Characteristics of biostability of drinking water in aged pipes after water source switching: ATP evaluation, biofilms niches and microbial community transition.

[1]  Yang Deng,et al.  Impacts of pre-oxidation on the formation of disinfection byproducts from algal organic matter in subsequent chlor(am)ination: A review. , 2020, The Science of the total environment.

[2]  Yuhui Wang,et al.  Metal-release potential from iron corrosion scales under stagnant and active flow, and varying water quality conditions. , 2020, Water research.

[3]  Jing-qing Liu,et al.  Formation of biofilms from new pipelines at both ends of the drinking water distribution system and comparison of disinfection by-products formation potential. , 2020, Environmental research.

[4]  W. Zhou,et al.  Impact of substrate material and chlorine/chloramine on the composition and function of a young biofilm microbial community as revealed by high-throughput 16S rRNA sequencing. , 2020, Chemosphere.

[5]  B. Dutilh,et al.  Microbial diversity, ecological networks and functional traits associated to materials used in drinking water distribution systems. , 2020, Water research.

[6]  Wen-Tso Liu,et al.  Assessing the transition effects in a drinking water distribution system caused by changing supply water quality: an indirect approach by characterizing suspended solids. , 2020, Water research.

[7]  R. Hozalski,et al.  Comparison of the microbiomes of two drinking water distribution systems—with and without residual chloramine disinfection , 2019, Microbiome.

[8]  Tuqiao Zhang,et al.  A novel method: using an adenosine triphosphate (ATP) luminescence–based assay to rapidly assess the biological stability of drinking water , 2019, Applied Microbiology and Biotechnology.

[9]  R. Hozalski,et al.  Effects of Chloramine and Coupon Material on Biofilm Abundance and Community Composition in Bench-Scale Simulated Water Distribution Systems and Comparison with Full-Scale Water Mains. , 2018, Environmental science & technology.

[10]  Wen-Tso Liu,et al.  Assessing the origin of bacteria in tap water and distribution system in an unchlorinated drinking water system by SourceTracker using microbial community fingerprints. , 2018, Water research.

[11]  Zhengqing Cai,et al.  Pilot investigation on formation of 2,4,6-trichloroanisole via microbial O-methylation of 2,4,6-trichlorophenol in drinking water distribution system: An insight into microbial mechanism. , 2018, Water research.

[12]  J. Qu,et al.  Impacts of water quality on the corrosion of cast iron pipes for water distribution and proposed source water switch strategy. , 2018, Water research.

[13]  M. Dignum,et al.  Assessment of the microbial growth potential of slow sand filtrate with the biomass production potential test in comparison with the assimilable organic carbon method. , 2017, Water research.

[14]  A. Pruden,et al.  Methodological approaches for monitoring opportunistic pathogens in premise plumbing: A review. , 2017, Water research.

[15]  Gertjan Medema,et al.  Potential impacts of changing supply-water quality on drinking water distribution: A review. , 2017, Water research.

[16]  J S Vrouwenvelder,et al.  Flow cytometric bacterial cell counts challenge conventional heterotrophic plate counts for routine microbiological drinking water monitoring. , 2017, Water research.

[17]  Chun Hu,et al.  Characterization of chemical composition and bacterial community of corrosion scales in different drinking water distribution systems , 2017 .

[18]  Frederik Hammes,et al.  Behavior and stability of adenosine triphosphate (ATP) during chlorine disinfection. , 2016, Water research.

[19]  Rose Amal,et al.  Understanding, Monitoring, and Controlling Biofilm Growth in Drinking Water Distribution Systems. , 2016, Environmental science & technology.

[20]  S. Vesper,et al.  Microbial pathogens in source and treated waters from drinking water treatment plants in the United States and implications for human health. , 2016, The Science of the total environment.

[21]  Amy Pruden,et al.  Legionella DNA Markers in Tap Water Coincident with a Spike in Legionnaires’ Disease in Flint, MI , 2016 .

[22]  David G. Wahman,et al.  Resilience of microbial communities in a simulated drinking water distribution system subjected to disturbances: role of conditionally rare taxa and potential implications for antibiotic-resistant bacteria , 2016 .

[23]  L. Lou,et al.  Characteristics of pipe-scale in the pipes of an urban drinking water distribution system in eastern China , 2016 .

[24]  I. Douterelo,et al.  Dynamics of Biofilm Regrowth in Drinking Water Distribution Systems , 2016, Applied and Environmental Microbiology.

[25]  J. Rose,et al.  How do you like your tap water? , 2016, Science.

[26]  R. Sadler,et al.  Elevated Blood Lead Levels in Children Associated With the Flint Drinking Water Crisis: A Spatial Analysis of Risk and Public Health Response. , 2016, American journal of public health.

[27]  Xiao-jian Zhang,et al.  Impact of disinfection on drinking water biofilm bacterial community. , 2015, Journal of environmental sciences.

