Your search keyword '"de Man, H."' showing total 4 results

1. Health risk assessment for splash parks that use rainwater as source water.

Author

de Man H, Bouwknegt M, van Heijnsbergen E, Leenen EJ, van Knapen F, and de Roda Husman AM

Subjects

Child, Child, Preschool, Communicable Diseases epidemiology, Humans, Inhalation Exposure, Netherlands epidemiology, Risk Factors, Uncertainty, Water Microbiology, Public Health, Rain, Recreation, Risk Assessment methods, Water

Abstract

In the Netherlands, rainwater becomes more and more popular as an economic and environmentally sustainable water source for splash parks, however, the associated public health risk and underlying risk factors are unknown. Since splash parks have been associated with outbreaks of infectious diseases, a quantitative microbial risk assessment was performed using Legionella pneumophila as a target pathogen to quantify the risk of infection for exposure due to inhalation and Campylobacter jejuni for ingestion. Data for L. pneumophila and C. jejuni concentrations in rainfall generated surface runoff from streets were extracted from literature. Data for exposure were obtained by observing 604 people at splash parks, of whom 259 were children. Exposure volumes were estimated using data from literature to determine the volume of exposure through inhalation at 0.394 μL/min (95% CI-range 0.0446-1.27 μL/min), hand-to-mouth contact at 22.6 μL/min, (95% CI-range 2.02-81.0 μL/min), ingestion of water droplets at 94.4 μL/min (95% CI-range 5.1-279 μL/min) and ingestion of mouthfuls of water at 21.5·10(3) μL/min (95% CI-range 1.17 ·10(3)-67.0·10(3) μL/min). The corresponding risk of infection for the mean exposure duration of 3.5 min was 9.3·10(-5) (95% CI-range 0-2.4·10(-4)) for inhalation of L. pneumophila and 3.6·10(-2) (95% CI-range 0-5.3·10(-1)) for ingestion of C. jejuni. This study provided a methodology to quantify exposure volumes using observations on site. We estimated that using rainwater as source water for splash parks may pose a health risk, however, further detailed quantitative microbial analysis is required to confirm this finding. Furthermore we give insight into the effect of water quality standards, which may limit infection risks from exposure at splash parks., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

2. Health risk assessment for splash parks that use rainwater as source water

Author

De Man, H., Bouwknegt, M., van Heijnsbergen, E., Leenen, E. J T M, van Knapen, F., de Roda Husman, A. M., LS IRAS VPH VV (veterinaire volksgezh.), LS IRAS EEPI Global changes, Risk Assessment of Toxic and Immunomodulatory Agents, IRAS RATIA2, IRAS RATIA-SIB, LS IRAS VPH VV (veterinaire volksgezh.), LS IRAS EEPI Global changes, Risk Assessment of Toxic and Immunomodulatory Agents, IRAS RATIA2, and IRAS RATIA-SIB

Subjects

Veterinary medicine, Environmental Engineering, Risk of infection, Rain, Communicable Diseases, Risk Assessment, Rainwater harvesting, Exposure, Risk Factors, Ingestion, Humans, Child, Waste Management and Disposal, Interactive splash park, Civil and Structural Engineering, Fountain, Water Science and Technology, Netherlands, Hydrology, Splash, Inhalation Exposure, Inhalation, Health risk assessment, QMRA, Ecological Modeling, Uncertainty, Outbreak, Water, Pollution, Ecological Modelling, Rainwater, Child, Preschool, Environmental science, Recreation, Water quality, Public Health, Surface runoff, Water Microbiology

Abstract

In the Netherlands, rainwater becomes more and more popular as an economic and environmentally sustainable water source for splash parks, however, the associated public health risk and underlying risk factors are unknown. Since splash parks have been associated with outbreaks of infectious diseases, a quantitative microbial risk assessment was performed using Legionella pneumophila as a target pathogen to quantify the risk of infection for exposure due to inhalation and Campylobacter jejuni for ingestion. Data for L . pneumophila and C. jejuni concentrations in rainfall generated surface runoff from streets were extracted from literature. Data for exposure were obtained by observing 604 people at splash parks, of whom 259 were children. Exposure volumes were estimated using data from literature to determine the volume of exposure through inhalation at 0.394 μL/min (95% CI-range 0.0446–1.27 μL/min), hand-to-mouth contact at 22.6 μL/min, (95% CI-range 2.02 –81.0 μL/min), ingestion of water droplets at 94.4 μL/min (95% CI-range 5.1–279 μL/min) and ingestion of mouthfuls of water at 21.5·10 3 μL/min (95% CI-range 1.17 ·10 3 –67.0·10 3 μL/min). The corresponding risk of infection for the mean exposure duration of 3.5 min was 9.3·10 −5 (95% CI-range 0–2.4·10 −4 ) for inhalation of L. pneumophila and 3.6·10 −2 (95% CI-range 0–5.3·10 −1 ) for ingestion of C. jejuni . This study provided a methodology to quantify exposure volumes using observations on site. We estimated that using rainwater as source water for splash parks may pose a health risk, however, further detailed quantitative microbial analysis is required to confirm this finding. Furthermore we give insight into the effect of water quality standards, which may limit infection risks from exposure at splash parks.

