Viral dispersal in the coastal zone: A method to quantify water quality risk
Waterborne and shellfish-borne enteric viruses associated with wastewater-polluted coastal waters (e.g. Norovirus, Hepatitis A/E viruses, Adenovirus) represent a major threat to human health. Improved understanding of the locations and periods of heightened risks can help target mitigation measures...
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Elsevier
2019-05-01
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| Series: | Environment International |
| Online Access: | http://www.sciencedirect.com/science/article/pii/S0160412018331398 |
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doaj-14847461bcd44d6b89989209ee6761392020-11-25T02:48:57ZengElsevierEnvironment International0160-41202019-05-01126430442Viral dispersal in the coastal zone: A method to quantify water quality riskPeter E. Robins0Kata Farkas1David Cooper2Shelagh K. Malham3Davey L. Jones4School of Ocean Sciences, Bangor University, Marine Centre Wales, Menai Bridge LL59 5AB, UK; Corresponding author.School of Natural Sciences, Bangor University, Bangor LL57 2UW, UKCentre for Ecology and Hydrology, Environment Centre Wales, Bangor LL57 2UW, UKSchool of Ocean Sciences, Bangor University, Marine Centre Wales, Menai Bridge LL59 5AB, UKSchool of Natural Sciences, Bangor University, Bangor LL57 2UW, UK; UWA School of Agriculture and Environment, University of Western Australia, Crawley, AustraliaWaterborne and shellfish-borne enteric viruses associated with wastewater-polluted coastal waters (e.g. Norovirus, Hepatitis A/E viruses, Adenovirus) represent a major threat to human health. Improved understanding of the locations and periods of heightened risks can help target mitigation measures and improve public health. We developed a river-estuary-coast model to simulate virus dispersal, driven by point source discharges and river flows in combination with tidal forcing. Viral inputs were based on measured wastewater adenovirus concentrations and the model was implemented with or without viral die-off. We applied the model to the Conwy river (North Wales, UK), through the estuary, to the Irish Sea coast where bathing waters and shellfisheries are known to be prone to viral contamination. Using a suite of scenarios, we showed that river flow was the primary control of viral export to the coast. Since the Conwy catchment is short and steep, and the estuary is small and river-dominated, short-duration high intensity ‘flash floods’ were shown to transport viruses through the estuary and out to sea, despite dilution or die-off effects. Duplicating flow events (i.e., storm clustering) did not double the virus export since the virus re-entered the estuary on the flood tide. The tidal magnitude and timing of high water relative to peak river flow were also important drivers regulating viral dispersal. A worst-case event simulation (i.e., combining high river flows with high viral loading and high spring tide) resulted in increased concentrations of virus at nearby coasts, although the spatial spread was similar to the previous scenarios. Our results suggest that impact models for predicting and mitigating episodes of poor microbiological water quality may require careful representation of the intensity and timings of river flow when evaluating pathogen exposure risk. Keywords: Extreme events, Combination Hazard, Recreational waters, Risk assessment, Sewage dischargehttp://www.sciencedirect.com/science/article/pii/S0160412018331398 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Peter E. Robins Kata Farkas David Cooper Shelagh K. Malham Davey L. Jones |
| spellingShingle |
Peter E. Robins Kata Farkas David Cooper Shelagh K. Malham Davey L. Jones Viral dispersal in the coastal zone: A method to quantify water quality risk Environment International |
| author_facet |
Peter E. Robins Kata Farkas David Cooper Shelagh K. Malham Davey L. Jones |
| author_sort |
Peter E. Robins |
| title |
Viral dispersal in the coastal zone: A method to quantify water quality risk |
| title_short |
Viral dispersal in the coastal zone: A method to quantify water quality risk |
| title_full |
Viral dispersal in the coastal zone: A method to quantify water quality risk |
| title_fullStr |
Viral dispersal in the coastal zone: A method to quantify water quality risk |
| title_full_unstemmed |
Viral dispersal in the coastal zone: A method to quantify water quality risk |
| title_sort |
viral dispersal in the coastal zone: a method to quantify water quality risk |
| publisher |
Elsevier |
| series |
Environment International |
| issn |
0160-4120 |
| publishDate |
2019-05-01 |
| description |
Waterborne and shellfish-borne enteric viruses associated with wastewater-polluted coastal waters (e.g. Norovirus, Hepatitis A/E viruses, Adenovirus) represent a major threat to human health. Improved understanding of the locations and periods of heightened risks can help target mitigation measures and improve public health. We developed a river-estuary-coast model to simulate virus dispersal, driven by point source discharges and river flows in combination with tidal forcing. Viral inputs were based on measured wastewater adenovirus concentrations and the model was implemented with or without viral die-off. We applied the model to the Conwy river (North Wales, UK), through the estuary, to the Irish Sea coast where bathing waters and shellfisheries are known to be prone to viral contamination. Using a suite of scenarios, we showed that river flow was the primary control of viral export to the coast. Since the Conwy catchment is short and steep, and the estuary is small and river-dominated, short-duration high intensity ‘flash floods’ were shown to transport viruses through the estuary and out to sea, despite dilution or die-off effects. Duplicating flow events (i.e., storm clustering) did not double the virus export since the virus re-entered the estuary on the flood tide. The tidal magnitude and timing of high water relative to peak river flow were also important drivers regulating viral dispersal. A worst-case event simulation (i.e., combining high river flows with high viral loading and high spring tide) resulted in increased concentrations of virus at nearby coasts, although the spatial spread was similar to the previous scenarios. Our results suggest that impact models for predicting and mitigating episodes of poor microbiological water quality may require careful representation of the intensity and timings of river flow when evaluating pathogen exposure risk. Keywords: Extreme events, Combination Hazard, Recreational waters, Risk assessment, Sewage discharge |
| url |
http://www.sciencedirect.com/science/article/pii/S0160412018331398 |
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