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Uncertainty of Population Risk Estimates for Pathogens Based on QMRA or Epidemiology: A Case Study of Campylobacter in the Netherlands

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  • Martijn Bouwknegt
  • Anne B. Knol
  • Jeroen P. van der Sluijs
  • Eric G. Evers

Abstract

Epidemiology and quantitative microbiological risk assessment are disciplines in which the same public health measures are estimated, but results differ frequently. If large, these differences can confuse public health policymakers. This article aims to identify uncertainty sources that explain apparent differences in estimates for Campylobacter spp. incidence and attribution in the Netherlands, based on four previous studies (two for each discipline). An uncertainty typology was used to identify uncertainty sources and the NUSAP method was applied to characterize the uncertainty and its influence on estimates. Model outcomes were subsequently calculated for alternative scenarios that simulated very different but realistic alternatives in parameter estimates, modeling, data handling, or analysis to obtain impressions of the total uncertainty. For the epidemiological assessment, 32 uncertainty sources were identified and for QMRA 67. Definitions (e.g., of a case) and study boundaries (e.g., of the studied pathogen) were identified as important drivers for the differences between the estimates of the original studies. The range in alternatively calculated estimates usually overlapped between disciplines, showing that proper appreciation of uncertainty can explain apparent differences between the initial estimates from both disciplines. Uncertainty was not estimated in the original QMRA studies and underestimated in the epidemiological studies. We advise to give appropriate attention to uncertainty in QMRA and epidemiological studies, even if only qualitatively, so that scientists and policymakers can interpret reported outcomes more correctly. Ideally, both disciplines are joined by merging their strong respective properties, leading to unified public health measures.

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  • Martijn Bouwknegt & Anne B. Knol & Jeroen P. van der Sluijs & Eric G. Evers, 2014. "Uncertainty of Population Risk Estimates for Pathogens Based on QMRA or Epidemiology: A Case Study of Campylobacter in the Netherlands," Risk Analysis, John Wiley & Sons, vol. 34(5), pages 847-864, May.
    • Handle: RePEc:wly:riskan:v:34:y:2014:i:5:p:847-864
    DOI: 10.1111/risa.12153
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    References listed on IDEAS

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    1. Maarten J. Nauta & Wilma F. Jacobs‐Reitsma & Arie H. Havelaar, 2007. "A Risk Assessment Model for Campylobacter in Broiler Meat," Risk Analysis, John Wiley & Sons, vol. 27(4), pages 845-861, August.
    2. Ides Boone & Yves Van der Stede & Jeroen Dewulf & Winy Messens & Marc Aerts & Georges Daube & Koen Mintiens, 2010. "NUSAP: a method to evaluate the quality of assumptions in quantitative microbial risk assessment," Journal of Risk Research, Taylor & Francis Journals, vol. 13(3), pages 337-352, April.
    3. Maarten Nauta & Ine Van Der Fels‐Klerx & Arie Havelaar, 2005. "A Poultry‐Processing Model for Quantitative Microbiological Risk Assessment," Risk Analysis, John Wiley & Sons, vol. 25(1), pages 85-98, February.
    4. Arie H. Havelaar & Marie‐Josee J. Mangen & Aline A. De Koeijer & Marc‐Jeroen Bogaardt & Eric G. Evers & Wilma F. Jacobs‐Reitsma & Wilfrid Van Pelt & Jaap A. Wagenaar & G. Ardine De Wit & Henk Van Der , 2007. "Effectiveness and Efficiency of Controlling Campylobacter on Broiler Chicken Meat," Risk Analysis, John Wiley & Sons, vol. 27(4), pages 831-844, August.
    5. Ides Boone & Yves Van der Stede & Kaatje Bollaerts & David Vose & Dominiek Maes & Jeroen Dewulf & Winy Messens & Georges Daube & Marc Aerts & Koen Mintiens, 2009. "NUSAP Method for Evaluating the Data Quality in a Quantitative Microbial Risk Assessment Model for Salmonella in the Pork Production Chain," Risk Analysis, John Wiley & Sons, vol. 29(4), pages 502-517, April.
    6. Wendelke E. A. Katsma & Aline A. De Koeijer & Wilma F. Jacobs‐Reitsma & Marie‐Josée J. Mangen & Jaap A. Wagenaar, 2007. "Assessing Interventions to Reduce the Risk of Campylobacter Prevalence in Broilers," Risk Analysis, John Wiley & Sons, vol. 27(4), pages 863-876, August.
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    1. Eric G. Evers & Martijn Bouwknegt, 2016. "Combining QMRA and Epidemiology to Estimate Campylobacteriosis Incidence," Risk Analysis, John Wiley & Sons, vol. 36(10), pages 1959-1968, October.

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