Numerical investigation and identification of susceptible sites of atherosclerotic lesion formation in a complete coronary artery bypass model

As hemodynamics is widely believed to correlate with anastomotic stenosis in coronary bypass surgery, this paper investigates the flow characteristics and distributions of the hemodynamic parameters (HPs) in a coronary bypass model (which includes both proximal and distal anastomoses), under physiological flow conditions. Disturbed flows (flow separation/reattachment, vortical and secondary flows) as well as regions of high oscillatory shear index (OSI) with low wall shear stress (WSS), i.e., high-OSI-and-low-WSS and low-OSI-and-high-WSS were found in the proximal and distal anastomoses, especially at the toe and heel regions of distal anastomosis, which indicate highly suspected sites for the onset of the atherosclerotic lesions. The flow patterns found in the graft and distal anastomoses of our model at deceleration phases are different from those of the isolated distal anastomosis model. In addition, a huge significant difference in segmental averages of HPs was found between the distal and proximal anastomoses. These findings further suggest that intimal hyperplasia would be more prone to form in the distal anastomosis than in the proximal anastomosis, particularly along the suture line at the toe and heel of distal anastomosis.

[1]  William Francis Ganong,et al.  Review of Medical Physiology , 1969 .

[2]  D. Ku,et al.  Steady flow and wall compression in stenotic arteries: a three-dimensional thick-wall model with fluid-wall interactions. , 2001, Journal of biomechanical engineering.

[3]  C Kleinstreuer,et al.  Hemodynamics simulation and identification of susceptible sites of atherosclerotic lesion formation in a model abdominal aorta. , 2003, Journal of biomechanics.

[4]  F. Kajiya,et al.  Analysis of flow characteristics in poststenotic regions of the human coronary artery during bypass graft surgery. , 1987, Circulation.

[5]  A. Leuprecht,et al.  Numerical study of hemodynamics and wall mechanics in distal end-to-side anastomoses of bypass grafts. , 2002, Journal of biomechanics.

[6]  N. Haites,et al.  Aortic blood velocity measurement in healthy adults using a simple ultrasound technique. , 1983, Cardiovascular research.

[7]  C. Visser,et al.  Value of magnetic resonance imaging in assessing patency and function of coronary artery bypass grafts. An angiographically controlled study. , 1996, Circulation.

[8]  J. Raman,et al.  Factors affecting saphenous vein graft patency: clinical and angiographic study in 1402 symptomatic patients operated on between 1977 and 1999. , 2003, The Journal of thoracic and cardiovascular surgery.

[9]  C. Zarins,et al.  Relative contribution of wall shear stress and injury in experimental intimal thickening at PTFE end-to-side arterial anastomoses. , 2002, Journal of biomechanical engineering.

[10]  L. Chua,et al.  Computational model of blood flow in the aorto-coronary bypass graft , 2005, Biomedical engineering online.

[11]  C. R. Ethier,et al.  A numerical study of blood flow patterns in anatomically realistic and simplified end-to-side anastomoses. , 1999, Journal of biomechanical engineering.

[12]  V. Sottiurai,et al.  Distal anastomotic intimal hyperplasia: histopathologic character and biogenesis. , 1989, Annals of vascular surgery.

[13]  J. Watterson,et al.  Numerical investigation of the haemodynamics at a patched arterial bypass anastomosis. , 2002, Medical engineering & physics.

[14]  Tongming Zhou,et al.  Numerical study of a complete anastomosis model for the coronary artery bypass , 2005 .

[15]  P. Roache Verification of Codes and Calculations , 1998 .

[16]  L. Chua,et al.  Numerical Study on the Pulsatile Flow Characteristics of Proximal Anastomotic Models , 2005, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[17]  H. Schima,et al.  Numerical study of wall mechanics and fluid dynamics in end-to-side anastomoses and correlation to intimal hyperplasia. , 1996, Journal of biomechanics.

[18]  Clement Kleinstreuer,et al.  Numerical simulation of wall shear stress conditions and platelet localization in realistic end-to-side arterial anastomoses. , 2003, Journal of biomechanical engineering.

[19]  M. Budoff,et al.  Evaluation of Coronary Artery Bypass Graft Patency Using Three-Dimensional Reconstruction and Flow Study on Electron Beam Tomography , 2000, Chinese medical journal.

[20]  C Kleinstreuer,et al.  Relation between non-uniform hemodynamics and sites of altered permeability and lesion growth at the rabbit aorto-celiac junction. , 1999, Atherosclerosis.

[21]  S Glagov,et al.  Anastomotic intimal hyperplasia: mechanical injury or flow induced. , 1992, Journal of vascular surgery.

[22]  J. Womersley Method for the calculation of velocity, rate of flow and viscous drag in arteries when the pressure gradient is known , 1955, The Journal of physiology.

[23]  T. Carrel,et al.  The St Jude Medical symmetry aortic connector system for proximal vein graft anastomoses in coronary artery bypass grafting. , 2002, The Journal of thoracic and cardiovascular surgery.

[24]  Robert J. Lutz,et al.  The onset of turbulence in physiological pulsatile flow in a straight tube , 1998 .

[25]  G. Truskey,et al.  Hemodynamic parameters and early intimal thickening in branching blood vessels. , 2001, Critical reviews in biomedical engineering.

[26]  H. Y. Liang,et al.  A numerical simulation of steady flow fields in a bypass tube. , 2001, Journal of biomechanics.

[27]  朝倉 利久,et al.  Flow patterns and spatial distribution of atherosclerotic lesions in human coronary arteries , 1989 .

[28]  Antonino Filippone Advanced Topics in Aerodynamics , 1999 .

[29]  G. Kassab,et al.  Biomechanical considerations in the design of graft: the homeostasis hypothesis. , 2006, Annual review of biomedical engineering.