Intimal Growth in Cylindrical Arteries: Impact of Anisotropic Growth on Glagov Remodeling

TL;DR

This study models how anisotropic growth affects arterial remodeling, showing it produces more realistic stress profiles and remodeling curves consistent with experimental data, compared to isotropic growth.

Contribution

It introduces a morphoelasticity-based model for anisotropic arterial growth and demonstrates its impact on vessel remodeling and stress distribution.

Findings

Anisotropic growth results in lower strain energy than isotropic growth.

The model produces Glagov curves aligning better with experimental observations.

Anisotropic growth leads to more realistic stress profiles in arteries.

Abstract

In this paper we investigate the effect of anisotropic growth on Glagov remodeling in different cases: pure radial, pure circumferential, pure axial and general anisotropic growth. We use the theory of morphoelasticity on an axisymmetric arterial domain. For each case we explore their specific effect on the Glagov curves and stress and provide the changes in collagen fibers angles in the intima, media and adventitia. In addition, we compare the strain energy produced by growth in radial, circumferential and axial direction and deduce that anisotropic growth generally leads to lower strain energy than isotropic growth. Therefore, we explore an anisotropic growth regime and use the resulting model to simulate vessel remodeling. We compare the Glagov curves, stress, energies and fiber angles in the anisotropic case with those of the isotropic case. Our results show that the anisotropic growth produces a remodeling curve more consistent with Glagov's experimental data with gentler outward remodeling and more realistic stress profiles.