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Unexpected abrupt increase in left ventricular assist device thrombosis.左心室辅助装置血栓形成的意外急剧增加。
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J Heart Lung Transplant. 2013 Feb;32(2):141-56. doi: 10.1016/j.healun.2012.12.004.
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Heart disease and stroke statistics--2013 update: a report from the American Heart Association.《2013年心脏病和中风统计数据更新:美国心脏协会报告》
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脉动血流条件下CF-VADs中的血流特征和装置引起的血液损伤:一项CFD对比研究。

Flow features and device-induced blood trauma in CF-VADs under a pulsatile blood flow condition: A CFD comparative study.

作者信息

Chen Zengsheng, Jena Sofen K, Giridharan Guruprasad A, Koenig Steven C, Slaughter Mark S, Griffith Bartley P, Wu Zhongjun J

机构信息

Department of Surgery, University of Maryland School of Medicine, Baltimore, MD, 21201, USA.

Department of Cardiovascular and Thoracic Surgery, School of Medicine, University of Louisville, Louisville, KY, 40202, USA.

出版信息

Int J Numer Method Biomed Eng. 2018 Feb;34(2). doi: 10.1002/cnm.2924. Epub 2017 Oct 6.

DOI:10.1002/cnm.2924
PMID:28859253
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5803368/
Abstract

In this study, the flow features and device-associated blood trauma in 4 clinical ventricular assist devices (VADs; 2 implantable axial VADs, 1 implantable centrifugal VAD, and 1 extracorporeal VAD) were computationally analyzed under clinically relevant pulsatile flow conditions. The 4 VADs were operated at fixed pump speed at a mean rate of 4.5 L/min. Mean pressure difference, wall shear stress, volume distribution of scalar shear stress (SSS), and shear-induced hemolysis index (HI) were derived from the flow field of each VAD and were compared. The computationally predicted mean pressure difference across the 3 implantable VADs was ~70 mmHg, and the extracorporeal VAD was ~345 mmHg, which matched well with their reported pressure-flow curves. The axial VADs had higher mean wall shear stress and SSS compared with the centrifugal VADs. However, the residence time of the centrifugal VADs was much longer compared with the axial VADs because of the large volume of the centrifugal VADs. The highest SSS was observed in one axial VAD, and the longest exposure time was observed in 1 centrifugal VAD. These 2 VADs generated the highest HI. The shear-induced HI varied as a function of flow rate within each cardiac cycle. At fixed pump speed, the HI was greatest at low flow rate due to longer exposure time to shear stress compared with at high flow rate. Subsequently, we hypothesize that to reduce the risk of blood trauma during VAD support, shear stress magnitude and exposure time need to be minimized.

摘要

在本研究中,对4种临床心室辅助装置(VAD;2种植入式轴向VAD、1种植入式离心VAD和1种体外VAD)在临床相关的搏动血流条件下的血流特征和与装置相关的血液损伤进行了计算分析。这4种VAD以固定泵速运行,平均速率为4.5升/分钟。从每个VAD的流场中得出平均压差、壁面剪应力、标量剪应力(SSS)的体积分布以及剪应力诱导的溶血指数(HI),并进行比较。计算预测的3种植入式VAD的平均压差约为70 mmHg,体外VAD约为345 mmHg,这与它们报告的压力-流量曲线非常吻合。与离心式VAD相比,轴向VAD具有更高的平均壁面剪应力和SSS。然而,由于离心式VAD的体积较大,其停留时间与轴向VAD相比要长得多。在一个轴向VAD中观察到最高的SSS,在1个离心式VAD中观察到最长的暴露时间。这2种VAD产生了最高的HI。在每个心动周期内,剪应力诱导的HI随流速而变化。在固定泵速下,由于与高流速相比,低流速下暴露于剪应力的时间更长,所以HI在低流速时最大。随后,我们假设为了降低VAD支持期间血液损伤的风险,需要将剪应力大小和暴露时间降至最低。