Biological instability in a chlorinated drinking water distribution network

The purpose of a drinking water distribution system is to deliver drinking water to the consumer, preferably with the same quality as when it left the treatment plant. In this context, the maintenance of good microbiological quality is often referred to as biological stability, and the addition of s...

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Bibliographic Details
Published in:PloS one 2014-05, Vol.9 (5), p.e96354
Main Authors: Nescerecka, Alina, Rubulis, Janis, Vital, Marius, Juhna, Talis, Hammes, Frederik
Format: Article
Language:English
Subjects:
Adenosine
Aquatic sciences
ATP
Bacteria
Biofilms
Biological effects
Biology and Life Sciences
Chlorination
Chlorine
Cultivation
Disinfection & disinfectants
Distribution management
Drinking water
Drinking Water - microbiology
Drinking Water - standards
E coli
Escherichia coli
Flow Cytometry
Flow stability
Flow velocity
Instability
Latvia
Methods
Microbiology
Microorganisms
Networks
Phosphates
Residual chlorine
Stability
Stability analysis
Wastewater treatment
Water analysis
Water distribution
Water distribution systems
Water engineering
Water Microbiology
Water Purification - methods
Water Purification - standards
Water Quality
Water sampling
Water shortages
Water Supply - standards
Water treatment
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Summary:The purpose of a drinking water distribution system is to deliver drinking water to the consumer, preferably with the same quality as when it left the treatment plant. In this context, the maintenance of good microbiological quality is often referred to as biological stability, and the addition of sufficient chlorine residuals is regarded as one way to achieve this. The full-scale drinking water distribution system of Riga (Latvia) was investigated with respect to biological stability in chlorinated drinking water. Flow cytometric (FCM) intact cell concentrations, intracellular adenosine tri-phosphate (ATP), heterotrophic plate counts and residual chlorine measurements were performed to evaluate the drinking water quality and stability at 49 sampling points throughout the distribution network. Cell viability methods were compared and the importance of extracellular ATP measurements was examined as well. FCM intact cell concentrations varied from 5×10(3) cells mL(-1) to 4.66×10(5) cells mL(-1) in the network. While this parameter did not exceed 2.1×10(4) cells mL(-1) in the effluent from any water treatment plant, 50% of all the network samples contained more than 1.06×10(5) cells mL(-1). This indisputably demonstrates biological instability in this particular drinking water distribution system, which was ascribed to a loss of disinfectant residuals and concomitant bacterial growth. The study highlights the potential of using cultivation-independent methods for the assessment of chlorinated water samples. In addition, it underlines the complexity of full-scale drinking water distribution systems, and the resulting challenges to establish the causes of biological instability.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0096354