RT Journal Article
SR Electronic
T1 Risk Analysis of Unruptured Aneurysms Using Computational Fluid Dynamics Technology: Preliminary Results
JF American Journal of Neuroradiology
JO Am. J. Neuroradiol.
FD American Society of Neuroradiology
SP 1948
OP 1955
DO 10.3174/ajnr.A2655
VO 32
IS 10
A1 Y. Qian
A1 H. Takao
A1 M. Umezu
A1 Y. Murayama
YR 2011
UL http://www.ajnr.org/content/32/10/1948.abstract
AB BACKGROUND AND PURPOSE: The decision as to the treatment of incidental IAs is complex. There are no certain quantitative methods that can be used to evaluate the risk of rupture in IAs. In recent years, CFD technology has been recognized as a potential risk-analysis tool. The aim of this article was to propose a hemodynamic parameter, EL, to determine the effects of stable unruptured aneurysms and of those that ruptured during the subsequent observation period. MATERIALS AND METHODS: Four incidentally found ICA-PcomA aneurysms ruptured during the period of observation (ruptured-IAs). Another 26 unruptured aneurysms (stable-IAs) with similar location, size, and morphology were compared for the differences in hemodynamic factors, such as EL and WSS. RESULTS: The EL calculated at the ruptured-IAs was nearly 5 times higher on average than that at the stable-IAs (ruptured, 0.00374 ± 0.0011; stable, 0.000745 ± 0.0001 mW/mm3, P &lt; .001). However, there was no difference between the ruptured and stable groups according to the results of time-averaged WSS (P = .8) for ruptured- and stable-IAs. According to flow visualization, though the mean average inflow speed of ruptured-IAs was 2 times higher than that of the stable-IAs, the flow inside ruptured-IAs appeared to undergo longer resident tracks, with stronger impact on the aneurysm wall. On the contrary, the flow inside stable-IAs passed smoothly through the aneurysms. CONCLUSIONS: These preliminary results indicated that EL may be a useful parameter for the quantitative estimation of the risks of rupture for IAs. ARaspect ratioIAintracranial aneurysmCFDcomputational fluid dynamicsCTACT angiographyELenergy lossELvenergy loss per unit volumeFSIfluid-structure interactionICAinternal carotid arteryMCAmiddle cerebral arteryPcomAposterior communicating arterySTLstereolithography file formatWSSwall shear stress