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优化下腔静脉滤器设计:一项关于支柱构型以增强血流动力学性能和减少血栓形成的计算流体动力学研究。

Optimizing inferior vena cava filter design: A computational fluid dynamics study on strut configuration for enhanced hemodynamic performance and thrombosis reduction.

作者信息

Kim Byeong-Jun, Lee Chiseung

机构信息

Department of Biomedical Engineering, Graduate School, Pusan National University, Busan 49241, Republic of Korea.

Department of Biomedical Engineering, School of Medicine, Pusan National University, Busan 49241, Republic of Korea.

出版信息

Heliyon. 2024 Jun 7;10(11):e32667. doi: 10.1016/j.heliyon.2024.e32667. eCollection 2024 Jun 15.

DOI:10.1016/j.heliyon.2024.e32667
PMID:38912484
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11193039/
Abstract

BACKGROUND AND OBJECTIVE

Inferior vena cava filters have been shown to be effective in preventing deep vein thrombosis and its secondary complication, pulmonary embolism, thereby reducing the high mortality rate. Although inferior vena cava filters have evolved, specific complications like inferior vena cava thrombosis-induced deep vein thrombosis worsening and recurrent pulmonary embolism continue to pose challenges. This study analyzes the effects of geometric parameter variations of inferior vena cava filters, which have a significant impact on the thrombus formation inside the filter, the capture, dissolution, and hemodynamic flow of thrombus, as well as the shear stress on the filter and vascular wall.

METHODS

This study used computational fluid dynamic simulations with the carreau model to investigate the impact of varying inferior vena cava filter design parameters (number of struts, strut arm length, and tilt angle) on hemodynamics.

RESULTS

Recirculation and stagnation areas due to flow velocity and pressure, along with wall shear stress values, were identified as key factors. It is important to find a balance between wall shear stress high enough to aid thrombolysis and low enough to prevent platelet activation. The results of this paper show that the risk of platelet activation and thrombus filtration may be lowest when the wall shear stress of the filter ranges from 0 to 4 [Pa], minimizing stress concentration within the filter.

CONCLUSION

16 arm struts with a length of 20 mm and a tilt angle of 0° provide the best balance between thrombus capture and minimization of hemodynamic disturbance. This configuration minimizes the size of the stagnation and recirculation zones while maintaining sufficient wall shear stress for thrombus dissolution.

摘要

背景与目的

下腔静脉滤器已被证明在预防深静脉血栓形成及其继发并发症肺栓塞方面有效,从而降低了高死亡率。尽管下腔静脉滤器不断发展,但诸如下腔静脉血栓形成导致深静脉血栓恶化和复发性肺栓塞等特定并发症仍然构成挑战。本研究分析了下腔静脉滤器几何参数变化的影响,这些参数对滤器内血栓形成、血栓的捕获、溶解和血流动力学以及滤器和血管壁上的剪切应力有重大影响。

方法

本研究使用计算流体动力学模拟和卡雷奥模型来研究不同的下腔静脉滤器设计参数(支柱数量、支柱臂长度和倾斜角度)对血流动力学的影响。

结果

由于流速和压力产生的再循环和停滞区域以及壁面剪切应力值被确定为关键因素。在足以辅助溶栓的高壁面剪切应力和足以防止血小板激活的低壁面剪切应力之间找到平衡很重要。本文结果表明,当滤器的壁面剪切应力在0至4[帕斯卡]范围内时,血小板激活和血栓过滤的风险可能最低,可将滤器内的应力集中降至最低。

结论

16个臂的支柱,长度为20毫米,倾斜角度为0°,在血栓捕获和血流动力学干扰最小化之间提供了最佳平衡。这种配置可将停滞和再循环区域的大小降至最低,同时保持足够的壁面剪切应力以促进血栓溶解。

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4
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