Abstract
This study presents a patient-specific computational analysis of hemodynamic alterations induced by stent-assisted deformation in five cerebral aneurysm models. Using high-fidelity geometrical reconstructions and computational fluid dynamics (CFD) simulations, the effects of parent vessel deformation on Wall Shear Stress (WSS), Oscillatory Shear Index (OSI), and blood flow velocity were systematically evaluated across distinct aneurysm geometries. The results demonstrate that each model exhibited a unique hemodynamic response to deformation. Model A showed an increase in WSS and OSI, indicating enhanced flow instability; Model B remained largely insensitive, displaying negligible hemodynamic variation; Model C experienced reductions in OSI and velocity, suggesting a stabilized intra-aneurysmal environment; Model D revealed a gradual decrease and redistribution of axial velocity, reflecting attenuation of inflow momentum; and Model E exhibited a pronounced redirection of the inflow jet and asymmetric velocity field, accompanied by a moderate decline in flow magnitude. Overall, these findings emphasize the critical role of aneurysm morphology and vessel curvature in modulating post-treatment hemodynamics and reinforce the need for patient-specific computational modeling to guide stent design and placement for improved clinical outcomes in cerebral aneurysm management.