Bayesian growth models: evaluation of robust Bayesian mixed-effects models of longitudinal childhood BMI
Bayesian growth models: evaluation of robust Bayesian mixed-effects models of longitudinal childhood BMI
This paper introduces Bayesian mixed-effects models (BMM) for characterizing childhood BMI trajectories from birth to 13 years of age and proposes a Bayesian marginal posterior sampling approach to decompose BMI variance into residuals, fixed, and random effects contributions. This is one of the first studies to rigorously evaluate Fractional Polynomials (FP), Reed2 (R2), and Breakpoint (BP) models using data from three longitudinal cohorts, assessing performance based on bias, heteroskedasticity, and Bayesian goodness-of-fit.
Results indicate that model choice matters, as FP and Reed2 models generally outperform BP models in capturing the complex non-linearity of BMI trajectories, with residual errors accounting for less than 10\% of BMI variance. Among five likelihoods considered, the Laplace distribution provided the most robust fit. The residual correlation structures were complex and non‑stationary. A normal likelihood with a stationary correlation function improved fit, but less so than an independent Laplace likelihood. Most BMI variance was explained by random effects, underscoring the importance of personalized approaches in childhood obesity.
This study rigorously evaluates competing BMI trajectory models and introduces a robust BMM library that improve modeling of abnormal trajectories. These results may inform early identification of children at risk, targeted intervention selection, and intervention efficacy monitoring.
Couto Alves, Alex
87b9179e-abde-4ca5-abfc-4b7c5ac8b03b
2025
Couto Alves, Alex
87b9179e-abde-4ca5-abfc-4b7c5ac8b03b
(2025)
Bayesian growth models: evaluation of robust Bayesian mixed-effects models of longitudinal childhood BMI.
Gitlab
[Software]
Abstract
This paper introduces Bayesian mixed-effects models (BMM) for characterizing childhood BMI trajectories from birth to 13 years of age and proposes a Bayesian marginal posterior sampling approach to decompose BMI variance into residuals, fixed, and random effects contributions. This is one of the first studies to rigorously evaluate Fractional Polynomials (FP), Reed2 (R2), and Breakpoint (BP) models using data from three longitudinal cohorts, assessing performance based on bias, heteroskedasticity, and Bayesian goodness-of-fit.
Results indicate that model choice matters, as FP and Reed2 models generally outperform BP models in capturing the complex non-linearity of BMI trajectories, with residual errors accounting for less than 10\% of BMI variance. Among five likelihoods considered, the Laplace distribution provided the most robust fit. The residual correlation structures were complex and non‑stationary. A normal likelihood with a stationary correlation function improved fit, but less so than an independent Laplace likelihood. Most BMI variance was explained by random effects, underscoring the importance of personalized approaches in childhood obesity.
This study rigorously evaluates competing BMI trajectory models and introduces a robust BMM library that improve modeling of abnormal trajectories. These results may inform early identification of children at risk, targeted intervention selection, and intervention efficacy monitoring.
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Published date: 2025
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Local EPrints ID: 510050
URI: http://eprints.soton.ac.uk/id/eprint/510050
PURE UUID: fbea0389-3dee-4138-8931-05d970e374d5
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Date deposited: 16 Mar 2026 17:46
Last modified: 17 Mar 2026 03:12
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Author:
Alex Couto Alves
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