Patient-Specific Simulation of Carotid Artery Stenting Using Computational Fluid Dynamics (original) (raw)

References

1. ConnorsIII, J.J.: The Nature of Cervical Carotid Stenosis. Techniques in Vascular and Interventional Radiology, 3(2) (2000) 62–64.
   Article Google Scholar
2. Vitek, J.J., Roubin, G.S., New, G., Al-Mubarek, N., Iyer, S.S.: Carotid Stenting. Techniques in Vascular and Interventional Radiology, 3(2) (2000) 75–85.
   Article Google Scholar
3. Meyers PM, Higashida RT, Phatouros C, Malek AM, Lempert TE, Dowd CF, Halbach VV: Cerebral Hyperperfusion Syndrome after Percutaneous transluminal Stenting of the Craniocervical Arteries. Neurosurgery, 47(2), (2000) 335–345.
   Article Google Scholar
4. Berger, S.A., Jou, L.D.: Flow in Stenotic Blood Vessels. Annual Review of Fluid Mechanics, 32 (2000) 347–82.
   Article MathSciNet Google Scholar
5. Jou, L.D., Saloner, D.: A Numerical Study of Magnetic Resonance Angiography Images for Pulsatile Flow in the Carotid Bifurcation. Medical Engineering and Physics, 20(9) (1998) 643–52.
   Article Google Scholar
6. Wentzel, J.J., Whelan, D.M., van Der Giessen, W.J., van Beusekom, H.M.M., Andhyiswara, I., Serruys, P.W., Slager, C.J., Kram, R.: Coronary Stent Implantation Changes 3D Vessel Geometry and 3D Shear Stress Distribution. J. Biomech., 33 (2000) 1287–1295.
   Article Google Scholar
7. Milner, J.S., Moore, J.A., Rutt, B.K., Steinman, D.A.: Hemodynamics of Human Artery Bifurcations: Computational Studies with Models Reconstructed from Magnetic Resonance Imaging of Normal Subjects. J. Vasc. Surg., 27 (1998) 143–156.
   Article Google Scholar
8. Moore, J.A., Steinman, D.A., Holdsworth, D.W.: Accuracy of Computational Hemodynamics in Complex Arterial Geometries Reconstructed from Magnetic Resonance Imaging. Ann. Biomed. Eng., 27 (1999) 32–41.
   Article Google Scholar
9. Cebral, J.R., Yim, P.J., Lohner, R., Soto, O., Marcos, H., Choyke, P.L.: New Methods for Computational Fluid Dynamics Modeling of Carotid Artery from Magnetic Resonance Angiography. Proc. SPIE Medical Imaging, 4321,paper No. 22 (2001).
   Google Scholar
10. Perktold, K., Hofer, M., Karner, G., Trubel, W., Schima, H.: Computer Simulation of Vascular Fluid Dynamics and Mass Transport: Optimal Design of Arterial Bypass Anastomoses. Proc. ECCOMAS 98, 2, John Wiley & Sons, (1998) 484–489.
    Google Scholar
11. Taylor, C.A., Draney, M.T., Ku, J.P., Parker, D., Steele, B.N., Wang, K., Zarins, C.K.: Predictive Medicine: Computational Techniques in Therapeutic Decision-Making. Computer Assisted Surgery 4 (1999) 231–247.
    Article Google Scholar
12. Yim, P.J., Cebral, J.R., Mullick, R., Choyke, P.L.: Vessel Surface Reconstruction with a Tubular Deformable Model. Submitted to IEEE Trans. Medical Imaging (2001).
    Google Scholar
13. Cebral, J.R., Löhner, R., Choyke, P.L., Yim, P.J.: Merging of Intersecting Triangulations for Finite Element Modeling. J. Biomech. (2001) in press.
    Google Scholar
14. Löhner, R.: Regridding Surface Triangulations. J. Comp. Phys., 126 (1996) 1–10.
    Article MATH Google Scholar
15. Löhner, R.: Automatic Unstructured Grid Generators. Finite Elements in Analysis and Design, 25 (1997) 111–134.
    Article MATH MathSciNet Google Scholar
16. Cebral, J.R., Löhner, R.: Flow Visualization On Unstructured Grids Using Geometrical Cuts, Vortex Detection and Shock Surfaces. AIAA-01-0915 (2001).
    Google Scholar
17. Cebral, J.R., Löhner, R.: Visualization of Blood Flow Computations in Realistic Anatomical Models Using Geometrical Surface Cuts. Submitted to IEEE Trans. Visualization and Computer Graphics (2001).
    Google Scholar
18. Taylor, C.A., Hughes, T.J.R., Zarins, C.K.: Finite Element Modeling of Blood Flow in Arteries. Comput. Methods Appl. Mech. Engrg. 158 (1998) 155–196.
    Article MATH MathSciNet Google Scholar
19. Zhao, S.Z., Xu, X.Y., Hughes, A.D., Thom, S.A., Stanton, A.V., Ariff, B., Long, Q.: Blood Flow and Vessel Mechanics in a Physiologically Realistic Model of a Human Carotid Arterial Bifurcation. J. Biomech. 33 (2000) 975–984.
    Article Google Scholar
20. Soto, O., Löhner, R., Cebral, J.R., Codina, R.: A Time-Accurate Implicit Monolithic Finite Element Scheme for Incompressible Flow Problems. Proc. ECCOMAS CFD, Swansea, UK (2001) to appear.
    Google Scholar
21. Womersley, J.R.: Method for the Calculation of Velocity, Rate of Flow and Viscous Drag in Arteries When the Pressure gradient is Known. J. Physiol. 127 (1955) 553–563.
    Google Scholar
22. Cebral, J.R., Lohner, R., Burgess, J.E.: Computer Simulation of Cerebral Artery Clipping: Relevance to Aneurysm Neuro-Surgery Planning. Proc. ECCOMAS, Barcelona-Spain (2000).
    Google Scholar

Download references