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Disparity in Quantitative Risk Assessment: A Review of Input Distributions

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  • Bruce S. Binkowitz
  • Daniel Wartenberg

Abstract

Monte Carlo simulations are commonplace in quantitative risk assessments (QRAs). Designed to propagate the variability and uncertainty associated with each individual exposure input parameter in a quantitative risk assessment, Monte Carlo methods statistically combine the individual parameter distributions to yield a single, overall distribution. Critical to such an assessment is the representativeness of each individual input distribution. The authors performed a literature review to collect and compare the distributions used in published QRAs for the parameters of body weight, food consumption, soil ingestion rates, breathing rates, and fluid intake. To provide a basis for comparison, all estimated exposure parameter distributions were evaluated with respect to four properties: consistency, accuracy, precision, and specificity. The results varied depending on the exposure parameter. Even where extensive, well‐collected data exist, investigators used a variety of different distributional shapes to approximate these data. Where such data do not exist, investigators have collected their own data, often leading to substantial disparity in parameter estimates and subsequent choice of distribution. The present findings indicate that more attention must be paid to the data underlying these distributional choices. More emphasis should be placed on sensitivity analyses, quantifying the impact of assumptions, and on discussion of sources of variation as part of the presentation of any risk assessment results. If such practices and disclosures are followed, it is believed that Monte Carlo simulations can greatly enhance the accuracy and appropriateness of specific risk assessments. Without such disclosures, researchers will be increasing the size of the risk assessment “black box,” a concern already raised by many critics of more traditional risk assessments.

Suggested Citation

  • Bruce S. Binkowitz & Daniel Wartenberg, 2001. "Disparity in Quantitative Risk Assessment: A Review of Input Distributions," Risk Analysis, John Wiley & Sons, vol. 21(1), pages 75-90, February.
  • Handle: RePEc:wly:riskan:v:21:y:2001:i:1:p:75-90
    DOI: 10.1111/0272-4332.211091
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    Cited by:

    1. Per Sander & Bo Bergbäck & Tomas Öberg, 2006. "Uncertain Numbers and Uncertainty in the Selection of Input Distributions—Consequences for a Probabilistic Risk Assessment of Contaminated Land," Risk Analysis, John Wiley & Sons, vol. 26(5), pages 1363-1375, October.
    2. Monika Filipsson & Tomas Öberg & Bo Bergbäck, 2011. "Variability and Uncertainty in Swedish Exposure Factors for Use in Quantitative Exposure Assessments," Risk Analysis, John Wiley & Sons, vol. 31(1), pages 108-119, January.
    3. Kai Lessmann & Andreas Beyer & Jörg Klasmeier & Michael Matthies, 2005. "Influence of Distributional Shape of Substance Parameters on Exposure Model Output," Risk Analysis, John Wiley & Sons, vol. 25(5), pages 1137-1145, October.
    4. Richard R. Lester & Laura C. Green & Igor Linkov, 2007. "Site‐Specific Applications of Probabilistic Health Risk Assessment: Review of the Literature Since 2000," Risk Analysis, John Wiley & Sons, vol. 27(3), pages 635-658, June.
    5. Martí Nadal & Vikas Kumar & Marta Schuhmacher & José L. Domingo, 2008. "Applicability of a Neuroprobabilistic Integral Risk Index for the Environmental Management of Polluted Areas: A Case Study," Risk Analysis, John Wiley & Sons, vol. 28(2), pages 271-286, April.
    6. Randy L. Maddalena & Thomas E. McKone & Michael D. Sohn, 2004. "Standardized Approach for Developing Probabilistic Exposure Factor Distributions," Risk Analysis, John Wiley & Sons, vol. 24(5), pages 1185-1199, October.
    7. Gilberto Montibeller & L. Alberto Franco & Ashley Carreras, 2020. "A Risk Analysis Framework for Prioritizing and Managing Biosecurity Threats," Risk Analysis, John Wiley & Sons, vol. 40(11), pages 2462-2477, November.

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