Therapeutic Effect of Targeted Deployment Filling Coils in the Treatment of Intracranial Aneurysms.

IF 2.2 4区医学 Q3 ENGINEERING, BIOMEDICAL International Journal for Numerical Methods in Biomedical Engineering Pub Date : 2024-11-06 DOI:10.1002/cnm.3880

Xiaoyu Ren, Bin Gao, Wangsheng Lu, Guangming Yang, Yunjie Wang, Yin Yin

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Abstract

Endovascular coil embolization is the primary therapeutic modality for intracranial aneurysms. Substantial reports have been found regarding the coil packing density and inflow jet. However, the hemodynamic effect of increasing the rate of tamponade in the inflow jet area within the aneurysm remains unclear. In this study, individualized geometries of six intracranial aneurysms were recruited: all six aneurysms were located in the internal carotid artery. Two groups were created by changing the position and orientation of the microcatheter for the release of the third segment of the filling coil. The finite element method was used to simulate coil deployment. Computational fluid dynamics was used to characterize hemodynamics in post-deployment aneurysms. The parameters evaluated included velocity reduction, wall shear stress (WSS), low WSS (LWSS), relative residence time (RRT), flow kinetic energy in the neck region of the aneurysms, and residual flow volume (RFV) in the aneurysms. At the peak time (t = 0.17 s), the targeted deployment group has similar proportion of LWSS area to conventional deployment groups: targeted 78.13% ± 34.59% versus normal 74.20% ± 36.94% (mean ± SD, p = 0.583). The targeted deployment group has a higher RRT area (targeted 16.84% ± 5.58% vs. normal 6.42% ± 5.67% [mean ± SD, p = 0.009]), smaller flow kinetic energy (targeted 9.43 ± 4.33 vs. normal 16.23 ± 5.92 [mean ± SD, p = 0.047]), and a larger RFV in the aneurysms (targeted 35.97 ± 24.35 mm³ vs. normal 25.80 ± 18.94 mm³ [mean ± SD, p = 0.44]). Inflow jets play an important role in the treatment of aneurysms, and deploying filling coils in accordance with inflow jets may result in a better hemodynamic environment.

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靶向部署填充线圈在治疗颅内动脉瘤中的疗效。

血管内线圈栓塞是治疗颅内动脉瘤的主要方法。有关线圈填塞密度和流入喷射的报道很多。然而，增加动脉瘤内流入射流区域的填塞率对血液动力学的影响仍不清楚。在这项研究中，研究人员采集了六个颅内动脉瘤的个性化几何形状：所有六个动脉瘤都位于颈内动脉。通过改变微导管的位置和方向来释放填充线圈的第三段，创建了两组。使用有限元法模拟线圈的展开。计算流体动力学用于描述部署后动脉瘤的血液动力学特征。评估的参数包括速度降低、壁切应力（WSS）、低WSS（LWSS）、相对停留时间（RRT）、动脉瘤颈部的流动动能以及动脉瘤内的残余血流量（RFV）。在峰值时间（t = 0.17 秒），靶向部署组的 LWSS 面积比例与常规部署组相似：靶向 78.13% ± 34.59% 对常规 74.20% ± 36.94%（平均值 ± SD，P = 0.583）。靶向部署组的 RRT 面积更大（靶向 16.84% ± 5.58% vs. 正常 6.42% ± 5.67% [平均值 ± 标准差，p = 0.009]），流动动能更小（靶向 9.43 ± 4.33 vs. 正常值 16.23 ± 5.92 [平均值±标准差，p = 0.047]），动脉瘤中的 RFV 较大（目标值 35.97 ± 24.35 mm3 vs. 正常值 25.80 ± 18.94 mm3 [平均值±标准差，p = 0.44]）。血流喷射在动脉瘤的治疗中起着重要作用，根据血流喷射部署填充线圈可能会带来更好的血液动力学环境。

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来源期刊

International Journal for Numerical Methods in Biomedical Engineering ENGINEERING, BIOMEDICAL-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

4.50

自引率

9.50%

发文量

103

审稿时长

3 months

期刊介绍： All differential equation based models for biomedical applications and their novel solutions (using either established numerical methods such as finite difference, finite element and finite volume methods or new numerical methods) are within the scope of this journal. Manuscripts with experimental and analytical themes are also welcome if a component of the paper deals with numerical methods. Special cases that may not involve differential equations such as image processing, meshing and artificial intelligence are within the scope. Any research that is broadly linked to the wellbeing of the human body, either directly or indirectly, is also within the scope of this journal.