SECRET:  Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare

L. Mihaela Paun; Mitchel J. Colebank; Alyssa Taylor-LaPole; Mette S. Olufsen; William Ryan; Iain Murray; James M. Salter; Victor Applebaum; Michael Dunne; Jake Hollins; Louise Kimpton; Victoria Volodina; Xiaoyu Xiong; Dirk Husmeier

doi:10.1016/j.cma.2024.117193

SECRET: Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare

L. Mihaela Paun^*, Mitchel J. Colebank, Alyssa Taylor-LaPole, Mette S. Olufsen, William Ryan, Iain Murray, James M. Salter, Victor Applebaum, Michael Dunne, Jake Hollins, Louise Kimpton, Victoria Volodina, Xiaoyu Xiong, Dirk Husmeier

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

There have been impressive advances in the physical and mathematical modelling of complex physiological systems in the last few decades, with the potential to revolutionise personalised healthcare with patient-specific evidence-based diagnosis, risk assessment and treatment decision support using digital twins. However, practical progress and genuine clinical impact hinge on successful model calibration, parameter estimation and uncertainty quantification, which calls for novel innovative adaptions and methodological extensions of contemporary state-of-the-art inference techniques from Statistics and Machine Learning. In the present study, we focus on two computational fluid-dynamics (CFD) models of the blood systemic and pulmonary circulation. We discuss state-of-the-art emulation techniques based on deep learning and Gaussian processes, which are coupled with established inference techniques based on greedy optimisation, simulated annealing, Markov Chain Monte Carlo, History Matching and rejection sampling for computationally fast inference of unknown parameters of the CFD models from blood flow and pressure data. The inference task was set as a competitive challenge which the participants had to conduct within a limited time frame representative of clinical requirements. The performance of the methods was assessed independently and objectively by the challenge organisers, based on a ground truth that was unknown to the method developers. Our results indicate that for the systemic challenge, in which an idealised case of noise-free data was considered, the relative deviation from the ground-truth in parameter space ranges from 10−5% (highest-performing method) to 3% (lowest-performing method). For the pulmonary challenge, for which noisy data was generated, the performance ranges from 0.9% to 7% deviation for the parameter posterior mean, and from 35% to 570% deviation for the parameter posterior variance.

Original language	English
Article number	117193
Pages (from-to)	1-22
Number of pages	22
Journal	Computer Methods in Applied Mechanics and Engineering
Volume	430
Early online date	15 Jul 2024
DOIs	https://doi.org/10.1016/j.cma.2024.117193
Publication status	Published - Oct 2024

Keywords / Materials (for Non-textual outputs)

statistical emulation
parameter inference
uncertainty quantification
computational fluid-dynamics
personalised healthcare

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Paun, L. M., Colebank, M. J., Taylor-LaPole, A., Olufsen, M. S., Ryan, W., Murray, I., Salter, J. M., Applebaum, V., Dunne, M., Hollins, J., Kimpton, L., Volodina, V., Xiong, X., & Husmeier, D. (2024). SECRET: Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare. Computer Methods in Applied Mechanics and Engineering, 430, 1-22. Article 117193. https://doi.org/10.1016/j.cma.2024.117193

@article{b34e8d53eb934e3c9ac25ee300e38c5b,

title = "SECRET: Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare",

abstract = "There have been impressive advances in the physical and mathematical modelling of complex physiological systems in the last few decades, with the potential to revolutionise personalised healthcare with patient-specific evidence-based diagnosis, risk assessment and treatment decision support using digital twins. However, practical progress and genuine clinical impact hinge on successful model calibration, parameter estimation and uncertainty quantification, which calls for novel innovative adaptions and methodological extensions of contemporary state-of-the-art inference techniques from Statistics and Machine Learning. In the present study, we focus on two computational fluid-dynamics (CFD) models of the blood systemic and pulmonary circulation. We discuss state-of-the-art emulation techniques based on deep learning and Gaussian processes, which are coupled with established inference techniques based on greedy optimisation, simulated annealing, Markov Chain Monte Carlo, History Matching and rejection sampling for computationally fast inference of unknown parameters of the CFD models from blood flow and pressure data. The inference task was set as a competitive challenge which the participants had to conduct within a limited time frame representative of clinical requirements. The performance of the methods was assessed independently and objectively by the challenge organisers, based on a ground truth that was unknown to the method developers. Our results indicate that for the systemic challenge, in which an idealised case of noise-free data was considered, the relative deviation from the ground-truth in parameter space ranges from 10−5\% (highest-performing method) to 3\% (lowest-performing method). For the pulmonary challenge, for which noisy data was generated, the performance ranges from 0.9\% to 7\% deviation for the parameter posterior mean, and from 35\% to 570\% deviation for the parameter posterior variance.",

keywords = "statistical emulation, parameter inference, uncertainty quantification, computational fluid-dynamics, personalised healthcare",

