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Effects of size and location of distal tear on hemodynamics and wave propagation in type B aortic dissection

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摘要 The type B aortic dissection(TBAD)is a perilous disease with high morbidity and mortality rates.The hemodynamics of TBAD in different scenarios has been widely studied by computational fluid dynamics(CFD)research.However,the flow pattern and wave propagation characteristics in the cardiovascular system with TBAD are not yet clear,and the effect of the distal tear is still unknown.In this work,a onedimensional(1D)cardiovascular system model coupling with a zero-dimensional(0D)lumped-parameter model is introduced to study the hemodynamics and wave propagation in the cardiovascular system.The results show that the proposed 0D-1D method well captures the oscillation and retrograde characteristics for the flow in the false lumen(FL),and the smaller distal tear damps the retrograde flow.Besides,the distal tear should also be paid attention to,and the wave intensity(WI)can be used as an access mark of the degree of the aortic dissection(AD).
作者 Huimin CHEN Qingzhuo CHI Ying HE Lizhong MU Yong LUAN
机构地区 Key Laboratory of Ocean Energy Utilization and Energy Conservation of Ministry of Education Department of Anesthesiology
出处 《Applied Mathematics and Mechanics(English Edition)》 SCIE EI CSCD 2022年第9期1449-1468,共20页 应用数学和力学(英文版)
基金 supported by the National Natural Science Foundation of China(No.51976026) the Fundamental Research Funds of Central Universities of China(Nos.DUT22YG206 and DUT21JC25)。
关键词 type B aorta dissection(TBAD) zero-dimensional(0D)-one-dimensional(1D)coupling model distal tear flow pattern wave intensity analysis(WIA)
分类号 O357 [理学—流体力学]
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Applied Mathematics and Mechanics(English Edition)
2022年 第9期

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