(Montana State University - Bozeman, College of Engineering, 2007) Grabinski, Kevin John; Chairperson, Graduate Committee: Warren Jones
Drinking water distribution systems pose the potential to transport biological and chemical contaminants to the consumers' tap that can be responsible for widespread waterborne disease outbreaks (WBDO). A need exists to improve the ability to monitor contaminants that can attach to the distribution system's interior surfaces and to obtain samples for diagnosing both the cause of a WBDO and the extent of contamination within the system. In this study, a porous media reactor colonized with a mixed-species drinking water biofilm was used to study the capture of Salmonella typhimurium as a model pathogen. Parallel reactors were operated under constant flow (CF) and constant head (CH) to compare flow-regime induced spatial variations in biofilm accumulation and the resulting pathogen capture. Parallel test reactors were operated with 0.5 mg/L supplemental carbon until the accumulation of biofilm in the CH reactor reduced the flowrate to the target sampling point (CF flowrate). Both test reactors were then inoculated with slug doses of approximately 3x109 CFU S. typhimurium. Effluent water samples were collected for five pore-volumes, followed by the destructive sampling of the reactor.
