Restle David J, Zhang David M, Hung George, Howard Jessica L, Kallel Faouzi, Acker Michael A, Atluri Pavan, Bartoli Carlo R
Division of Cardiovascular Surgery, Hospital of the University of Pennsylvania, Philadelphia, PA, USA.
Thoratec Corporation, Pleasanton, CA, USA.
Artif Organs. 2015 Jul;39(7):569-75. doi: 10.1111/aor.12428. Epub 2015 Mar 21.
Evidence suggests a major role for von Willebrand factor (vWF) in left ventricular assist device (LVAD)-associated bleeding. However, the mechanisms of vWF degradation during LVAD support are not well understood. We developed: (i) a simple and inexpensive vortexer model; and (ii) a translational LVAD mock circulatory loop to perform preclinical investigations of LVAD-associated vWF degradation. Whole blood was obtained from LVAD patients (n = 8) and normal humans (n = 15). Experimental groups included: (i) blood from continuous-flow LVAD patients (baseline vs. post-LVAD, n = 8); (ii) blood from normal humans (baseline vs. 4 h in vitro laboratory vortexer, ∼ 2400 rpm, shear stress ∼175 dyne/cm(2) , n = 8); and (iii) blood from normal humans (baseline vs. 12 h HeartMate II mock circulatory loop, 10 000 rpm, n = 7). vWF multimers and degradation fragments were characterized with electrophoresis and immunoblotting. Blood from LVAD patients, blood exposed to in vitro supraphysiologic shear stress, and blood circulated through an LVAD mock circulatory loop demonstrated a similar profile of decreased large vWF multimers and increased vWF degradation fragments. A laboratory vortexer and an LVAD mock circulatory loop reproduced the pathologic degradation of vWF that occurs during LVAD support. Both models are appropriate for preclinical studies of LVAD-associated vWF degradation.
有证据表明,血管性血友病因子(vWF)在左心室辅助装置(LVAD)相关出血中起主要作用。然而,LVAD支持期间vWF降解的机制尚不清楚。我们开发了:(i)一种简单且廉价的涡旋仪模型;以及(ii)一种转化型LVAD模拟循环回路,以进行LVAD相关vWF降解的临床前研究。从LVAD患者(n = 8)和正常人(n = 15)获取全血。实验组包括:(i)连续流LVAD患者的血液(基线与LVAD后,n = 8);(ii)正常人的血液(基线与体外实验室涡旋仪处理4小时,约2400转/分钟,剪切应力约175达因/平方厘米,n = 8);以及(iii)正常人的血液(基线与HeartMate II模拟循环回路处理12小时,10000转/分钟,n = 7)。通过电泳和免疫印迹对vWF多聚体和降解片段进行表征。来自LVAD患者的血液、暴露于体外超生理剪切应力的血液以及通过LVAD模拟循环回路循环的血液,均显示出大vWF多聚体减少和vWF降解片段增加的相似特征。实验室涡旋仪和LVAD模拟循环回路再现了LVAD支持期间发生的vWF病理性降解。这两种模型均适用于LVAD相关vWF降解的临床前研究。
