Your search keyword '"premise plumbing systems"' showing total 9 results

1. Bacterial populations in different parts of domestic drinking water systems are distinct and adapted to the given ambient temperatures

Author

Benjamin Meyer, Mark Pannekens, André R. Soares, Lara Timmermann, Alexander J. Probst, Martin Hippelein, Bernd Bendinger, and Andreas Nocker

Subjects

premise plumbing systems, domestic drinking water distribution, drinking water microbiology, drinking water microbiome, temperature adaptation, Environmental technology. Sanitary engineering, TD1-1066

Abstract

Drinking water enters buildings with a given microbiological community composition. Within premise plumbing systems, the drinking water is subject to very different conditions and temperatures. Whereas part of the water stays cold, another part is heated to provide hot water. In this study, drinking water samples were taken at different locations in four buildings that had central heating circles and that were equipped with ultrafiltration modules. The latter were intended to keep bacterial numbers low. When studying the increase in bacterial concentrations in these water samples using regrowth tests at different incubation temperatures, a temperature-dependence could be observed. Bacteria in cold water samples propagated best when incubated at 22°C, but often poorly at 36°C and not at all at 50°C. Bacteria in hot water samples showed the reverse behavior and grew best when incubated at 50°C, whereas growth at 22°C was poor or associated with a long growth lag. Water samples from distal taps in periphery locations used for retrieving both cold and hot water showed intermediate growth behaviors. Results suggest the existence of different temperature-adapted bacterial populations within domestic drinking water systems. The finding was supported by sequence data revealing distinct differences in the microbiomes between cold and hot water samples. Abundant bacterial groups in hot water included Deinococci, Kryptonia, Ignavibacteria, Nitrospiria, Gemmatimonadetes and different genera of Gammaproteobacteria. Stagnation of hot water at 50°C, 55°C, or 60°C furthermore shaped the microbiome in different ways indicating that small temperature differences can have a substantial impact on the bacterial communities.

Published

2023

2. Legionella and the Role of Dissolved Oxygen in Its Growth and Inhibition: A Review.

Author

Krause, J. David

Subjects

DISSOLVED oxygen in water, LEGIONELLA, LEGIONNAIRES' disease, CELL respiration, DRINKING water, OXYGEN

Abstract

This review discusses the relationship between dissolved oxygen and Legionella growth. Growth of Legionella in building water systems is considered to pose a health risk and controlling it could benefit public health by reducing the number of healthcare and community acquired Legionnaires' disease cases. Conditions known to encourage Legionella growth include low disinfectant concentrations, warm temperature, and water stagnation. Legionella is an obligate aerobe meaning its cellular respiration is inhibited under anaerobic conditions. Despite evidence from earlier published studies the importance of dissolved oxygen for the survival and growth of Legionella has received little attention from researchers and public health authorities. Modern measurement devices can reliably determine if dissolved oxygen concentrations in potable water and other building water systems are at levels capable of supporting Legionella growth or inhibiting its amplification. Removing dissolved oxygen from water can be achieved using gas transfer membrane contactors. Water with low dissolved oxygen levels interferes with Legionella's cellular respiration by oxygen starvation, whereas disinfectants achieve the same effect by interfering with oxygen transport across the cell membrane. Ultimately, the same effect on Legionella growth may be achieved by reducing dissolved oxygen as treatment with oxidants, while avoiding the drawbacks of corrosion and disinfectant byproducts. [ABSTRACT FROM AUTHOR]

Published

2022

3. Legionella and the Role of Dissolved Oxygen in Its Growth and Inhibition: A Review

Author

J. David Krause

Subjects

legionellosis, Legionella control, premise plumbing systems, treatment technologies, dissolved oxygen, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

This review discusses the relationship between dissolved oxygen and Legionella growth. Growth of Legionella in building water systems is considered to pose a health risk and controlling it could benefit public health by reducing the number of healthcare and community acquired Legionnaires’ disease cases. Conditions known to encourage Legionella growth include low disinfectant concentrations, warm temperature, and water stagnation. Legionella is an obligate aerobe meaning its cellular respiration is inhibited under anaerobic conditions. Despite evidence from earlier published studies the importance of dissolved oxygen for the survival and growth of Legionella has received little attention from researchers and public health authorities. Modern measurement devices can reliably determine if dissolved oxygen concentrations in potable water and other building water systems are at levels capable of supporting Legionella growth or inhibiting its amplification. Removing dissolved oxygen from water can be achieved using gas transfer membrane contactors. Water with low dissolved oxygen levels interferes with Legionella’s cellular respiration by oxygen starvation, whereas disinfectants achieve the same effect by interfering with oxygen transport across the cell membrane. Ultimately, the same effect on Legionella growth may be achieved by reducing dissolved oxygen as treatment with oxidants, while avoiding the drawbacks of corrosion and disinfectant byproducts.

