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Rapid detection of bacteria in drinking water and water contamination case studies |
Rolf A. Deininger1( ), Jiyoung Lee2, Robert M. Clark3 |
| 1. School of Public Health, The University of Michigan, Ann Arbor, MI 48033, USA; 2. College of Public Health, Division of Environmental Health Sciences, Ohio State University, Columbus, OH 43210, USA; 3. Environmental Engineering and Public Health Consultant, 9627 Lansford Drive, Cincinnati, OH 45242, USA |
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Abstract Water systems are inherently vulnerable to physical, chemical and biologic threats that might compromise a systems’ ability to reliably deliver safe water. The ability of a water supply to provide water to its customers can be compromised by destroying or disrupting key physical elements of the water system. However, contamination is generally viewed as the most serious potential terrorist threat to water systems. Chemical or biologic agents could spread throughout a distribution system and result in sickness or death among the consumers and for some agents the presence of the contaminant might not be known until emergency rooms report an increase in patients with a particular set of symptoms. Even without serious health impacts, just the knowledge that a water system had been breached could seriously undermine consumer confidence in public water supplies. Therefore, the ability to rapidly detect contamination, especially microbiological contamination, is highly desirable. The authors summarize water contamination case studies and discuss a technique for identifying microbiological contamination based on ATP bioluminescence. This assay allows an estimation of bacterial populations within minutes and can be applied using a local platform. Previous ATP-based methods requires one hour, one liter of water, and has a sensitivity of 100000 cells for detection. The improved method discussed here is 100 times more sensitive, requires one-hundredth of the sample volume, and is over 10 times faster than standard method. T\his technique has a great deal of potential for application in situations in which a water system has been compromised.
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| Keywords
drinking water
bacteria
waste water treatment plants
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Corresponding Author(s):
Deininger Rolf A.,Email:rad@umich.edu
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Issue Date: 05 December 2011
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