Left Ventricular Motion Analysis Framework for the MATRIX-VT Study.

IF 2.3 3区医学 Q3 ENGINEERING, BIOMEDICAL

International Journal of Computer Assisted Radiology and Surgery Pub Date : 2025-09-05 DOI:10.1007/s11548-025-03510-1

Christian Janorschke, Sorin S Popescu, Jonas Osburg, Xinyu Lu, Jingyang Xie, Engin Yaman, Christoph Marquetand, Oliver Blanck, Hannes Alessandrini, Achim Schweikard, Roland R Tilz

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引用次数: 0

Abstract

Purpose: Ultrasound (US) is commonly used to assess left ventricular motion for examination of heart function. In stereotactic arrhythmia radioablation (STAR) therapy, managing cardiorespiratory motion during radiation delivery requires representation of motion information in computed tomography (CT) coordinates. Similar to conventional US-guided navigation during surgical procedures, 3D US can provide real-time motion data of the radiation target that could be transferred to CT coordinates and then be accounted for by the radiation system. A motion analysis framework is presented that covers all necessary components to capture and analyse US motion data and transfer it to CT coordinates.

Methods: Utilizing a robotic test set-up with a human phantom, a baseline and ground truth dataset is recorded for the development and implementation of the motion analysis framework. An optical tracking system and an additional spatial calibration phantom are used to determine necessary transformations. Methods for frame matching, calibration, registration and evaluation are implemented.

Results: The hardware set-up meets all requirements, including a frame rate exceeding 20 Hz and acceptable image quality, while involving only a few components that can easily be mounted and dismantled in a clinical context.The recorded phantom dataset meets all hardware-specific requirements including a frame rate exceeding 20 Hz, an offset between CT trigger time and the closest US recording of 2-20 ms as well as acceptable US image quality. The static phantom allows for quantitative evaluation by matching structures from different US frames in CT coordinates. While each individual step of the US and CT fusion process achieves the target accuracy of less than 5 mm error, the cumulative error over all transformations exceeded this limit for extreme probe positions.

Conclusion: The framework is developed and tested for the MATRIX-VT study and can be utilized for patient data evaluation as well as for transferring information such as positional data of moving anatomical structures between US and CTpredictive motion management in STAR therapy. Its modular design allows for the incorporation of advanced calibration and registration methods to address probe positioning limitations, thereby enhancing overall system performance for future applications.

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矩阵- vt研究的左心室运动分析框架。

目的：超声（US）通常用于评估左心室运动，以检查心功能。在立体定向心律失常放射消融（STAR）治疗中，处理放射传递过程中的心肺运动需要在计算机断层扫描（CT）坐标中表示运动信息。与外科手术过程中传统的US引导导航类似，3D US可以提供辐射目标的实时运动数据，这些数据可以转移到CT坐标，然后由辐射系统进行计算。提出了一个运动分析框架，该框架涵盖了捕获和分析美国运动数据并将其传输到CT坐标的所有必要组件。方法：利用具有人类幻影的机器人测试装置，记录基线和地面真实数据集，用于运动分析框架的开发和实施。利用光学跟踪系统和附加的空间校准体来确定必要的变换。实现了帧匹配、标定、配准和评估方法。结果：硬件设置满足所有要求，包括超过20 Hz的帧率和可接受的图像质量，同时只涉及几个易于在临床环境中安装和拆卸的组件。记录的幻影数据集满足所有硬件特定要求，包括帧率超过20 Hz， CT触发时间与最近的美国记录2-20毫秒之间的偏移，以及可接受的美国图像质量。静态幻影允许通过在CT坐标中匹配来自不同US帧的结构来进行定量评估。虽然US和CT融合过程的每个单独步骤都实现了小于5mm误差的目标精度，但对于极端探头位置，所有转换的累积误差超过了这一限制。结论：该框架是为MATRIX-VT研究开发和测试的，可用于患者数据评估，以及在STAR治疗中在US和CTpredictive motion management之间传递信息，如移动解剖结构的位置数据。其模块化设计允许结合先进的校准和配准方法，以解决探头定位限制，从而提高未来应用的整体系统性能。

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

International Journal of Computer Assisted Radiology and Surgery ENGINEERING, BIOMEDICAL-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

5.90

自引率

6.70%

发文量

243

审稿时长

6-12 weeks

期刊介绍： The International Journal for Computer Assisted Radiology and Surgery (IJCARS) is a peer-reviewed journal that provides a platform for closing the gap between medical and technical disciplines, and encourages interdisciplinary research and development activities in an international environment.