Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.

Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.

Approximately one-quarter of ischemic strokes involve the vertebrobasilar arterial system that includes the upstream flow confluence and downstream flow divergence. A patient-specific hemodynamic analysis is needed to understand the posterior circulation. The objective of this study is to determine...

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Main Authors: Xiaoping Yin, Xu Huang, Yundi Feng, Wenchang Tan, Huaijun Liu, Yunlong Huo
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2016-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC4965217?pdf=render
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spelling doaj-370c2a08d6494f6ebd69c5df9206c07f2020-11-25T00:07:16ZengPublic Library of Science (PLoS)PLoS ONE1932-62032016-01-01117e015983610.1371/journal.pone.0159836Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.Xiaoping YinXu HuangYundi FengWenchang TanHuaijun LiuYunlong HuoApproximately one-quarter of ischemic strokes involve the vertebrobasilar arterial system that includes the upstream flow confluence and downstream flow divergence. A patient-specific hemodynamic analysis is needed to understand the posterior circulation. The objective of this study is to determine the distribution of hemodynamic parameters in the vertebrobasilar system, based on computer tomography angiography images. Here, the interplay of upstream flow confluence and downstream flow divergence was hypothesized to be a determinant factor for the hemodynamic distribution in the vertebrobasilar system. A computational fluid dynamics model was used to compute the flow fields in patient-specific vertebrobasilar models (n = 6). The inlet and outlet boundary conditions were the aortic pressure waveform and flow resistances, respectively. A 50% reduction of total outlet area was found to induce a ten-fold increase in surface area ratio of low time-averaged wall shear stress (i.e., TAWSS ≤ 4 dynes/cm2). This study enhances our understanding of the posterior circulation associated with the incidence of atherosclerotic plaques.http://europepmc.org/articles/PMC4965217?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Xiaoping Yin
Xu Huang
Yundi Feng
Wenchang Tan
Huaijun Liu
Yunlong Huo
spellingShingle Xiaoping Yin
Xu Huang
Yundi Feng
Wenchang Tan
Huaijun Liu
Yunlong Huo
Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.
PLoS ONE
author_facet Xiaoping Yin
Xu Huang
Yundi Feng
Wenchang Tan
Huaijun Liu
Yunlong Huo
author_sort Xiaoping Yin
title Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.
title_short Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.
title_full Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.
title_fullStr Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.
title_full_unstemmed Interplay of Proximal Flow Confluence and Distal Flow Divergence in Patient-Specific Vertebrobasilar System.
title_sort interplay of proximal flow confluence and distal flow divergence in patient-specific vertebrobasilar system.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2016-01-01
description Approximately one-quarter of ischemic strokes involve the vertebrobasilar arterial system that includes the upstream flow confluence and downstream flow divergence. A patient-specific hemodynamic analysis is needed to understand the posterior circulation. The objective of this study is to determine the distribution of hemodynamic parameters in the vertebrobasilar system, based on computer tomography angiography images. Here, the interplay of upstream flow confluence and downstream flow divergence was hypothesized to be a determinant factor for the hemodynamic distribution in the vertebrobasilar system. A computational fluid dynamics model was used to compute the flow fields in patient-specific vertebrobasilar models (n = 6). The inlet and outlet boundary conditions were the aortic pressure waveform and flow resistances, respectively. A 50% reduction of total outlet area was found to induce a ten-fold increase in surface area ratio of low time-averaged wall shear stress (i.e., TAWSS ≤ 4 dynes/cm2). This study enhances our understanding of the posterior circulation associated with the incidence of atherosclerotic plaques.
url http://europepmc.org/articles/PMC4965217?pdf=render
work_keys_str_mv AT xiaopingyin interplayofproximalflowconfluenceanddistalflowdivergenceinpatientspecificvertebrobasilarsystem
AT xuhuang interplayofproximalflowconfluenceanddistalflowdivergenceinpatientspecificvertebrobasilarsystem
AT yundifeng interplayofproximalflowconfluenceanddistalflowdivergenceinpatientspecificvertebrobasilarsystem
AT wenchangtan interplayofproximalflowconfluenceanddistalflowdivergenceinpatientspecificvertebrobasilarsystem
AT huaijunliu interplayofproximalflowconfluenceanddistalflowdivergenceinpatientspecificvertebrobasilarsystem
AT yunlonghuo interplayofproximalflowconfluenceanddistalflowdivergenceinpatientspecificvertebrobasilarsystem
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