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DOI

  • Matthew J Wade
    University of Newcastle
  • Anna Lo Jacomo
    Bristol University
  • Elena Armenise
    Environment Agency
  • Mathew R Brown
    University of Newcastle
  • Joshua T Bunce
    University of Newcastle
  • Graeme J Cameron
    Scottish Environment Protection Agency
  • Zhou Fang
    Biomathematics and Statistics Scotland
  • Kata Farkas
    Environment Centre Wales
  • Deidre F Gilpin
    Queen's University, Belfast
  • David W Graham
    University of Newcastle
  • Jasmine M S Grimsley
    UK Health Security Agency
  • Alwyn Hart
    Environment Agency
  • Till Hoffmann
    Imperial College London
  • Katherine J Jackson
    Environment Agency
  • David L Jones
    Environment Centre WalesUniversity of Western AustraliaUWA School of Agriculture and EnvironmentDepartment of Fisheries, Perth
  • Chris J Lilley
    UK Health Security Agency
  • John W McGrath
    Queen's University, Belfast
  • Jennifer M McKinley
    Queen's University, Belfast
  • Cormac McSparron
    Queen's University, Belfast
  • Behnam F Nejad
    Queen's University, Belfast
  • Mario Morvan
    University College London, Adelaide
  • Marcos Quintela-Baluja
    University of Newcastle
  • Adrian M I Roberts
    Biomathematics and Statistics ScotlandJames Clerk Maxwell BuildingPeter Guthrie Tait Road
  • Andrew C Singer
    UK Centre for Ecology and Hydrology, Penicuik
  • Célia Souque
    University Hospital, Oxford
  • Vanessa L Speight
    Sheffield University
  • Chris Sweetapple
    Exeter University
  • David Walker
    Centre for Environment, Fisheries and Aquaculture ScienceBarrack Road
  • Glenn Watts
    Environment Agency
  • Andrew Weightman
    Cardiff Metropolitan University
  • Barbara Kasprzyk-Hordern
    Bath Spa University

The COVID-19 pandemic has put unprecedented pressure on public health resources around the world. From adversity, opportunities have arisen to measure the state and dynamics of human disease at a scale not seen before. In the United Kingdom, the evidence that wastewater could be used to monitor the SARS-CoV-2 virus prompted the development of National wastewater surveillance programmes. The scale and pace of this work has proven to be unique in monitoring of virus dynamics at a national level, demonstrating the importance of wastewater-based epidemiology (WBE) for public health protection. Beyond COVID-19, it can provide additional value for monitoring and informing on a range of biological and chemical markers of human health. A discussion of measurement uncertainty associated with surveillance of wastewater, focusing on lessons-learned from the UK programmes monitoring COVID-19 is presented, showing that sources of uncertainty impacting measurement quality and interpretation of data for public health decision-making, are varied and complex. While some factors remain poorly understood, we present approaches taken by the UK programmes to manage and mitigate the more tractable sources of uncertainty. This work provides a platform to integrate uncertainty management into WBE activities as part of global One Health initiatives beyond the pandemic.

Original languageEnglish
Article number127456
JournalJournal of Hazardous Materials
Volume424
Issue numberPt B
Early online date8 Oct 2021
DOIs
Publication statusPublished - 15 Feb 2022
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