4.5 Article

Subject-specific one-dimensional fluid dynamics model of chronic thromboembolic pulmonary hypertension

Journal

Publisher

SPRINGER HEIDELBERG
DOI: 10.1007/s10237-023-01786-3

Keywords

CTEPH; 1D CFD; Hemodynamics modeling; Wall shear stress

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This article investigates the impact of chronic thromboembolic pulmonary hypertension (CTEPH) on pulmonary artery stiffness and hemodynamics using computational fluid dynamics. The results demonstrate that CTEPH increases pulmonary artery wall stiffness and decreases blood flow shear stress.
Chronic thromboembolic pulmonary hypertension (CTEPH) develops due to the accumulation of blood clots in the lung vasculature that obstructs flow and increases pressure. The mechanobiological factors that drive progression of CTEPH are not understood, in part because mechanical and hemodynamic changes in the small pulmonary arteries due to CTEPH are not easily measurable. Using previously published hemodynamic measurements and imaging from a large animal model of CTEPH, we applied a subject-specific one-dimensional (1D) computational fluid dynamic (CFD) approach to investigate the impact of CTEPH on pulmonary artery stiffening, time-averaged wall shear stress (TAWSS), and oscillatory shear index (OSI) in extralobar (main, right, and left) pulmonary arteries and intralobar (distal to the extralobar) arteries. Our results demonstrate that CTEPH increases pulmonary artery wall stiffness and decreases TAWSS in extralobar and intralobar arteries. Moreover, CTEPH increases the percentage of the intralobar arterial network with both low TAWSS and high OSI, quantified by the novel parameter phi, which is related to thrombogenicity. Our analysis reveals a strong positive correlation between increases in mean pulmonary artery pressure (mPAP) and phi from baseline to CTEPH in individual subjects, which supports the suggestion that increased phi drives disease severity. This subject-specific experimental-computational framework shows potential as a predictor of the impact of CTEPH on pulmonary arterial hemodynamics and pulmonary vascular mechanics. By leveraging advanced modeling techniques and calibrated model parameters, we predict spatial distributions of flow and pressure, from which we can compute potential physiomarkers of disease progression. Ultimately, this approach can lead to more spatially targeted interventions that address the needs of individual CTEPH patients.

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