A computational framework modeling the pulmonary arterial tree demonstrated that non-uniform mechanical behavior and hemodynamic feedback are essential for simulating PAH disease time courses.
A novel computational framework successfully models pulmonary arterial remodeling and hemodynamics, offering a tool to predict disease evolution in pulmonary arterial hypertension.
Hemodynamic loading is known to contribute to the development and progression of pulmonary arterial hypertension (PAH). This loading drives changes in mechanobiological stimuli that affect cellular phenotypes and lead to pulmonary vascular remodeling. Computational models have been used to simulate mechanobiological metrics of interest, such as wall shear stress, at single time points for PAH patients. However, there is a need for new approaches that simulate disease evolution to allow for prediction of long-term outcomes. In this work, we develop a framework that models the pulmonary arterial tree through adaptive and maladaptive responses to mechanical and biological perturbations. We coupled a constrained mixture theory-based growth and remodeling framework for the vessel wall with a morphometric tree representation of the pulmonary arterial vasculature. We show that non-uniform mechanical behavior is important to establish the homeostatic state of the pulmonary arterial tree, and that hemodynamic feedback is essential for simulating disease time courses. We also employed a series of maladaptive constitutive models, such as smooth muscle hyperproliferation and stiffening, to identify critical contributors to development of PAH phenotypes. Together, these simulations demonstrate an important step towards predicting changes in metrics of clinical interest for PAH patients and simulating potential treatment approaches.
Szafron et al. (Fri,) conducted a other in Pulmonary arterial hypertension (PAH). Computational growth and remodeling framework was evaluated on Simulation of disease evolution and mechanobiological metrics. A computational framework modeling the pulmonary arterial tree demonstrated that non-uniform mechanical behavior and hemodynamic feedback are essential for simulating PAH disease time courses.
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