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Accurately Reflecting Uncertainty When Using Patient-Level Simulation Models to Extrapolate Clinical Trial Data

Author

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  • Helen A. Dakin

    (Nuffield Department of Population, Health Economics Research Centre, University of Oxford, Oxford, Oxfordshire, UK)

  • José Leal

    (Nuffield Department of Population, Health Economics Research Centre, University of Oxford, Oxford, Oxfordshire, UK)

  • Andrew Briggs

    (Department of Health Services Research & Policy, London School of Hygiene and Tropical Medicine, London, UK)

  • Philip Clarke

    (Nuffield Department of Population, Health Economics Research Centre, University of Oxford, Oxford, Oxfordshire, UK)

  • Rury R. Holman

    (Diabetes Trials Unit, University of Oxford, Oxford, Oxfordshire, UK)

  • Alastair Gray

    (Nuffield Department of Population, Health Economics Research Centre, University of Oxford, Oxford, Oxfordshire, UK)

Abstract

Introduction. Patient-level simulation models facilitate extrapolation of clinical trial data while allowing for heterogeneity, prior history, and nonlinearity. However, combining different types of uncertainty around within-trial and extrapolated results remains challenging. Methods. We tested 4 methods to combine parameter uncertainty (around the regression coefficients used to predict future events) with sampling uncertainty (uncertainty around mean risk factors within the finite sample whose outcomes are being predicted and the effect of treatment on these risk factors). We compared these 4 methods using a simulation study based on an economic evaluation extrapolating the AFORRD randomized controlled trial using the UK Prospective Diabetes Study Outcomes Model version 2. This established type 2 diabetes model predicts patient-level health outcomes and costs. Results. The 95% confidence intervals around life years gained gave 25% coverage when sampling uncertainty was excluded (i.e., 25% of 95% confidence intervals contained the “true†value). Allowing for sampling uncertainty as well as parameter uncertainty widened confidence intervals by 6.3-fold and gave 96.3% coverage. Methods adjusting for baseline risk factors that combine sampling and parameter uncertainty overcame the bias that can result from between-group baseline imbalance and gave confidence intervals around 50% wider than those just considering parameter uncertainty, with 99.8% coverage. Conclusions. Analyses extrapolating data for individual trial participants should include both sampling uncertainty and parameter uncertainty and should adjust for any imbalance in baseline covariates.

Suggested Citation

  • Helen A. Dakin & José Leal & Andrew Briggs & Philip Clarke & Rury R. Holman & Alastair Gray, 2020. "Accurately Reflecting Uncertainty When Using Patient-Level Simulation Models to Extrapolate Clinical Trial Data," Medical Decision Making, , vol. 40(4), pages 460-473, May.
    • Handle: RePEc:sae:medema:v:40:y:2020:i:4:p:460-473
    DOI: 10.1177/0272989X20916442
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    References listed on IDEAS

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    1. Marina Antoniou & Céu Mateus & Bruce Hollingsworth & Andrew Titman, 2024. "A Systematic Review of Methodologies Used in Models of the Treatment of Diabetes Mellitus," PharmacoEconomics, Springer, vol. 42(1), pages 19-40, January.
    2. David D. Kim & Lu Wang & Brianna N. Lauren & Junxiu Liu & Matti Marklund & Yujin Lee & Renata Micha & Dariush Mozaffarian & John B. Wong, 2023. "Development and Validation of the US Diabetes, Obesity, Cardiovascular Disease Microsimulation (DOC-M) Model: Health Disparity and Economic Impact Model," Medical Decision Making, , vol. 43(7-8), pages 930-948, October.
    3. Dixon, Padraig & Harrison, Sean & Hollingworth, William & Davies, Neil M. & Davey Smith, George, 2022. "Estimating the causal effect of liability to disease on healthcare costs using Mendelian Randomization," Economics & Human Biology, Elsevier, vol. 46(C).

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