Brain Sciences (Sep 2024)

Fluid–Structure Interaction Simulations of the Initiation Process of Cerebral Aneurysms

  • Jozsef Nagy,
  • Wolfgang Fenz,
  • Veronika M. Miron,
  • Stefan Thumfart,
  • Julia Maier,
  • Zoltan Major,
  • Harald Stefanits,
  • Johannes Oberndorfer,
  • Nico Stroh,
  • Vanessa Mazanec,
  • Philip-Rudolf Rauch,
  • Andreas Gruber,
  • Matthias Gmeiner

DOI
https://doi.org/10.3390/brainsci14100977
Journal volume & issue
Vol. 14, no. 10
p. 977

Abstract

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Background: Hemodynamics during the growth process of cerebral aneurysms are incompletely understood. We developed a novel fluid–structure interaction analysis method for the identification of relevant scenarios of aneurysm onset. Method: This method integrates both fluid dynamics and structural mechanics, as well as their mutual interaction, for a comprehensive analysis. Patients with a single unruptured cerebral aneurysm were included. Results: Overall, three scenarios were identified. In scenario A, wall shear stress (WSS) was low, and the oscillatory shear index (OSI) was high in large areas within the region of aneurysm onset (RAO). In scenario B, the quantities indicated a reversed behavior, where WSS was high and OSI was low. In the last scenario C, a behavior in-between was found, with scenarios A and B coexisting simultaneously in the RAO. Structural mechanics demonstrated a similar but independent trend. Further, we analyzed the change in hemodynamics between the onset and a fully developed aneurysm. While scenarios A and C remained unchanged during aneurysm growth, 47% of aneurysms in scenario B changed into scenario A and 20% into scenario C. Conclusions: In conclusion, these findings suggest that WSS and the OSI are reciprocally regulated, and both low and high WSS/OSI conditions can lead to aneurysm onset.

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