Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension

Christopher Tossas-Betancourt; Nathan Y. Li; Sheikh M. Shavik; Katherine Afton; Brian Beckman; Wendy Whiteside; Mary K. Olive; Heang M. Lim; Jimmy C. Lu; Christina M. Phelps; Robert J. Gajarski; Simon Lee; David A. Nordsletten; Ronald G. Grifka; Adam L. Dorfman; Seungik Baek; Lik Chuan Lee; C. Alberto Figueroa

doi:10.3389/fphys.2022.958734

Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension

Christopher Tossas-Betancourt, Nathan Y. Li, Sheikh M. Shavik, Katherine Afton, Brian Beckman, Wendy Whiteside, Mary K. Olive, Heang M. Lim, Jimmy C. Lu, Christina M. Phelps, Robert J. Gajarski, Simon Lee, David A. Nordsletten, Ronald G. Grifka, Adam L. Dorfman, Seungik Baek, Lik Chuan Lee, C. Alberto Figueroa^*

^*Corresponding author for this work

Biomedical Engineering Department

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

Abstract

Pulmonary arterial hypertension (PAH) is a complex disease involving increased resistance in the pulmonary arteries and subsequent right ventricular (RV) remodeling. Ventricular-arterial interactions are fundamental to PAH pathophysiology but are rarely captured in computational models. It is important to identify metrics that capture and quantify these interactions to inform our understanding of this disease as well as potentially facilitate patient stratification. Towards this end, we developed and calibrated two multi-scale high-resolution closed-loop computational models using open-source software: a high-resolution arterial model implemented using CRIMSON, and a high-resolution ventricular model implemented using FEniCS. Models were constructed with clinical data including non-invasive imaging and invasive hemodynamic measurements from a cohort of pediatric PAH patients. A contribution of this work is the discussion of inconsistencies in anatomical and hemodynamic data routinely acquired in PAH patients. We proposed and implemented strategies to mitigate these inconsistencies, and subsequently use this data to inform and calibrate computational models of the ventricles and large arteries. Computational models based on adjusted clinical data were calibrated until the simulated results for the high-resolution arterial models matched within 10% of adjusted data consisting of pressure and flow, whereas the high-resolution ventricular models were calibrated until simulation results matched adjusted data of volume and pressure waveforms within 10%. A statistical analysis was performed to correlate numerous data-derived and model-derived metrics with clinically assessed disease severity. Several model-derived metrics were strongly correlated with clinically assessed disease severity, suggesting that computational models may aid in assessing PAH severity.

Original language	English
Article number	958734
Journal	Frontiers in Physiology
Volume	13
DOIs	https://doi.org/10.3389/fphys.2022.958734
Publication status	Published - 7 Sept 2022

Keywords

arterial hemodynamics
biomechanics
computational modeling
patient stratification
pulmonary arterial hypertension
ventricular mechanics
ventricular-arterial coupling

Access to Document

10.3389/fphys.2022.958734

Cite this

Tossas-Betancourt, C., Li, N. Y., Shavik, S. M., Afton, K., Beckman, B., Whiteside, W., Olive, M. K., Lim, H. M., Lu, J. C., Phelps, C. M., Gajarski, R. J., Lee, S., Nordsletten, D. A., Grifka, R. G., Dorfman, A. L., Baek, S., Lee, L. C., & Figueroa, C. A. (2022). Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension. Frontiers in Physiology, 13, Article 958734. https://doi.org/10.3389/fphys.2022.958734

