FBG-driven simulation for virtual augmentation of fluoroscopic images during endovascular interventions

IF 2.8 Q3 ENGINEERING, BIOMEDICAL

Healthcare Technology Letters Pub Date : 2024-12-07 DOI:10.1049/htl2.12108

Valentina Scarponi, Juan Verde, Nazim Haouchine, Michel Duprez, Florent Nageotte, Stéphane Cotin

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引用次数: 0

Abstract

Endovascular interventions are procedures designed to diagnose and treat vascular diseases, using catheters to navigate inside arteries and veins. Thanks to their minimal invasiveness, they offer many benefits, such as reduced pain and hospital stays, but also present many challenges for clinicians, as they require specialized training and heavy use of X-rays. This is particularly relevant when accessing (i.e. cannulating) small arteries with steep angles, such as most aortic branches. To address this difficulty, a novel solution that enhances fluoroscopic 2D images in real-time by displaying virtual configurations of the catheter and guidewire is proposed. In contrast to existing works, proposing either simulators or simple augmented reality frameworks, this approach involves a predictive simulation showing the resulting shape of the catheter after guidewire withdrawal without requiring the clinician to perform this task. This system demonstrated accurate prediction with a mean 3D error of 2.4 $\pm$ 1.3 mm and a mean error of 1.1 $\pm$ 0.7 mm on the fluoroscopic image plane between the real catheter shape after guidewire withdrawal and the predicted shape. A user study reported an average intervention time reduction of 56 $%$ when adopting this system, resulting in a lower X-ray exposure.

Abstract Image

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在血管内介入期间，fbg驱动的虚拟增强透视图像模拟。

血管内介入是用来诊断和治疗血管疾病的程序，使用导管在动脉和静脉内导航。由于其侵入性最小，它们提供了许多好处，例如减轻疼痛和住院时间，但也给临床医生带来了许多挑战，因为它们需要专门的培训和大量使用x射线。这在进入（即插管）小动脉（如大多数主动脉分支）时尤其重要。为了解决这一困难，提出了一种新的解决方案，通过显示导管和导丝的虚拟结构来实时增强透视二维图像。与现有的工作相反，提出了模拟器或简单的增强现实框架，该方法包括预测模拟，显示导丝拔出后导管的最终形状，而不需要临床医生执行此任务。该系统预测准确，导丝拔出后导管实际形状与预测形状在透视图像平面上的平均三维误差为2.4±1.3 mm，平均误差为1.1±0.7 mm。一项用户研究报告称，采用该系统后，平均干预时间减少了56%，从而降低了x射线暴露。

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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来源期刊

Healthcare Technology Letters Health Professions-Health Information Management

CiteScore

6.10

自引率

4.80%

发文量

审稿时长

22 weeks

期刊介绍： Healthcare Technology Letters aims to bring together an audience of biomedical and electrical engineers, physical and computer scientists, and mathematicians to enable the exchange of the latest ideas and advances through rapid online publication of original healthcare technology research. Major themes of the journal include (but are not limited to): Major technological/methodological areas: Biomedical signal processing Biomedical imaging and image processing Bioinstrumentation (sensors, wearable technologies, etc) Biomedical informatics Major application areas: Cardiovascular and respiratory systems engineering Neural engineering, neuromuscular systems Rehabilitation engineering Bio-robotics, surgical planning and biomechanics Therapeutic and diagnostic systems, devices and technologies Clinical engineering Healthcare information systems, telemedicine, mHealth.