Modeling of aneurysm progression in anterior cerebral arteries to estimate rupture risk: A computational study

Gurpreet Singh, Prem Nath Yadav, Shubham Gupta, Arnab Chanda
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Abstract

A cerebral aneurysm is a medical disorder that occurs when the wall of the cerebral artery ruptures as a result of abnormally high blood pressure. The imaging techniques that are now in use, such as CT and MRI scans, can only show the geometrical information about an aneurysm and cannot determine the risk of rupture that relates to the progression of an aneurysm. In this work, computational modeling was performed to simulate aneurysm progression and to analyze the stress development for a variety of different pressure loading conditions. Image segmentation was utilized to segment one anterior cerebral artery and one anterior communicating artery, both of which were rebuilt to generate aneurysm models at susceptible locations of the aneurysm progression simulation. To represent the various phases of aneurysm development, five different aneurysm sizes with two varying wall thicknesses were identified. The diastolic pressure, the systolic pressure, and the hypertensive pressure were applied to simulate the actual pressure conditions for the anterior cerebral arteries. The rupture risk was determined by analyzing the stress distributions across all of the models. It was estimated that the stresses around the walls of aneurysm varies with an incremental change in both the diameter of the aneurysm and the magnitude of the blood pressure. Aneurysms that were observed to have significant rupture risks were those that had a large diameter and a thin wall and were simulated at high blood pressures. The findings of this research are anticipated to assist medical practitioners in estimating rupture risks with known imaging, based on the diameters of aneurysms, and in early decision making for the treatment of aneurysms.

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脑前动脉动脉瘤进展的建模以估计破裂风险:一项计算研究
脑动脉瘤是一种医学疾病,当大脑动脉壁因异常高血压而破裂时发生。目前使用的成像技术,如CT和MRI扫描,只能显示动脉瘤的几何信息,而不能确定与动脉瘤进展有关的破裂风险。在这项工作中,进行了计算建模,以模拟动脉瘤的进展,并分析各种不同压力载荷条件下的应力发展。图像分割用于分割一条大脑前动脉和一条前交通动脉,这两条动脉都被重建以在动脉瘤进展模拟的敏感位置生成动脉瘤模型。为了代表动脉瘤发展的不同阶段,确定了五种不同大小、两种不同壁厚的动脉瘤。应用舒张压、收缩压和高血压压力来模拟大脑前动脉的实际压力条件。破裂风险是通过分析所有模型的应力分布来确定的。据估计,动脉瘤壁周围的应力随着动脉瘤直径和血压大小的增量变化而变化。被观察到具有显著破裂风险的动脉瘤是那些直径大、壁薄并在高压下模拟的动脉瘤。这项研究的发现有望帮助医生根据动脉瘤的直径,通过已知的成像来估计破裂风险,并在动脉瘤治疗的早期决策中提供帮助。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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Biomedical engineering advances
Biomedical engineering advances Bioengineering, Biomedical Engineering
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59 days
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