PT - JOURNAL ARTICLE AU - G. Byrne AU - F. Mut AU - J. Cebral TI - Quantifying the Large-Scale Hemodynamics of Intracranial Aneurysms AID - 10.3174/ajnr.A3678 DP - 2014 Feb 01 TA - American Journal of Neuroradiology PG - 333--338 VI - 35 IP - 2 4099 - http://www.ajnr.org/content/35/2/333.short 4100 - http://www.ajnr.org/content/35/2/333.full SO - Am. J. Neuroradiol.2014 Feb 01; 35 AB - BACKGROUND AND PURPOSE: Hemodynamics play an important role in the mechanisms that govern the initiation, growth, and possible rupture of intracranial aneurysms. The purpose of this study was to objectively characterize these dynamics, classify them, and connect them to aneurysm rupture. MATERIALS AND METHODS: Image-based computational fluid dynamic simulations were used to re-create the hemodynamics of 210 patient-specific intracranial aneurysm geometries. The hemodynamics were then classified according to their spatial complexity and temporal stability by using quantities derived from vortex core lines and proper orthogonal decomposition. RESULTS: The quantitative classification was compared with a previous qualitative classification performed by visual inspection. Receiver operating characteristic curves provided area-under-the-curve estimates for spatial complexity (0.905) and temporal stability (0.85) to show that the 2 classifications were in agreement. Statistically significant differences were observed in the quantities describing the hemodynamics of ruptured and unruptured intracranial aneurysms. Specifically, ruptured aneurysms had more complex and more unstable flow patterns than unruptured aneurysms. Spatial complexity was more strongly associated with rupture than temporal stability. CONCLUSIONS: Complex-unstable blood flow dynamics characterized by longer core line length and higher entropy could induce biologic processes that predispose an aneurysm for rupture. IAintracranial aneurysmPODproper orthogonal decompositionCFDcomputational fluid dynamicROCreceiver operating characteristicAUCarea under the curve