Published

2022

4. Impact of fixture purging on water age and excess water usage, considering stochastic water demands.

Author

Clements, Emily, Irwin, Christopher, Taflanidis, Alexandros, Bibby, Kyle, and Nerenberg, Robert

Subjects

*WATER use, *MICROBIAL growth, *WATER quality, *AGE, *ORGANOMETALLIC compounds, *DISINFECTION by-product

Abstract

• Purging devices reduce water age in premise plumbing systems but increase water use. • Purging removes much variability in water ages, avoiding extreme ages entirely. • Smart purging used less water than scheduled purging and maintained low ages. • Larger purging volumes and frequencies result in lower water ages but higher use. • Purging has a larger impact on low occupancy homes. Higher water ages are linked with water quality decline as chlorine dissipates, temperatures become more favorable for microbial growth, and metals and organic matter leach from the pipes. Water fixtures with automated purging devices can limit water age in premise plumbing systems, but also increase water use. To develop purging strategies that lower age while also minimizing water use, the stochastic nature of water demands must be considered. In this research, a hydraulic plumbing network model, with stochastic demands at fixtures, was used to compare water age and water use for five purging conditions: purging at regular intervals, "smart" purging (considering the time of last use), purging with different volumes of water, purging at different fixtures, and the purging with different levels of home occupancy. Higher purging frequency and volume resulted in lower water ages, but higher water use. Purging greatly reduced the variability in water ages, avoiding extreme ages entirely. Water age was minimized by scheduling the purging around occupancy behavior, such as before the occupants wake up or return from work. Scheduled purging used more water than smart purging. Purging after 12 h of nonuse used only 55% of the additional water required for purging every 12 h. Purging after 24 h of nonuse at the kitchen tap and shower used only 38% of the additional water required for purging every 24 h, while maintaining lower water ages and removing the variability in water ages. While larger purging volumes had a greater impact on water age, there were diminishing returns. Purging has a larger impact on low-occupancy homes because fixtures have less frequent use. Overall, this research provides a methodology to compare purging strategies that minimize both water age and water use. While the numerical results presented here are only valid for the specific layout and usage habits, they provide insights and trends applicable to other cases. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

5. Legionellosis and Recent Advances in Technologies for Legionella Control in Premise Plumbing Systems: A Review

Author

Kelsie M. Carlson, Laura A. Boczek, Soryong Chae, and Hodon Ryu

Subjects

legionellosis, legionella control, premise plumbing systems, treatment technologies, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

This review discusses Legionella, among the most prolific and publicly well-known waterborne pathogens, and advances in potential treatment technologies. The number of cases associated with Legionella continues to rise, as does its public awareness. Currently, cases associated with premise plumbing account for the largest number of legionellosis cases in the United States. So, while it is important to understand Legionella as such, it is also important to investigate how to treat drinking water in premise plumbing for Legionella and other waterborne pathogens. While there are currently several methods recognized as potential means of inactivating waterborne pathogens, several shortcomings continue to plague its implementation. These methods are generally of two types. Firstly, there are chemical treatments such as chlorine, chlorine dioxide, monochloramine, ozone, and copper-silver ionization. Secondly, there are physical treatments such as thermal inactivation and media filtration. Their shortcomings range from being labor-intensive and costly to having negative health effects if not properly operated. Recently developed technologies including ultraviolet (UV) irradiation using light emitting diodes (LEDs) and innovative carbon nanotube (CNT) filters can better control waterborne pathogens by allowing for the simultaneous use of different treatment measures in plumbing systems.

Published

2020

6. Legionella Diversity and Spatiotemporal Variation in the Occurrence of Opportunistic Pathogens within a Large Building Water System.

Author

Buse, Helen Y., Morris, Brian J., Gomez-Alvarez, Vicente, Szabo, Jeffrey G., and Hall, John S.

