Center for Medical Physics and Biomedical Engineering, Medical University of Vienna, Vienna, Austria.
Ludwig Boltzmann Institute for Cardiovascular Research, Vienna, Austria.
Artif Organs. 2020 Sep;44(9):939-946. doi: 10.1111/aor.13705. Epub 2020 May 6.
The use of left ventricular assist devices (LVADs) as a treatment method for heart failure patients has been steadily increasing; however, pathological studies showed presence of thrombi around the HeartWare ventricular assist device inflow cannula (IC) in more than 95% of patients after device explantation. Flow fields around the IC might trigger thrombus formation and require further investigation. In this study flow dynamics parameters were evaluated for different patient geometries using computational fluid dynamics (CFD) simulations. Left ventricular (LV) models of two LVAD patients were obtained from CT scans. The LV volumes of Patient 1 (P1) and Patient 2 (P2) were 264 and 114 cm with an IC angle of 20° and 9° from the mitral-IC tip axis at the coronal plane. The IC insertion site at the apex was central for P1, whereas it was lateral for P2. Transient CFD simulations were performed over 9 cardiac cycles. The wedge area was defined from the cannula tip to the wall of the LV apex. Mean velocity magnitude and blood stagnation region (volume with mean velocity <5 mm/s) as well as the wall shear stress (WSS) at the IC surface were calculated. Cardiac support resulted in a flow mainly crossing the ventricle from the mitral valve to the LVAD cannula for P2, while the main inflow jet deviated toward the septal wall in P1. Lower WSS at the IC surface and consequently larger stagnation volumes were observed for P2 (P1: 0.17, P2: 0.77 cm ). Flow fields around an LVAD cannula can be influenced by many parameters such as LV size, IC angle, and implantation site. Careful consideration of influencing parameters is essential to get reliable evaluations of the apical flow field and its connection to apical thrombus formation. Higher blood washout and lower stagnation were observed for a central implantation of the IC at the apex.
左心室辅助装置(LVAD)作为心力衰竭患者的治疗方法的使用一直在稳步增加;然而,病理学研究表明,在装置取出后,超过 95%的患者的心包辅助装置流入管(IC)周围存在血栓。IC 周围的流场可能会引发血栓形成,需要进一步研究。在这项研究中,使用计算流体动力学(CFD)模拟评估了不同患者几何形状的流场动力学参数。从 CT 扫描中获得了两名 LVAD 患者的左心室(LV)模型。患者 1(P1)和患者 2(P2)的 LV 体积分别为 264cm 和 114cm,IC 角度在冠状面从二尖瓣-IC 尖端轴为 20°和 9°。P1 的 IC 插入点在顶点是中心的,而 P2 的则是侧面的。对 9 个心动周期进行了瞬态 CFD 模拟。楔形区域是从导管尖端到 LV 顶点壁定义的。计算了平均速度大小和血液停滞区域(平均速度<5mm/s 的体积)以及 IC 表面的壁面切应力(WSS)。心脏支持导致 P2 的血流主要从二尖瓣穿过心室流向 LVAD 导管,而 P1 的主要流入射流则偏向间隔壁。P2 的 IC 表面的 WSS 较低,因此停滞体积较大(P1:0.17,P2:0.77cm)。LVAD 导管周围的流场会受到许多参数的影响,如 LV 大小、IC 角度和植入部位。仔细考虑影响参数对于获得可靠的顶点流场及其与顶点血栓形成的连接评估至关重要。IC 在顶点的中心植入时,观察到更高的血液冲洗和更低的停滞。