[28]  Yan Liu,et al.  Pyrosequencing analysis of bacterial communities in biofilms from different pipe materials in a city drinking water distribution system of East China , 2015, Applied Microbiology and Biotechnology.

[29]  R. Hozalski,et al.  Sulfate Reducing Bacteria and Mycobacteria Dominate the Biofilm Communities in a Chloraminated Drinking Water Distribution System. , 2015, Environmental science & technology.

[30]  Paul Weir,et al.  Assessing microbiological water quality in drinking water distribution systems with disinfectant residual using flow cytometry. , 2014, Water research.

[31]  I B Gomes,et al.  An overview on the reactors to study drinking water biofilms. , 2014, Water research.

[32]  Nardy Kip,et al.  The dual role of microbes in corrosion , 2014, The ISME Journal.

[33]  B. Little,et al.  Mini-review: the morphology, mineralogy and microbiology of accumulated iron corrosion products , 2014, Biofouling.

[34]  Dongsheng Wang,et al.  Effect of sulfate on the transformation of corrosion scale composition and bacterial community in cast iron water distribution pipes. , 2014, Water research.

[35]  Lutgarde Raskin,et al.  Spatial-Temporal Survey and Occupancy-Abundance Modeling To Predict Bacterial Community Dynamics in the Drinking Water Microbiome , 2014, mBio.

[36]  J. Vreeburg,et al.  Pyrosequencing reveals bacterial communities in unchlorinated drinking water distribution system: an integral study of bulk water, suspended solids, loose deposits, and pipe wall biofilm. , 2014, Environmental science & technology.

[37]  Min Yang,et al.  Molecular analysis of long-term biofilm formation on PVC and cast iron surfaces in drinking water distribution system. , 2014, Journal of environmental sciences.

[38]  M. VanBriesenJeanne,et al.  Comparing Spatial and Temporal Diversity of Bacteria in a Chlorinated Drinking Water Distribution System , 2014 .

[39]  Naeem Qureshi,et al.  Aging infrastructure and decreasing demand: A dilemma for water utilities , 2014 .

[40]  M C M van Loosdrecht,et al.  Monitoring microbiological changes in drinking water systems using a fast and reproducible flow cytometric method. , 2013, Water research.

[41]  J. V. Dijk,et al.  Bacteriology of drinking water distribution systems: an integral and multidimensional review , 2013, Applied Microbiology and Biotechnology.

[42]  Paul Monis,et al.  Comparison of drinking water treatment process streams for optimal bacteriological water quality. , 2012, Water research.

[43]  R. Javaherdashti Impact of sulphate-reducing bacteria on the performance of engineering materials , 2011, Applied Microbiology and Biotechnology.

[44]  Dick van der Kooij,et al.  Effect of water composition, distance and season on the adenosine triphosphate concentration in unchlorinated drinking water in the Netherlands. , 2010 .

[45]  R. L. Valentine,et al.  Characterization of elemental and structural composition of corrosion scales and deposits formed in drinking water distribution systems. , 2010, Water research.

[46]  Yingying Wang,et al.  Measurement and interpretation of microbial adenosine tri-phosphate (ATP) in aquatic environments. , 2010, Water research.

[47]  Y. Tsai Impact of flow velocity on the dynamic behaviour of biofilm bacteria , 2005, Biofouling.

[48]  R. Donlan,et al.  Biofilms: Microbial Life on Surfaces , 2002, Emerging infectious diseases.

[49]  W. Ng,et al.  Investigation of assimilable organic carbon (AOC) and bacterial regrowth in drinking water distribution system. , 2002, Water research.

[50]  Marc Edwards,et al.  IRON PIPE corrosion IN DISTRIBUTION SYSTEMS , 2001 .

[51]  D. B. Smith,et al.  Full-scale studies of factors related to coliform regrowth in drinking water , 1996, Applied and environmental microbiology.

[52]  R. Donlan,et al.  Biofilm formation on cast iron substrata in water distribution systems , 1994 .

[53]  A K Camper,et al.  Bacteria associated with granular activated carbon particles in drinking water , 1986, Applied and environmental microbiology.

[54]  Olli H. Tuovinen,et al.  Bacterial, chemical, and mineralogical characteristics of tubercles in distribution pipelines , 1980 .

[55]  Min Yang,et al.  Characteristics of biofilms and iron corrosion scales with ground and surface waters in drinking water distribution systems , 2015 .

[56]  O. Köster,et al.  Flow-cytometric total bacterial cell counts as a descriptive microbiological parameter for drinking water treatment processes. , 2008, Water research.

[57]  C. Nicolella,et al.  Mechanisms of biofilm detachment in fluidized bed reactors , 1997 .

[58]  Richard S Tobin,et al.  Factors affecting coliform bacteria growth in distribution systems , 1982 .