Subjects

LEGIONELLA, DRINKING water, WATER quality, NUCLEOTIDE sequencing, PATHOGENIC microorganisms, LEPTOSPIRA interrogans

Abstract

Understanding Legionella survival mechanisms within building water systems (BWSs) is challenging due to varying engineering, operational, and water quality characteristics unique to each system. This study aimed to evaluate Legionella, mycobacteria, and free-living amoebae occurrence within a BWS over 18–28 months at six locations differing in plumbing material and potable water age, quality, and usage. A total of 114 bulk water and 57 biofilm samples were analyzed. Legionella culturability fluctuated seasonally with most culture-positive samples being collected during the winter compared to the spring, summer, and fall months. Positive and negative correlations between Legionella and L.pneumophila occurrence and other physiochemical and microbial water quality parameters varied between location and sample types. Whole genome sequencing of 19 presumptive Legionella isolates, from four locations across three time points, identified nine isolates as L. pneumophila serogroup (sg) 1 sequence-type (ST) 1; three as L. pneumophila sg5 ST1950 and ST2037; six as L. feeleii; and one as Ochrobactrum. Results showed the presence of a diverse Legionella population with consistent and sporadic occurrence at four and two locations, respectively. Viewed collectively with similar studies, this information will enable a better understanding of the engineering, operational, and water quality parameters supporting Legionella growth within BWSs. [ABSTRACT FROM AUTHOR]

Published

2020

7. Legionellosis and Recent Advances in Technologies for Legionella Control in Premise Plumbing Systems: A Review.

Author

Carlson, Kelsie M., Boczek, Laura A., Chae, Soryong, and Ryu, Hodon

Subjects

LEGIONNAIRES' disease, WATERBORNE infection, LEGIONELLA, LIGHT emitting diodes, CHLORINE dioxide, DRINKING water

Abstract

This review discusses Legionella, among the most prolific and publicly well-known waterborne pathogens, and advances in potential treatment technologies. The number of cases associated with Legionella continues to rise, as does its public awareness. Currently, cases associated with premise plumbing account for the largest number of legionellosis cases in the United States. So, while it is important to understand Legionella as such, it is also important to investigate how to treat drinking water in premise plumbing for Legionella and other waterborne pathogens. While there are currently several methods recognized as potential means of inactivating waterborne pathogens, several shortcomings continue to plague its implementation. These methods are generally of two types. Firstly, there are chemical treatments such as chlorine, chlorine dioxide, monochloramine, ozone, and copper-silver ionization. Secondly, there are physical treatments such as thermal inactivation and media filtration. Their shortcomings range from being labor-intensive and costly to having negative health effects if not properly operated. Recently developed technologies including ultraviolet (UV) irradiation using light emitting diodes (LEDs) and innovative carbon nanotube (CNT) filters can better control waterborne pathogens by allowing for the simultaneous use of different treatment measures in plumbing systems. [ABSTRACT FROM AUTHOR]

Published

2020

8. Development of novel culture independent nucleic acid based diagnostics technologies for the detection and identification of microbial contaminants in building water distribution and premise plumbing systems

Author

Minogue, Elizabeth, Barry, Thomas, and NUI Galway College of Science

Subjects

Water distribution systems, Biocontamination, Multiplex real-time PCR NAD assays, Premise plumbing systems, Molecular diagnostics, Human microbial pathogens, Culture independent, Microbiology