@article{ca12ff2f2fe9457c813eda405c305aff,

title = "Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension",

abstract = "Pulmonary arterial hypertension (PAH) is a complex disease involving increased resistance in the pulmonary arteries and subsequent right ventricular (RV) remodeling. Ventricular-arterial interactions are fundamental to PAH pathophysiology but are rarely captured in computational models. It is important to identify metrics that capture and quantify these interactions to inform our understanding of this disease as well as potentially facilitate patient stratification. Towards this end, we developed and calibrated two multi-scale high-resolution closed-loop computational models using open-source software: a high-resolution arterial model implemented using CRIMSON, and a high-resolution ventricular model implemented using FEniCS. Models were constructed with clinical data including non-invasive imaging and invasive hemodynamic measurements from a cohort of pediatric PAH patients. A contribution of this work is the discussion of inconsistencies in anatomical and hemodynamic data routinely acquired in PAH patients. We proposed and implemented strategies to mitigate these inconsistencies, and subsequently use this data to inform and calibrate computational models of the ventricles and large arteries. Computational models based on adjusted clinical data were calibrated until the simulated results for the high-resolution arterial models matched within 10% of adjusted data consisting of pressure and flow, whereas the high-resolution ventricular models were calibrated until simulation results matched adjusted data of volume and pressure waveforms within 10%. A statistical analysis was performed to correlate numerous data-derived and model-derived metrics with clinically assessed disease severity. Several model-derived metrics were strongly correlated with clinically assessed disease severity, suggesting that computational models may aid in assessing PAH severity.",

keywords = "arterial hemodynamics, biomechanics, computational modeling, patient stratification, pulmonary arterial hypertension, ventricular mechanics, ventricular-arterial coupling",

author = "Christopher Tossas-Betancourt and Li, {Nathan Y.} and Shavik, {Sheikh M.} and Katherine Afton and Brian Beckman and Wendy Whiteside and Olive, {Mary K.} and Lim, {Heang M.} and Lu, {Jimmy C.} and Phelps, {Christina M.} and Gajarski, {Robert J.} and Simon Lee and Nordsletten, {David A.} and Grifka, {Ronald G.} and Dorfman, {Adam L.} and Seungik Baek and Lee, {Lik Chuan} and Figueroa, {C. Alberto}",

note = "Funding Information: This work was supported by the National Institutes of Health (U01 HL135842), Edward B. Diethrich Professorship, and the Frankel Cardiovascular Center. Computing resources were provided by the National Science Foundation (Grant 1531752): Acquisition of Conflux, A Novel Platform for Data-Driven Computational Physics (Tech. Monitor: Ed Walker). CT-B acknowledges financial support from the National Science Foundation Graduate Research Fellowship Program (DGE1256260) and the University of Michigan Rackham Merit Fellowship. Publisher Copyright: Copyright {\textcopyright} 2022 Tossas-Betancourt, Li, Shavik, Afton, Beckman, Whiteside, Olive, Lim, Lu, Phelps, Gajarski, Lee, Nordsletten, Grifka, Dorfman, Baek, Lee and Figueroa.",

year = "2022",

month = sep,

day = "7",

doi = "10.3389/fphys.2022.958734",

language = "English",

volume = "13",

journal = "Frontiers in Physiology",

issn = "1664-042X",

publisher = "Frontiers",

}

Tossas-Betancourt, C, Li, NY, Shavik, SM, Afton, K, Beckman, B, Whiteside, W, Olive, MK, Lim, HM, Lu, JC, Phelps, CM, Gajarski, RJ, Lee, S, Nordsletten, DA, Grifka, RG, Dorfman, AL, Baek, S, Lee, LC & Figueroa, CA 2022, 'Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension', Frontiers in Physiology, vol. 13, 958734. https://doi.org/10.3389/fphys.2022.958734

TY - JOUR

T1 - Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension

AU - Tossas-Betancourt, Christopher

AU - Li, Nathan Y.

AU - Shavik, Sheikh M.

AU - Afton, Katherine

AU - Beckman, Brian

AU - Whiteside, Wendy

AU - Olive, Mary K.

AU - Lim, Heang M.

AU - Lu, Jimmy C.

AU - Phelps, Christina M.

AU - Gajarski, Robert J.

AU - Lee, Simon

AU - Nordsletten, David A.

AU - Grifka, Ronald G.

AU - Dorfman, Adam L.

AU - Baek, Seungik

AU - Lee, Lik Chuan

AU - Figueroa, C. Alberto

N1 - Funding Information: This work was supported by the National Institutes of Health (U01 HL135842), Edward B. Diethrich Professorship, and the Frankel Cardiovascular Center. Computing resources were provided by the National Science Foundation (Grant 1531752): Acquisition of Conflux, A Novel Platform for Data-Driven Computational Physics (Tech. Monitor: Ed Walker). CT-B acknowledges financial support from the National Science Foundation Graduate Research Fellowship Program (DGE1256260) and the University of Michigan Rackham Merit Fellowship. Publisher Copyright: Copyright © 2022 Tossas-Betancourt, Li, Shavik, Afton, Beckman, Whiteside, Olive, Lim, Lu, Phelps, Gajarski, Lee, Nordsletten, Grifka, Dorfman, Baek, Lee and Figueroa.