author = "Paun, \{L. Mihaela\} and Colebank, \{Mitchel J.\} and Alyssa Taylor-LaPole and Olufsen, \{Mette S.\} and William Ryan and Iain Murray and Salter, \{James M.\} and Victor Applebaum and Michael Dunne and Jake Hollins and Louise Kimpton and Victoria Volodina and Xiaoyu Xiong and Dirk Husmeier",

year = "2024",

month = oct,

doi = "10.1016/j.cma.2024.117193",

language = "English",

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Paun, LM, Colebank, MJ, Taylor-LaPole, A, Olufsen, MS, Ryan, W, Murray, I, Salter, JM, Applebaum, V, Dunne, M, Hollins, J, Kimpton, L, Volodina, V, Xiong, X & Husmeier, D 2024, 'SECRET: Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare', Computer Methods in Applied Mechanics and Engineering, vol. 430, 117193, pp. 1-22. https://doi.org/10.1016/j.cma.2024.117193

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T2 - Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare

AU - Paun, L. Mihaela

AU - Colebank, Mitchel J.

AU - Taylor-LaPole, Alyssa

AU - Olufsen, Mette S.

AU - Ryan, William

AU - Murray, Iain

AU - Salter, James M.

AU - Applebaum, Victor

AU - Dunne, Michael

AU - Hollins, Jake

AU - Kimpton, Louise

AU - Volodina, Victoria

AU - Xiong, Xiaoyu

AU - Husmeier, Dirk

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N2 - There have been impressive advances in the physical and mathematical modelling of complex physiological systems in the last few decades, with the potential to revolutionise personalised healthcare with patient-specific evidence-based diagnosis, risk assessment and treatment decision support using digital twins. However, practical progress and genuine clinical impact hinge on successful model calibration, parameter estimation and uncertainty quantification, which calls for novel innovative adaptions and methodological extensions of contemporary state-of-the-art inference techniques from Statistics and Machine Learning. In the present study, we focus on two computational fluid-dynamics (CFD) models of the blood systemic and pulmonary circulation. We discuss state-of-the-art emulation techniques based on deep learning and Gaussian processes, which are coupled with established inference techniques based on greedy optimisation, simulated annealing, Markov Chain Monte Carlo, History Matching and rejection sampling for computationally fast inference of unknown parameters of the CFD models from blood flow and pressure data. The inference task was set as a competitive challenge which the participants had to conduct within a limited time frame representative of clinical requirements. The performance of the methods was assessed independently and objectively by the challenge organisers, based on a ground truth that was unknown to the method developers. Our results indicate that for the systemic challenge, in which an idealised case of noise-free data was considered, the relative deviation from the ground-truth in parameter space ranges from 10−5% (highest-performing method) to 3% (lowest-performing method). For the pulmonary challenge, for which noisy data was generated, the performance ranges from 0.9% to 7% deviation for the parameter posterior mean, and from 35% to 570% deviation for the parameter posterior variance.

AB - There have been impressive advances in the physical and mathematical modelling of complex physiological systems in the last few decades, with the potential to revolutionise personalised healthcare with patient-specific evidence-based diagnosis, risk assessment and treatment decision support using digital twins. However, practical progress and genuine clinical impact hinge on successful model calibration, parameter estimation and uncertainty quantification, which calls for novel innovative adaptions and methodological extensions of contemporary state-of-the-art inference techniques from Statistics and Machine Learning. In the present study, we focus on two computational fluid-dynamics (CFD) models of the blood systemic and pulmonary circulation. We discuss state-of-the-art emulation techniques based on deep learning and Gaussian processes, which are coupled with established inference techniques based on greedy optimisation, simulated annealing, Markov Chain Monte Carlo, History Matching and rejection sampling for computationally fast inference of unknown parameters of the CFD models from blood flow and pressure data. The inference task was set as a competitive challenge which the participants had to conduct within a limited time frame representative of clinical requirements. The performance of the methods was assessed independently and objectively by the challenge organisers, based on a ground truth that was unknown to the method developers. Our results indicate that for the systemic challenge, in which an idealised case of noise-free data was considered, the relative deviation from the ground-truth in parameter space ranges from 10−5% (highest-performing method) to 3% (lowest-performing method). For the pulmonary challenge, for which noisy data was generated, the performance ranges from 0.9% to 7% deviation for the parameter posterior mean, and from 35% to 570% deviation for the parameter posterior variance.

KW - statistical emulation

KW - parameter inference

KW - uncertainty quantification

KW - computational fluid-dynamics

KW - personalised healthcare

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DO - 10.1016/j.cma.2024.117193

M3 - Article

SN - 0045-7825

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JO - Computer Methods in Applied Mechanics and Engineering

JF - Computer Methods in Applied Mechanics and Engineering

M1 - 117193

ER -

SECRET: Statistical Emulation for Computational Reverse Engineering and Translation with applications in healthcare

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