Published

2013

3. Human exposure to endotoxins and fecal indicators originating from water features

Author

de Man, H., Heederik, D. D J, Leenen, E. J T M, de Roda Husman, A. M., Spithoven, J. J G, van Knapen, F., LS IRAS EEPI GRA (Gezh.risico-analyse), LS IRAS EEPI Global changes, LS IRAS VPH VV (veterinaire volksgezh.), Risk Assessment of Toxic and Immunomodulatory Agents, IRAS RATIA-SIB, IRAS RATIA2, LS IRAS EEPI GRA (Gezh.risico-analyse), LS IRAS EEPI Global changes, LS IRAS VPH VV (veterinaire volksgezh.), Risk Assessment of Toxic and Immunomodulatory Agents, IRAS RATIA-SIB, and IRAS RATIA2

Subjects

Pollution, Environmental Engineering, media_common.quotation_subject, Coronacrisis-Taverne, Fresh Water, Risk Assessment, Exposure, Endotoxin, Escherichia coli, Interactive water fountain, Humans, Water Pollutants, Cities, Waste Management and Disposal, Respiratory health, Feces, Limulus Test, Civil and Structural Engineering, media_common, Water Science and Technology, Netherlands, Aerosols, Air Pollutants, Ecological Modeling, CELL DEBRIS, Environmental Exposure, Contamination, Fecal coliform, Endotoxins, Ecological Modelling, Logistic Models, Human exposure, Fecal indicator bacteria, Environmental chemistry, Environmental science, Health risk, Regression Analysis, Water quality, Environmental Monitoring

Abstract

Exposure to contaminated aerosols and water originating from water features may pose public health risks. Endotoxins in air and water and fecal bacteria in water of water features were measured as markers for exposure to microbial cell debris and enteric pathogens, respectively. Information was collected about wind direction, wind force, distance to the water feature, the height of the water feature and the tangibility of water spray. The mean concentration of endotoxins in air nearby and in water of 31 water features was 10 endotoxin units (EU)/m(3) (Geometric Mean (GM), range 0-85.5 EU/m(3) air) and 773 EU/mL (GM, range 9-18,170 EU/mL water), respectively. Such mean concentrations may be associated with respiratory health effects. The water quality of 26 of 88 water features was poor when compared to requirements for recreational water in the Bathing Water Directive 2006/7/EC. Concentrations greater than 1000 colony forming units (cfu) Escherichia coli per 100 mL and greater than 400 cfu intestinal enterococci per 100 mL increase the probability of acquiring gastrointestinal health complaints. Regression analyses showed that the endotoxin concentration in air was significantly influenced by the concentration of endotoxin in water, the distance to the water feature and the tangibility of water spray. Exposure to air and water near water features was shown to lead to exposure to endotoxins and fecal bacteria. The potential health risks resulting from such exposure to water features may be estimated by a quantitative microbial risk assessment (QMRA), however, such QMRA would require quantitative data on pathogen concentrations, exposure volumes and dose-response relationships. The present study provides estimates for aerosolisation ratios that can be used as input for QMRA to quantify exposure and to determine infection risks from exposure to water features.

Published

2013

4. Quantitative assessment of infection risk from exposure to waterborne pathogens in urban floodwater

Author

De Man, H., Van Den Berg, H. H J L, Leenen, E. J T M, Schijven, J. F., Schets, F. M., Van Der Vliet, J. C., Van Knapen, F., De Roda Husman, A. M., Risk Assessment of Toxic and Immunomodulatory Agents, IRAS RATIA2, IRAS RATIA-SIB, LS IRAS VPH VV (veterinaire volksgezh.), LS IRAS EEPI Global changes, Risk Assessment of Toxic and Immunomodulatory Agents, IRAS RATIA2, IRAS RATIA-SIB, LS IRAS VPH VV (veterinaire volksgezh.), and LS IRAS EEPI Global changes

Subjects

Veterinary medicine, Environmental Engineering, Risk of infection, Cryptosporidium, Infections, Risk Assessment, Exposure, Flooding, medicine, Humans, Drainage, Waste Management and Disposal, Civil and Structural Engineering, Enterovirus, Water Science and Technology, Hydrology, biology, Ecological Modeling, Giardia, Ingestion, Flooding (psychology), Norovirus, Urban Health, Outbreak, Waterborne diseases, Campylobacter, biology.organism_classification, medicine.disease, Pollution, Floods, Ecological Modelling, Quantitative microbial risk assessment, Water Microbiology, Risk assessment, Surface runoff, Heavy rainfall

Abstract

Flooding and heavy rainfall have been associated with waterborne infectious disease outbreaks, however, it is unclear to which extent they pose a risk for public health. Here, risks of infection from exposure to urban floodwater were assessed using quantitative microbial risk assessment (QMRA). To that aim, urban floodwaters were sampled in the Netherlands during 23 events in 2011 and 2012. The water contained Campylobacter jejuni (prevalence 61%, range 14-10(3) MPN/l), Giardia spp. (35%, 0.1-142 cysts/l), Cryptosporidium (30%, 0.1-9.8 oocysts/l), noroviruses (29%, 10(2)-10(4) pdu/l) and enteroviruses (35%, 10(3)-10(4) pdu/l). Exposure data collected by questionnaire, revealed that children swallowed 1.7 ml (mean, 95% Confidence Interval 0-4.6 ml) per exposure event and adults swallowed 0.016 ml (mean, 95% CI 0-0.068 ml) due to hand-mouth contact. The mean risk of infection per event for children, who were exposed to floodwater originating from combined sewers, storm sewers and rainfall generated surface runoff was 33%, 23% and 3.5%, respectively, and for adults it was 3.9%, 0.58% and 0.039%. The annual risk of infection was calculated to compare flooding from different urban drainage systems. An exposure frequency of once every 10 years to flooding originating from combined sewers resulted in an annual risk of infection of 8%, which was equal to the risk of infection of flooding originating from rainfall generated surface runoff 2.3 times per year. However, these annual infection risks will increase with a higher frequency of urban flooding due to heavy rainfall as foreseen in climate change projections.

Published

2014