2000 journal article
Hemodynamics analyses of arterial expansions with implications to thrombosis and restenosis
MEDICAL ENGINEERING & PHYSICS, 22(1), 13–27.
author keywords: computational hemodynamics simulations; transient particle-hemodynamics; sudden and smooth expansions; arterial disease indicators; thrombosis; restenosis
MeSH headings : Arteries / pathology; Arteries / physiopathology; Carotid Artery, Common / pathology; Carotid Artery, Common / physiopathology; Endarterectomy, Carotid / adverse effects; Hemodynamics; Humans; Models, Cardiovascular; Postoperative Complications / etiology; Postoperative Complications / pathology; Postoperative Complications / physiopathology; Stress, Mechanical; Thrombosis / etiology; Thrombosis / pathology; Thrombosis / physiopathology
TL;DR:
The regions near the expansion wall and the reattachment point are susceptible to both atherosclerotic lesion and thrombi formations as indicated by non-uniform hemodynamic indicators as well as blood particle accumulation and deposition.
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UN Sustainable Development Goal Categories
3. Good Health and Well-being
(Web of Science)
Source: Web Of Science
Added: August 6, 2018
It is assumed that critical hemodynamic factors play an important role in the onset, localization and degree of post-operative complications, for example, thrombosis and restenosis. Of special interest are sudden expansion flows, which may occur in straight artery segments such as the common carotid after endarterectomy or end-to-end anastomoses. Sudden expansion geometries are possible origins of early post-operative emboli and significant myointimal hyperplasia resulting in early or late complications. Transient laminar axisymmetric and fully three-dimensional blood flows were simulated employing a validated finite volume code in conjunction with a Runge–Kutta particle tracking technique. Disturbed flow indicators, which may predict the onset of thrombosis and/or restenosis, were identified and employed to evaluate 90°-step and smooth expansion geometries. Smooth expansion geometries have weaker disturbed flow features than step expansion geometries. Specifically, the regions near the expansion wall and the reattachment point are susceptible to both atherosclerotic lesion and thrombi formations as indicated by non-uniform hemodynamic indicators such as near-zero wall shear stress and elevated wall shear stress gradients as well as blood particle accumulation and deposition. A new parameter, the wall shear stress angle deviation (WSSAD) has been introduced, which indicates areas of abnormal endothelial cell morphology and particle wall deposition. In turn, regions of low wall shear stress and high wall shear stress gradients are recognized as susceptible sites for arterial diseases. Thus, it is interesting to note that high WSSAD surface areas cover low wall shear stress, high wall shear stress gradient locations as well as high wall particle deposition. A gradual change in step expansion geometry provides better results in terms of WSSAD values and hence potentially reducing atherosclerosis as well as thrombi formation.