PY - 2022/9/7

Y1 - 2022/9/7

N2 - Pulmonary arterial hypertension (PAH) is a complex disease involving increased resistance in the pulmonary arteries and subsequent right ventricular (RV) remodeling. Ventricular-arterial interactions are fundamental to PAH pathophysiology but are rarely captured in computational models. It is important to identify metrics that capture and quantify these interactions to inform our understanding of this disease as well as potentially facilitate patient stratification. Towards this end, we developed and calibrated two multi-scale high-resolution closed-loop computational models using open-source software: a high-resolution arterial model implemented using CRIMSON, and a high-resolution ventricular model implemented using FEniCS. Models were constructed with clinical data including non-invasive imaging and invasive hemodynamic measurements from a cohort of pediatric PAH patients. A contribution of this work is the discussion of inconsistencies in anatomical and hemodynamic data routinely acquired in PAH patients. We proposed and implemented strategies to mitigate these inconsistencies, and subsequently use this data to inform and calibrate computational models of the ventricles and large arteries. Computational models based on adjusted clinical data were calibrated until the simulated results for the high-resolution arterial models matched within 10% of adjusted data consisting of pressure and flow, whereas the high-resolution ventricular models were calibrated until simulation results matched adjusted data of volume and pressure waveforms within 10%. A statistical analysis was performed to correlate numerous data-derived and model-derived metrics with clinically assessed disease severity. Several model-derived metrics were strongly correlated with clinically assessed disease severity, suggesting that computational models may aid in assessing PAH severity.

AB - Pulmonary arterial hypertension (PAH) is a complex disease involving increased resistance in the pulmonary arteries and subsequent right ventricular (RV) remodeling. Ventricular-arterial interactions are fundamental to PAH pathophysiology but are rarely captured in computational models. It is important to identify metrics that capture and quantify these interactions to inform our understanding of this disease as well as potentially facilitate patient stratification. Towards this end, we developed and calibrated two multi-scale high-resolution closed-loop computational models using open-source software: a high-resolution arterial model implemented using CRIMSON, and a high-resolution ventricular model implemented using FEniCS. Models were constructed with clinical data including non-invasive imaging and invasive hemodynamic measurements from a cohort of pediatric PAH patients. A contribution of this work is the discussion of inconsistencies in anatomical and hemodynamic data routinely acquired in PAH patients. We proposed and implemented strategies to mitigate these inconsistencies, and subsequently use this data to inform and calibrate computational models of the ventricles and large arteries. Computational models based on adjusted clinical data were calibrated until the simulated results for the high-resolution arterial models matched within 10% of adjusted data consisting of pressure and flow, whereas the high-resolution ventricular models were calibrated until simulation results matched adjusted data of volume and pressure waveforms within 10%. A statistical analysis was performed to correlate numerous data-derived and model-derived metrics with clinically assessed disease severity. Several model-derived metrics were strongly correlated with clinically assessed disease severity, suggesting that computational models may aid in assessing PAH severity.

KW - arterial hemodynamics

KW - biomechanics

KW - computational modeling

KW - patient stratification

KW - pulmonary arterial hypertension

KW - ventricular mechanics

KW - ventricular-arterial coupling

UR - http://www.scopus.com/inward/record.url?scp=85138406420&partnerID=8YFLogxK

U2 - 10.3389/fphys.2022.958734

DO - 10.3389/fphys.2022.958734

M3 - Article

AN - SCOPUS:85138406420

SN - 1664-042X

VL - 13

JO - Frontiers in Physiology

JF - Frontiers in Physiology

M1 - 958734

ER -

Data-driven computational models of ventricular-arterial hemodynamics in pediatric pulmonary arterial hypertension

Abstract

Keywords

Access to Document

Other files and links

Cite this