Abstract
Aortic valve calcification is an important cardiovascular disorder that deteriorates the accurate functioning of the valve leaflets. The increasing stiffness due to the calcification prevents the complete closure of the valve and therefore leads to significant hemodynamic alterations. Computational fluid dynamics (CFD) modeling enables the investigation of the entire flow domain by processing medical images from aortic valve patients. In this study, we computationally modeled and simulated a 3D aortic valve using patient-specific dimensions of the aortic root and aortic sinus. Leaflet stiffness is deteriorated in aortic valve disease due to calcification. In order to investigate the influence of leaflet calcification on flow dynamics, three different leaflet-stiffness values were considered for healthy, mildly calcified, and severely calcified leaflets. Time-dependent CFD results were used for applying the Lagrangian coherent structures (LCS) technique by performing finite-time Lyapunov exponent (FTLE) computations along with Lagrangian particle residence time (PRT) analysis to identify unique vortex structures at the front and backside of the leaflets. Obtained results indicated that the peak flow velocity at the valve orifice increased with the calcification rate. For the healthy aortic valve, a low-pressure field was observed at the leaflet tips. This low-pressure field gradually expanded through the entire aortic sinus as the calcification level increased. FTLE field plots of the healthy and calcified valves showed a variety of differences in terms of flow structures. When the number of fluid particles in the healthy valve model was taken as reference, 1.59 and 1.74 times more particles accumulated in the mildly and severely calcified valves, respectively, indicating that the calcified valves were not sufficiently opened to allow normal mass flow rates.
Highlights
High-velocity jet flow occurred at the valve orifice, and as a result of limited leaflet deformation, the total duration of jet flow increased with increasing calcification
For a severely calcified aortic valve, high negative pressure dominated almost the entire aortic sinus, with a value of around −400 Pa. These results indicated that the flow hemodynamics were significantly altered in the case of aortic valve calcification
The first time step in the normal flow corresponded to the 400th time step in the backward finitetime Lyapunov exponent (FTLE) analysis, since the calculations were made from the last step in the backward FTLE analysis to the first step in the direction of the inlet boundary [51]
Summary
The aortic valve is composed of three half-moon-shaped leaflets, which open during the left ventricle contraction to provide blood supply to the aorta and immediately close to prevent any backflow after the blood ejection. Accurate functioning of these aortic valves is critically essential for the health of the cardiovascular system. The functional deterioration of the aortic leaflets leads to significant hemodynamic alterations, especially around the valvular region. Clinically monitoring these hemodynamic changes within the entire valve geometry is a challenge for clinicians
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