biological treatment system upset, Water Sci. Technol., 46(1-2), 11-18, 2002.

101. Boyd, A. and Chakrabarty, A.M., Role of alginate lyase in cell detachment of Pseudomonas aeruginosa, App. Environ. Microbiol., 60(7), 2355-2359, 1994.

Watanabe, K., Teramoto, M., and Harayama, S., An outbreak of nonflocculating catabolic populations caused the breakdown of a phenol-digesting activated sludge process, Appl. Environ. Microbiol., 65(7), 2813-2819, 1999.

Belas, R., Sensing, response, and adaptation to surfaces: swarmer cell differentiation and behavior, in Bacterial Adhesion, Molecular and Ecological Diversity, M. Fletcher, Ed., Wiley-Liss, New york, pp. 281-331, 1996.

Palmgren, R., Jorand, F., Nielsen, P.H., and Block, J.C., Influence of oxygen limitation on the cell surface properties of bacteria from activated sludge, Water Sci. Technol., 37(4-5), 349-352, 1998.

Marshall, K.C., Adhesion as a strategy for access to nutrients, in Bacterial Adhesion. Molecular and Ecological Diversity, M. Fletcher, Ed., Wiley-Liss, Inc., New York, pp. 59-87, 1996.

Lycette, R.M. and Hedrick, L.R., Action of deflocculating agents on Saccharomyces cerevisiae Class III brewer's yeast, Appl. Microbiol., 10, 428-430, 1962. King, R.O. and Forster, C.F., Effects of sonicationon activated sludge, Enzyme Microb. Technol., 12(February), 109-115, 1990.

Morgan-Sagastume, F. and Allen, D.G., Effects of temperature transient conditions on aerobic biological treatment of wastewater, Water Res., 37(15), 3590-3601, 2003. Morgan-Sagastume, F., Effect of mesophilic-thermophilic temperature transients on aerobic biological treatment of wastewater, Ph.D. thesis, Department of Chemical Engineering and Applied Chemistry, University of Toronto, Ontario, Canada, 2003. Gaughran, E.R.L., The thermophilic microorganisms, Bact. Revs., 11, 189-225, 1947.

Allen, M.B., The thermophilic aerobic sporeforming bacteria, Bact. Revs., 17, 125-173, 1953.

LaPara, T.M. and Alleman, J.E., Thermophilic aerobic biological wastewater treatment, Water Res., 33(4), 895-908, 1999.

Yura, T., Kanemori, M., and Morita, M.T., The heat shock response: regulation and function, in Bacterial Stress Responses, R.G. Storz and Hengge-Aronis, Eds, ASM Press, Washington, DC, pp. 3-18, 2000.

Russell, J.B. and Cook, G.M., Energetics of bacterial growth: balance of anabolic and catabolic reactions, Microbiol. Rev., Mar, 48-62, 1995.

Mikkelsen, L.H., Gotfredsen, A.K., Agerb®k, M.L., Nielsen, P.H., and Keiding, K., Effects of colloidal stability on clarification and dewatering of activated sludge, Water Sci. Technol., 34(3-4), 449-457, 1996.

Phadtare, S., Yamanaka, K., and Inouye, M., The cold shock response,in Bacterial Stress Responses, G.S.a.R. Hengge-Aronis, Ed., ASM Press, Washington, DC, 2000, 33-45.

Carratü, L., Franceschelli, S., Pardini, C.L., Kobayashi, G.S., Horvath, I., Vigh, L., andMaresca, B., Membrane lipid perturbation modifies the set point of the temperature of heat shock response in yeast, Proc. Natl. Acad. Sci. USA, 93(April), 3870-3875, 1996.

Bremer, E. and Krämer, R., Coping with osmotic challenges: osmoregulation through accumulation and release of compatible solutes in bacteria, in Bacterial Stress Responses, G.S.a.R. Hengge-Aronis, Ed., ASM Press, Washington, DC, pp. 79-97, 2000.

Low, E.W. and Chase, H.A., Reducing production of excess biomass during wastewater treatment, Water Res., 33(5), 1119-1132, 1999.

Foster, J.W., Microbial responses to acid stress, in Bacterial Stress Responses, G.S.a.R. Hengge-Aronis, Ed., ASM Press, Washington, DC, pp. 99-115, 2000.

121. Padan, E. and Krulwich, T.A., Sodium stress, in Bacterial Stress Response, G.S.a.R.Hengge-Aronis, Ed., ASM Press, Washington, DC, pp. 117-130, 2000.

122. Krabbe, M., Weyand, N., and Low, D., Environmental control of pilus gene expression, in Bacterial Stress Responses, G.S.a.R. Hengge-Aronis, Ed., ASM Press, Washington, DC, pp. 305-321, 2000.

123. Silverman, M., Belas, R., and Simon, M., Genetic control of bacterial adhesion, in Microbial Adhesion and Aggregation, K.C. Marshall, Ed., Springer-Verlag, Berlin, Heidelber, New York, Tokyo, pp. 95-107, 1984.

124. Erdincler, A. and Vesilind, P.A., Effect of sludge cell disruption on compactibility of biological sludges, Water. Sci. Technol., 42(9), 119-126, 2000.

125. J0rgensen, P.E., Eriksen, T., and Jensen, B.K., Estimation of viable biomass in wastewater and activated sludge by determination of ATP, oxygen utilization rate and FDA hydrolysis, Water. Res., 26(11), 1495-1501, 1992.

126. Häner, A., Mason, C.A., and Hamer, G., Death and lysis during aerobic thermophilic sludge treatment: characterization of recalcitrant products, Water Res., 28(4), 863-869, 1994.

127. Rocher, M., Goma, G., Pilas-Begue, A., Louvel, L., andRols, J.L., Towards areduction in excess sludge production in activated sludge processes: biomass physicochemical treatment and biodegradation, Appl. Microbiol. Biotechnol., 51, 883-890, 1999.

0 0

Post a comment