Abstract
Cerebral aneurysms should be treated on the basis of accurate rupture risk prediction. Nowadays, the rupture risk in aneurysms has been estimated using hemodynamic parameters. In this paper, we suggest a new way to predict the rupture risks in cerebral aneurysms by using fluid–structure interaction (FSI) analysis for better decision-making regarding treatment. A patient-specific model was constructed using digital subtraction angiography of 51 cerebral aneurysms. For each model, a thin-walled area (TWA) was first predicted using computational fluid dynamics (CFD), and then the highest equivalent strain in the TWA was calculated with FSI by varying wall thicknesses and mechanical properties. A critical curve was made from 16 FSI results for each patient-specific model to estimate the rupture risk. On average, the equivalent strains of the ruptured aneurysms were higher than those of the unruptured aneurysms. Furthermore, the patterns of critical curves between unruptured and ruptured aneurysms were clearly distinguishable. From the rupture risk evaluation based on the cut-off value, 24 of the 27 unruptured aneurysms and 15 of the 24 ruptured aneurysms were matched with actual-clinical setting cases. The critical curve proposed in the present study could be an effective tool for the prediction of the rupture risk of aneurysm.
Highlights
Cerebral aneurysms should be treated on the basis of accurate rupture risk prediction
Because the rupture of aneurysm is significantly influenced by the wall thickness and mechanical property of a neurysms[11,12], the accurate prediction of rupture risk could not be obtained through only computational fluid dynamics (CFD) analysis
The significance of the critical curve proposed in this study is that it could distinguish between unruptured and ruptured aneurysms, which is usually not feasible with factors currently used in the clinical setting for the prediction of their ruptures
Summary
Cerebral aneurysms should be treated on the basis of accurate rupture risk prediction. A critical curve was made from 16 FSI results for each patient-specific model to estimate the rupture risk. The critical curve proposed in the present study could be an effective tool for the prediction of the rupture risk of aneurysm. Computational fluid dynamics (CFD) has been performed to investigate the effects of HPs and geometrical features of aneurysms on the rupture risks of aneurysms[5,6,7,8,9]. Because the rupture of aneurysm is significantly influenced by the wall thickness and mechanical property of a neurysms[11,12], the accurate prediction of rupture risk could not be obtained through only CFD analysis. College of Medicine, Yonsei University, Gangnam Severance Hospital, 211 Eonju‐ro, Gangnam‐gu, Seoul 06273, Korea. 5These authors contributed : Kwang-Chun Cho and Hyeondong Yang *email: jehoon@
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