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Reverse cannulation method as a strategy for aortic aneurysm surgery: A computational fluid dynamics study on

Yuki Imamura1, Yoshishige Takayama2, Ryosuke Kowatari1

  • 1Department of Thoracic and Cardiovascular Surgery, Hirosaki University School of Medicine, Hirosaki, Japan.

The Journal of Thoracic and Cardiovascular Surgery
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Summary

Directing the cannula tip toward the aortic root during aortic arch surgery in "shaggy" aorta cases prevents accelerated blood flow, optimizing cerebral branch flow stability.

Keywords:
atherosclerosiscannulation methodcomputational fluid dynamicstotal arch replacement

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Area of Science:

  • Cardiovascular Surgery
  • Biomedical Engineering
  • Medical Imaging

Background:

  • Aortic arch aneurysms present surgical challenges, particularly with "shaggy" aorta.
  • Maintaining stable cerebral blood flow during total arch replacement is critical.

Purpose of the Study:

  • To evaluate blood flow dynamics and wall shear stress in total aortic arch replacement using computational fluid dynamics.
  • To determine the optimal cannulation strategy for "shaggy" aortas.

Main Methods:

  • Patient-specific aortic arch models were created from CT scans.
  • Three cannula types were simulated with varying tip orientations (standard vs. reversed).
  • Computational fluid dynamics analyzed blood flow velocity, streamlines, wall shear stress, and flow distribution.

Main Results:

  • Standard cannula direction led to unstable cerebral branch flow due to variable accelerated flow and wall shear stress.
  • Reversed cannula direction (toward aortic root) prevented accelerated flow at critical areas, ensuring stable cerebral branch flow.
  • Flow distribution showed minimal variation across cannula types and angles in the reversed direction.

Conclusions:

  • Cannula tip orientation toward the aortic root is a potentially optimal approach for aortic arch surgery in "shaggy" aorta.
  • This reversed direction strategy ensures stable cerebral branch flow irrespective of cannula type or orientation.
  • Simulations highlight the importance of cannulation strategy in mitigating hemodynamic risks.