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带有和不带有线圈的脑动脉瘤模型近壁流的体外研究。

In vitro study of near-wall flow in a cerebral aneurysm model with and without coils.

机构信息

Biofluid Mechanics Laboratory Charité-Universitätsmedizin Berlin, Berlin, Germany.

出版信息

AJNR Am J Neuroradiol. 2010 Sep;31(8):1521-8. doi: 10.3174/ajnr.A2121. Epub 2010 May 20.

DOI:10.3174/ajnr.A2121
PMID:20488901
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7966090/
Abstract

BACKGROUND AND PURPOSE

Coil embolization procedures change the flow conditions in the cerebral aneurysm and, therefore, in the near-wall region. Knowledge of these flow changes may be helpful to optimize therapy. The goal of this study was to investigate the effect of the coil-packing attenuation on the near-wall flow and its variability due to differences in the coil structure.

MATERIALS AND METHODS

An enlarged transparent model of an ACA aneurysm was fabricated on the basis of CT angiography. The near-wall flow was visualized by using a recently proposed technique called Wall-PIV. Coil-packing attenuation of 10%, 15%, and 20% were investigated and compared with an aneurysmal flow without coils. Then the flow variability due to the coil introduction was analyzed in 10 experiments by using a packing attenuation of 15%.

RESULTS

A small packing attenuation of 10% already alters the near-wall flow significantly in a large part of the aneurysmal sac. These flow changes are characterized by a slow flow with short (interrupted) path lines. An increased packing attenuation expands the wall area exposed to the altered flow conditions. This area, however, depends on the coil position and/or on the 3D coil structure in the aneurysm.

CONCLUSIONS

To our knowledge, this is the first time the near-wall flow changes caused by coils in an aneurysm model have been visualized. It can be concluded that future hydrodynamic studies of coil therapy should include an investigation of the coil structure in addition to the coil-packing attenuation.

摘要

背景与目的

线圈栓塞术改变了脑动脉瘤内的流动条件,因此也改变了近壁区域的流动条件。了解这些流动变化可能有助于优化治疗。本研究的目的是研究线圈堆积衰减对近壁流动及其因线圈结构差异而产生的可变性的影响。

材料与方法

基于 CT 血管造影,制作了一个 ACA 动脉瘤的放大透明模型。使用最近提出的一种名为 Wall-PIV 的技术可视化近壁流动。研究了 10%、15%和 20%的线圈堆积衰减,并将其与无线圈的动脉瘤流动进行了比较。然后,在 10 个实验中使用 15%的堆积衰减分析了由于引入线圈而导致的流动可变性。

结果

10%的小堆积衰减已经在动脉瘤囊的大部分区域显著改变了近壁流动。这些流动变化的特点是流速缓慢,路径线短(中断)。堆积衰减的增加扩大了暴露于改变的流动条件的壁面积。然而,这个区域取决于线圈的位置和/或动脉瘤内的 3D 线圈结构。

结论

据我们所知,这是首次可视化动脉瘤模型中线圈引起的近壁流动变化。可以得出结论,未来对线圈治疗的流体动力学研究除了线圈堆积衰减外,还应该包括对线圈结构的研究。

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