Pulsatile flow simulations in abdominal aortic aneurysms showed that maximum wall shear stresses and gradients at peak flow correlate with time-average Reynolds numbers via a fourth-order polynomial.
Numerical predictions of blood flow patterns and hemodynamic stresses in Abdominal Aortic Aneurysms (AAAs) are performed in a two-aneurysm, axisymmetric, rigid wall model using the spectral element method. Physiologically realistic aortic blood flow is simulated under pulsatile conditions for the range of time-averaged Reynolds numbers 50< or =Re(m)< or =300, corresponding to a range of peak Reynolds numbers 262.5< or =Re(peak) < or = 1575. The vortex dynamics induced by pulsatile flow in AAAs is characterized by a sequence of five different flow phases in one period of the flow cycle. Hemodynamic disturbance is evaluated for a modified set of indicator functions, which include wall pressure (p(w)), wall shear stress (tau(w)), and Wall Shear Stress Gradient (WSSG). At peak flow, the highest shear stress and WSSG levels are obtained downstream of both aneurysms, in a pattern similar to that of steady flow. Maximum values of wall shear stresses and wall shear stress gradients obtained at peak flow are evaluated as a function of the time-average Reynolds number resulting in a fourth order polynomial correlation. A comparison between predictions for steady and pulsatile flow is presented, illustrating the importance of considering time-dependent flow for the evaluation of hemodynamic indicators.
Finol et al. (Tue,) conducted a other in Abdominal Aortic Aneurysms. Pulsatile flow simulation vs. Steady flow was evaluated on Hemodynamic disturbance (wall pressure, wall shear stress, and Wall Shear Stress Gradient). Pulsatile flow simulations in abdominal aortic aneurysms showed that maximum wall shear stresses and gradients at peak flow correlate with time-average Reynolds numbers via a fourth-order polynomial.