预测腹主动脉瘤壁应力的人工智能框架

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY
Timothy K. Chung , Nathan L. Liang , David A. Vorp
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引用次数: 4

摘要

腹主动脉瘤(AAA)已被严格调查,以了解其破裂的风险何时超过修复的风险。腹主动脉瘤是美国第13大死亡原因。当动脉瘤直径超过5.5 cm时,需要进行临床干预,但这种“一贯性”的标准是不够的,因为据报道,小于5.5 cm的AAA动脉瘤破裂的比例高达四分之一。因此,需要一种更可靠的、针对患者的临床工具来帮助管理AAA。AAA的生物力学评估被认为可以为破裂风险提供关键的物理见解,但由于专业知识、时间和计算要求,基于生物力学的工具的临床翻译受到限制。据估计,截至2015年,只有348例AAA病例进行了生物力学应力分析,这表明样本量不足,无法使这种分析在临床中具有相关性。人工智能(AI)算法通过减少使用传统方法评估这些复杂结构中管壁应力所需的总时间,为提高AAA生物力学分析的吞吐量提供了潜力。这可以通过自动分割医学图像中的感兴趣区域并使用机器学习模型来预测AAA的壁应力来实现。在本研究中,我们提出了一种基于人工智能的自动化方法来预测单个AAA的生物力学壁应力。与更传统的方法相比,使用这种方法的预测在更短的时间内完成(~ 4小时对20秒)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Artificial intelligence framework to predict wall stress in abdominal aortic aneurysm

Artificial intelligence framework to predict wall stress in abdominal aortic aneurysm

Artificial intelligence framework to predict wall stress in abdominal aortic aneurysm

Artificial intelligence framework to predict wall stress in abdominal aortic aneurysm

Abdominal aortic aneurysms (AAA) have been rigorously investigated to understand when their risk of rupture - which is the 13th leading cause of death in the US – exceeds the risks associated with repair. Clinical intervention occurs when an aneurysm diameter exceeds 5.5 cm, but this “one-size fits all” criterion is insufficient, as it has been reported thatup to a quarter of AAA smaller than 5.5 cm do rupture. Therefore, there is a need for a more reliable, patient-specific, clinical tool to aide in the management of AAA. Biomechanical assessment of AAA is thought to provide critical physical insights to rupture risk, but clinical translataion of biomechanics-based tools has been limited due to the expertise, time, and computational requirements. It was estimated that through 2015, only 348 individual AAA cases have had biomechanical stress analysis performed, suggesting a deficient sample size to make such analysis relevant in the clinic. Artificial intelligence (AI) algorithms offer the potential to increase the throughput of AAA biomechanical analyses by reducing the overall time required to assess the wall stresses in these complex structures using traditional methods. This can be achieved by automatically segmenting regions of interest from medical images and using machine learning models to predict wall stresses of AAA. In this study, we present an automated AI-based methodology to predict the biomechanical wall stresses for individual AAA. The predictions using this approach were completed in a significantly less amount of time compared to a more traditional approach (∼4 hours vs 20 seconds).

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来源期刊
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
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