A longitudinal study of remodeling in a revised peripheral artery bypass graft using 3D ultrasound imaging and computational hemodynamics

A longitudinal study of remodeling in a revised peripheral artery bypass graft using 3D ultrasound imaging and computational hemodynamics

We report a study of the role of hemodynamic shear stress in the remodeling and failure of a peripheral artery bypass graft. Three separate scans of a femoral to popliteal above-knee bypass graft were taken over the course of a 16 month period following a revision of the graft. The morphology of the...

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Bibliographic Details
Published in:Journal of biomechanical engineering Vol. 133; no. 4; p. 041008
Main Authors: McGah, Patrick M, Leotta, Daniel F, Beach, Kirk W, Riley, James J, Aliseda, Alberto
Format: Journal Article
Language:English
Published: United States 01-04-2011
Subjects:
Computer Simulation
Constriction, Pathologic - diagnostic imaging
Constriction, Pathologic - physiopathology
Femoral Artery - diagnostic imaging
Femoral Artery - physiopathology
Femoral Artery - surgery
Hemodynamics
Humans
Imaging, Three-Dimensional
Longitudinal Studies
Popliteal Artery - diagnostic imaging
Popliteal Artery - physiopathology
Popliteal Artery - surgery
Prosthesis Failure
Retrospective Studies
Stress, Mechanical
Ultrasonography
Vascular Grafting - methods
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Summary:We report a study of the role of hemodynamic shear stress in the remodeling and failure of a peripheral artery bypass graft. Three separate scans of a femoral to popliteal above-knee bypass graft were taken over the course of a 16 month period following a revision of the graft. The morphology of the lumen is reconstructed from data obtained by a custom 3D ultrasound system. Numerical simulations are performed with the patient-specific geometries and physiologically realistic flow rates. The ultrasound reconstructions reveal two significant areas of remodeling: a stenosis with over 85% reduction in area, which ultimately caused graft failure, and a poststenotic dilatation or widening of the lumen. Likewise, the simulations reveal a complicated hemodynamic environment within the graft. Preliminary comparisons with in vivo velocimetry also showed qualitative agreement with the flow dynamics observed in the simulations. Two distinct flow features are discerned and are hypothesized to directly initiate the observed in vivo remodeling. First, a flow separation occurs at the stenosis. A low shear recirculation region subsequently develops distal to the stenosis. The low shear region is thought to be conducive to smooth muscle cell proliferation and intimal growth. A poststenotic jet issues from the stenosis and subsequently impinges onto the lumen wall. The lumen dilation is thought to be a direct result of the high shear stress and high frequency pressure fluctuations associated with the jet impingement.
ISSN:1528-8951
DOI:10.1115/1.4003622