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用于MRI引导导管三维形状测量的折反射立体跟踪技术

Catadioptric Stereo Tracking for Three Dimensional Shape Measurement of MRI Guided Catheters.

作者信息

Jackson Russell C, Liu Taoming, Çavuşoğlu M Cenk

机构信息

Department of Electrical Engineering and Computer Science (EECS) at Case Western Reserve University in Cleveland, OH, USA.

出版信息

IEEE Int Conf Robot Autom. 2016 May;2016:4422-4428. doi: 10.1109/ICRA.2016.7487641. Epub 2016 Jun 9.

DOI:10.1109/ICRA.2016.7487641
PMID:28392968
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5382962/
Abstract

The recent introduction of Magnetic Resonance Imaging (MRI)-actuated steerable catheters lays the ground work for increasing the efficacy of cardiac catheter procedures. The MRI, while capable of imaging the catheter for tracking and control, does not fulfill all of the needs required to identify and develop a complete catheter model. Specifially, the frequency response of the catheter must be identified to ensure stable control of the catheter system. This requires a higher frequency imaging than the MRI can achieve. This work uses a catadioptric stereo camera system consisting of a mirror and a single camera in order to track a MRI actuated catheter inside a MRI machine. The catadioptric system works in parallel to the MRI and is capable of recording the catheter at 60 fps for post processing. The accuracy of the catadioptric system is verified in imaging conditions that would be found inside the MRI. The stereo camera is then used to track a catheter as it is actuated inside the MRI.

摘要

最近引入的磁共振成像(MRI)驱动的可操纵导管为提高心脏导管手术的疗效奠定了基础。MRI虽然能够对导管进行成像以进行跟踪和控制,但并不能满足识别和开发完整导管模型所需的所有需求。具体而言,必须识别导管的频率响应以确保对导管系统的稳定控制。这需要比MRI所能实现的更高频率的成像。这项工作使用了一个由镜子和单台相机组成的折反射立体相机系统,以便在MRI机器内部跟踪MRI驱动的导管。该折反射系统与MRI并行工作,能够以60帧/秒的速度记录导管以便进行后处理。在MRI内部会出现的成像条件下验证了折反射系统的准确性。然后使用立体相机在MRI内部驱动导管时对其进行跟踪。

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