Bayesian Parameter Balancing Enables Robust and Consistent Estimation of Kinetic Parameter Uncertainty
Nguyen, T.; H. Ho, B.; Pan, M.; Flegg, J. A.; MCDONALD, M.; Drovandi, C.
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MotivationKinetic models are central to systems biology, but enzyme-kinetic parameters compiled from the literature and databases are often incomplete, inconsistent, and measured under heterogeneous conditions. Classical parameter balancing helps infer missing parameters, yet it often lacks calibrated uncertainty, robustness to misspecification, and explicit treatment of source-level heterogeneity. ResultsWe develop a formal Bayesian parameter balancing framework that enforces thermodynamic constraints, estimates full posterior uncertainty, and validates calibration using leave-one-out cross-validation and posterior-predictive coverage. Beyond the classical Gaussian formulation, we introduce robust Student-t and skewed error models to improve reliability under outliers and model misspecification, and incorporate random effects to account for source or group variability across studies. The resulting approach yields thermody-namically consistent parameter sets with well-calibrated credible intervals on held-out data, offering a Bayesian parameter balancing approach useful to systems biology researchers.
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