Optimization of flow rate and orientation of outflow graft at implantation for patients with left ventricular assist device.

Yongyi WANG; Li SHI; Shijun HU; Xiao TAN; Tianli ZHAO

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Optimization of flow rate and orientation of outflow graft at implantation for patients with left ventricular assist device.

Author: Yongyi WANG ^{1
,

2} ; Li SHI ³ ; Shijun HU ¹ ; Xiao TAN ³ ; Tianli ZHAO ^{1
,

4}
Author Information

1. Department of Cardiovascular Surgery, Second Xiangya Hospital, Central South University; Hunan Engineering Research Center for Digital Heart, Changsha
2. 238212293@csu.edu.cn.
3. School of Mechanical Engineering and Mechanics, Xiangtan University, Xiangtan 411105, China.
4. zhaotianli@csu.edu.cn.
Publication Type:Journal Article
Keywords: fluid-particle interactions; heart failure; hemodynamics; left ventricular assist device; patient-specific model
MeSH: Heart-Assist Devices/adverse effects*; Humans; Heart Failure/physiopathology*; Blood Flow Velocity; Thromboembolism/prevention & control*; Models, Cardiovascular; Heart Ventricles/physiopathology*; Imaging, Three-Dimensional
From: Journal of Central South University(Medical Sciences) 2025;50(3):457-468
CountryChina
Language:English
Abstract: OBJECTIVES:A ventricular assist device (VAD) is an electromechanical device used to assist cardiac blood circulation, which can be employed for the treatment of end-stage heart failure and is most commonly placed in the left ventricle. Despite enhancing perfusion performance, the implantation of left ventricular assist device (LVAD) transforms the local intraventricular flow and thus may increase the risk of thrombogenesis. This study aims to investigate fluid-particle interactions and thromboembolic risk under different LVAD configurations using three-dimensional (3D) reconstruction models, focusing on the effects of outflow tract orientation and blood flow rates.
METHODS:A patient-specific end-diastolic 3D reconstruction model was initially constructed in stereo lithography (STL) format using Mimics software based on CT images. Transient numerical simulations were performed to analyze fluid-particle interactions and thromboembolic risks for LVAD with varying outflow tract orientations under 2 flow rates (4 L/min and 5 L/min), using particles of uniform size (2 mm), and a blood flow rate optimization protocol was implemented for this patient.
RESULTS:When the LVAD flow rate was 5 L/min, helicity and flow stagnation of the blood flow increased the particle residence time (RT) and the risk of thrombogenesis of the aortic root. The percentage of particles traveling toward the brachiocephalic trunk was up to 20.33%. When the LVAD flow rate was 4 L/min, blood turbulence in the aorta was reduced, the RT of blood particles was shortened, and then the percentage of particles traveling toward the brachiocephalic trunk decreased to 10.54%. When the LVAD blood flow rate was 5 L/min and the direction of the outflow pipe was optimal, the RT of blood particles was shortened, and then the percentage of particles traveling toward the brachiocephalic trunk decreased to 11.22%. A 18-month follow-up observation of the patient revealed that the LVAD was in good working order and the patient had no complications related to the implantation of LVAD.
CONCLUSIONS:Implantation of LVAD results in a higher risk of cerebral infarction; When implanting LVAD with the same outflow tract direction, optimizing flow velocity and outflow tract can reduce the risk of cerebral infarction occurrence.