Abstract
The behavior of wall shear stress (WSS) was previously reported in a deformable aneurysm model using fluid-structure interactions. However, these findings have not been validated. In the present study, we examined the effect of elasticity (i.e., deformation) on wall shear stress inside a cerebral aneurysm at the apex of a bifurcation using particle image velocimetry in vitro. The flow model simulated a human patient-specific aneurysm at the apex of the bifurcation of the middle cerebral artery. Flow characteristics by wall elasticity were examined for both elastic and non-deformable aneurysm models with pulsatile blood flow. The absolute temporally- and spatially-averaged WSS along the bleb wall was smaller in the elastic model than that in the non-deformable model. This small WSS may be related to attenuation of the WSS. Further, the WSS gradient had a finite value near the stagnation point of the aneurysm dome. Finally, the WSS gradient near the stagnation point was slightly smaller in the elastic model than that in the non-deformable model. These data suggest that elasticity of the aneurysm wall can affect the progression and rupture of aneurysms via hemodynamic stress.
Highlights
IntroductionHemodynamic factors, including wall shear stress (WSS), oscillatory shear index, impingement region, and inflow jet, are known risk indicators for aneurysm progression and rupture [5] [6] [7] [8] [9]
We examined the effect of elasticity on wall shear stress inside a cerebral aneurysm at the apex of a bifurcation using particle image velocimetry in vitro
This plane is within a few degrees of perpendicular to the aneurysm wall lower bleb and is approximately symmetrical
Summary
Hemodynamic factors, including wall shear stress (WSS), oscillatory shear index, impingement region, and inflow jet, are known risk indicators for aneurysm progression and rupture [5] [6] [7] [8] [9]. Acevedo-Bolton et al used in vivo and in vitro phase contrast magnetic resonance imaging to validate CFD simulations in a patient-specific aneurysm model [10]. Sforza et al described the hemodynamic effects of perianeurysmal structures that caused displacement of the aneurysmal wall in the vertebral artery using yearly computed tomography angiography for 4 years [12]. Hoi et al validated the correlation of CFD simulation of a cerebral aneurysm with geometric variation in a rigid aneurysm model [13]
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