Title :
Analysis on intra-aneurysmal flow influence by stenting
Author :
Wong, Kelvin K L ; Thavornpattanapong, Pongpat ; Tu, Jiyuan ; Chaichana, Thanapong ; Sun, Zhonghua
Abstract :
This Using numerical simulation, the evolution of vortices in an aneurysm can be tracked. We examined large-scale swirling of blood within a significantly dilated aneurysm and quantified the pressure gradient and shear strain rate. Based on these fluid mechanical parameters, we are able to identify the difference in flow effects between the untreated and stented aneurysmal arteries. This study demonstrates that the large-scale vortex, pressure gradient and blood shear strain rate within an aneurysm sac reduces after stenting.
Keywords :
blood flow measurement; blood pressure measurement; blood vessels; computational fluid dynamics; flow simulation; numerical analysis; shear flow; stents; vortices; blood shear strain rate; fluid mechanical parameters; intraaneurysmal flow influence; large-scale blood swirling; large-scale vortex; numerical simulation; pressure gradient; shear strain rate; stented aneurysmal arteries; stenting; Aneurysm; Arteries; Blood; Computational modeling; Mathematical model; Numerical models; Strain; Aneurysm; Computational fluid dynamics; Flow analysis; Shear strain ratecomponent; Vorticity;
Conference_Titel :
Biomedical Engineering and Informatics (BMEI), 2010 3rd International Conference on
Conference_Location :
Yantai
Print_ISBN :
978-1-4244-6495-1
DOI :
10.1109/BMEI.2010.5639477