Abstract

Water is a vital component of the industrial, pharmaceutical and healthcare sectors. In industrial and pharmaceutical sectors water is a commonly used raw material, solvent and ingredient. While in healthcare facilities water is used for cleaning, bathing, sanitation, mixing or diluting drug solutions and rinsing medical devices. Building water distribution and premise plumbing systems can become contaminated with microorganisms. Currently microbial analysis of building water distribution and premise plumbing systems is routinely performed by culture incubation and can take 5-7 days to achieve a definitive result. The use of Nucleic Acid Diagnostics (NAD) technologies for the detection of biocontamination in building water distribution and premise plumbing systems has the potentially to quantitatively detect and identify contaminating microorganisms and also significantly reduce the turnaround time to result. In the industrial and pharmaceutical sectors a shorter time to result utilizing NAD technologies could potentially reduce manufacturing costs by enabling raw materials and end products to be released more quickly. It can also shorten the manufacturing production cycle and reduce inventory requirements. These rapid and specific NAD detection methods can provide the means to identify, contain and recover from a contamination event quickly which can result in significant cost savings for industry. Additionally, in healthcare settings such as hospitals, doctor’s clinics, nursing homes, clinical diagnostics testing laboratories and dental facilities contamination of building water distribution and premise plumbing systems can result in an increased risk of healthcare associated infections (HCAI’s). The use of NAD technologies for the rapid and early detection and identification of contamination in healthcare building water distribution and premise plumbing systems can help to decrease the risks of HCAI’s. This in turn can reduce the cost impact to the healthcare system and shorten the average healthcare stay for patients. The overall aim of this study was to design, develop, optimise and validate robust, internally controlled, NAD based methodologies for the simultaneous quantitative detection and identification of the most common microorganisms typically associated with the contamination of building water distribution and premise plumbing systems. The designed NAD assays were developed in accordance with Minimum Information for Publication of Quantitative Real-Time PCR Experiments (MIQE) guidelines. In the first study, an internally controlled multiplex real-time PCR diagnostics assay using novel molecular targets was designed to identify Pseudomonas aeruginosa and Burkholderia species. These microorganisms are commonly associated with contamination of building water distribution and premise plumbing systems. These microorganisms are pathogenic and can cause infection in humans especially in immuno-compromised patients. In the second study, two additional targets were incorporated into the previous triplex assay for the detection of Serratia marcescens and Stenotrophomonas maltophilia resulting in an internally controlled 5-plex assay. The specificity of these multiplex real-time PCR assays was optimised and validated against genomic DNA from a panel of 95 isolates. Analytical sensitivities of less than 10 genome equivalents were determined for each diagnostics assay developed in multiplex format. Additionally in studies one and two a methodology was developed for the recovery and quantitative analysis of microbial nucleic acid from water. In the first study this methodology was demonstrated using sterile High Purity Water (HPW) spiked with bacterial cells. The microbial cells were trapped on a filter, suspended in PBS followed by mild sonication to detach cells from filter before chemical cell lysis and column purification of DNA. This DNA was then used as a template in the developed multiplex real-time PCR. This developed methodology detected a spiked bacterial load of 1.06 x 102 cfu / 100 ml for P. aeruginosa and 2.66 x 102 cfu / 100 ml for Burkholderia cepacia. In study two this methodology was slightly altered to increase the sensitivity. Water was filtered to trap microbial cells which were then subjected to direct chemical lysis on the filter followed by column purification of DNA. Subsequently an analysis of HPW supplied by a Millipore Elix 35 water purification unit was performed using traditional culture and using the developed culture independent methodology. Both of these analyses revealed the presence of S. maltophilia and Burkholderia species in the HPW. The quantitative analysis using the developed culture independent methodology combining filtration, nucleic acid purification and multiplex real-time PCR NAD assay identified the levels of S. maltophilia and Burkholderia species present in the HPW was above the threshold of 10 cfu / 100 ml recommended by both EU and US pharmacopoeial guidelines. In the third study additional biomarkers were developed for the detection of three other microorganisms associated with contamination of building water distribution and premise plumbing systems namely Legionella species, Staphyloccus aureus and Enterobacter aerogenes. All of the developed assays were modified for compatibility with Luminex magnetic bead suspension array technologies. An 8-plex internally controlled PCR assay was developed for the detection of each of these seven human pathogens. There is a need to develop rapid NAD technologies for the microbial analysis of building water distribution and premise plumbing systems to provide appropriate alternatives to the traditional culture based methodologies currently in use. The methodology developed in this study is rapid specific, sensitive and quantitative with a turnaround time to results of < 5 h. We propose that this methodology could be applied to the residential, industrial, pharmaceutical and healthcare sectors to assure the safety and quality of building water distribution and premise plumbing systems. 2019-08-14

Published

2015

9. The presence and growth of Legionella species in thermostatic shower mixer taps

Subjects

rubber, premise plumbing systems, Legionella, microbial water quality, shower taps, respiratory tract diseases

Abstract

Legislation in the Netherlands requires routine analysis of drinking water samples for cultivable Legionella species from high-priority installations. A field study was conducted to investigate the presence of Legionella species in thermostatic shower mixer taps. Water samples and the interior of ten thermostatic shower mixer taps were investigated for cultivable Legionella species. In seven cases, Legionella species was found in at least one of the samples. In four cases, Legionella species was detected in the biofilm on the thermostatic shower mixer taps interior, with the highest values on rubber parts, and in five cases in the cold supply water. These results show that thermostatic shower mixer taps can play a role in exceeding the threshold limit for cultivable Legionella species, but the cold supply water can also be responsible. Practical implications: This study showed that contamination of thermostatic shower mixer taps (TSMTs) with Legionella spp. was frequently observed in combination with contamination of the water system. Consequently, a combined focus is necessary to prevent the proliferation of cultivable Legionella spp. in TSMTs. In addition, the results also demonstrated that biofilms on rubbers inside the TSMT had high numbers of Legionella spp., probably because rubber contains relatively high concentrations of biodegradable substrates. Therefore, improvement of the rubber materials is necessary to reduce the proliferation of cultivable Legionella spp. in TSMTs.

Published

2014