Uncertainty in model‐based treatment decision support: Applied to aortic valve stenosis

Meiburg, Roel; Huberts, Wouter; Rutten, Marcel; Vosse, Frans N. van de

doi:10.1002/cnm.3388

Cited by 6 publications

(2 citation statements)

References 60 publications

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“…Previous research has shown promising results for personalizing cardiovascular models [5][6][7][8][9][10][11][12] or predicting intervention effects in settings of localized cardiovascular disease and critical care [13,14]. In this work, we investigated the application of such models as a tool for monitoring of the left ventricle and systemic circulation in apparently healthy adults at risk of developing cardiovascular disease.…”

Section: Introductionmentioning

confidence: 99%

Monitoring variability in parameter estimates for lumped parameter models of the systemic circulation using longitudinal hemodynamic measurements

et al. 2023

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Background Physics-based cardiovascular models are only recently being considered for disease diagnosis or prognosis in clinical settings. These models depend on parameters representing the physical and physiological properties of the modeled system. Personalizing these parameters may give insight into the specific state of the individual and etiology of disease. We applied a relatively fast model optimization scheme based on common local optimization methods to two model formulations of the left ventricle and systemic circulation. One closed-loop model and one open-loop model were applied. Intermittently collected hemodynamic data from an exercise motivation study were used to personalize these models for data from 25 participants. The hemodynamic data were collected for each participant at the start, middle and end of the trial. We constructed two data sets for the participants, both consisting of systolic and diastolic brachial pressure, stroke volume, and left-ventricular outflow tract velocity traces paired with either the finger arterial pressure waveform or the carotid pressure waveform. Results We examined the feasibility of separating parameter estimates for the individual from population estimates by assessing the variability of estimates using the interquartile range. We found that the estimated parameter values were similar for the two model formulations, but that the systemic arterial compliance was significantly different ($$p < 10^{-6}$$ p < 10 - 6 ) depending on choice of pressure waveform. The estimates of systemic arterial compliance were on average higher when using the finger artery pressure waveform as compared to the carotid waveform. Conclusions We found that for the majority of participants, the variability of parameter estimates for a given participant on any measurement day was lower than the variability both across all measurement days combined for one participant, and for the population. This indicates that it is possible to identify individuals from the population, and that we can distinguish different measurement days for the individual participant by parameter values using the presented optimization method.

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Section: Introductionmentioning

confidence: 99%

Monitoring variability in parameter estimates for lumped parameter models of the systemic circulation using longitudinal hemodynamic measurements

et al. 2023

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“…Bayesian calibration was considered in Reference 13 to infer boundary conditions and the associated uncertainties in a virtual surgery prediction model and in Reference 14 for lumped parameter models of cardiovascular physiology. In Reference 15, calibration and propagation of uncertainties, where the latter was based on PC expansions, was discussed in a transaortic valve implantation context. In Reference 16, the authors carried out a sensitivity analysis in a preparation step to restrict the calibration procedure to the identifiable parameters of a model for the main pulmonary artery.…”

Section: Introductionmentioning

confidence: 99%

Surrogate‐based Bayesian calibration of biomechanical models with isotropic material behavior

Liu

Böl

2022

Numer Methods Biomed Eng

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This work introduces a computational methodology to calibrate material models in biomechanical applications under uncertainty. We adopt a Bayesian approach, which estimates the probability distributions of hyperelastic material parameters, based on force‐strain measurements. We approximate the parametric biomechanical model by combining a reduced order representation of the force response with a Polynomial Chaos expansion. The surrogate model allows to employ sampling‐intensive Markov chain Monte Carlo methods and provides an efficient way to estimate (generalized) Sobol coefficients. We use a Sobol sensitivity analysis to assess the influence of material parameters and present an iterative procedure to quantify the accuracy of the surrogate model as additional uncertainty during Bayesian updating. The methodology is illustrated with three cases, tensile experiments on heat‐induced whey protein gel, indentation experiments for oocytes and a manufactured example. Real experimental data are used for the calibration.

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Parameter estimation for closed-loop lumped parameter models of the systemic circulation using synthetic data

Bjørdalsbakke¹,

Sturdy²,

Hose³

et al. 2022

Mathematical Biosciences

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Uncertainty in model‐based treatment decision support: Applied to aortic valve stenosis

Cited by 6 publications

References 60 publications

Monitoring variability in parameter estimates for lumped parameter models of the systemic circulation using longitudinal hemodynamic measurements

Monitoring variability in parameter estimates for lumped parameter models of the systemic circulation using longitudinal hemodynamic measurements

Surrogate‐based Bayesian calibration of biomechanical models with isotropic material behavior

Parameter estimation for closed-loop lumped parameter models of the systemic circulation using synthetic data

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