Abstract
The stability of blood vessels is essential for maintaining the normal arterial function, and loss of stability may result in blood vessel tortuosity. The previous theoretical models of artery buckling were developed for circular vessel models, but arteries often demonstrate geometric variations such as elliptic and eccentric cross-sections. The objective of this study was to establish the theoretical foundation for noncircular blood vessel bent (i.e., lateral) buckling and simulate the buckling behavior of arteries with elliptic and eccentric cross-sections using finite element analysis. A generalized buckling equation for noncircular vessels was derived and finite element analysis was conducted to simulate the artery buckling behavior under lumen pressure and axial tension. The arterial wall was modeled as a thick-walled cylinder with hyper-elastic anisotropic and homogeneous material. The results demonstrated that oval or eccentric cross-section increases the critical buckling pressure of arteries and having both ovalness and eccentricity would further enhance the effect. We conclude that variations of the cross-sectional shape affect the critical pressure of arteries. These results improve the understanding of the mechanical stability of arteries.
Highlights
Mechanical stability of arteries is essential for normal arterial functioning
We developed the theoretical buckling equation for arteries with noncircular cross-sections and illustrated the effects of oval and eccentric cross-sections on the critical buckling pressure of arteries
The results demonstrated that arteries with concentric elliptical cross-section buckle in the direction of the minor diameter
Summary
Mechanical stability of arteries is essential for normal arterial functioning. tortuosity or kinking often occurs in blood vessels like coronary, carotid, or iliac arteries and veins due to high blood pressure, aging, atherosclerosis, diabetes, and other pathological changes in the arteries (Han, 2012). While there is a fair understanding of how these variations affect the wall stress under lumen pressure, little is known about how they will affect the stability of arteries. Previous computational analyses showed some effects of irregular geometry such as aneurysm, stenosis, oval, or eccentric cross-section (Datir et al, 2011; Lee et al, 2014; Sanyal and Han, 2015). It is not clear whether the buckling equations for circular cylindrical vessels can be applied to vessels with noncircular cross-sections. Further work is needed to better understand the buckling behavior of arteries with noncircular cross-sections
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