Fully Distributed Shape Sensing of a Flexible Surgical Needle Using Optical Frequency Domain Reflectometry for Prostate Interventions.

Jacynthe Francoeur, Dimitri Lezcano, Yernar Zhetpissov, Raman Kashyap, Iulian Iordachita, Samuel Kadoury
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Abstract

In minimally invasive procedures such as biopsies and prostate cancer brachytherapy, accurate needle placement remains challenging due to limitations in current tracking methods related to interference, reliability, resolution or image contrast. This often leads to frequent needle adjustments and reinsertions. To address these shortcomings, we introduce an optimized needle shape-sensing method using a fully distributed grating-based sensor. The proposed method uses simple trigonometric and geometric modeling of the fiber using optical frequency domain reflectometry (OFDR), without requiring prior knowledge of tissue properties or needle deflection shape and amplitude. Our optimization process includes a reproducible calibration process and a novel tip curvature compensation method. We validate our approach through experiments in artificial isotropic and inhomogeneous animal tissues, establishing ground truth using 3D stereo vision and cone beam computed tomography (CBCT) acquisitions, respectively. Our results yield an average RMSE ranging from 0.58 ± 0.21 mm to 0.66 ± 0.20 mm depending on the chosen spatial resolution, achieving the submillimeter accuracy required for interventional procedures.

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利用光频域反射仪对柔性手术针进行全分布式形状传感,用于前列腺介入治疗。
在活组织检查和前列腺癌近距离放射治疗等微创手术中,由于目前的追踪方法在干扰、可靠性、分辨率或图像对比度方面存在局限性,准确放置针头仍是一项挑战。这往往导致针头的频繁调整和重新插入。为了解决这些缺陷,我们采用全分布式光栅传感器引入了一种优化的针形状感应方法。该方法利用光频域反射仪 (OFDR) 对光纤进行简单的三角和几何建模,无需事先了解组织特性或针头偏转形状和振幅。我们的优化过程包括可重复的校准过程和新颖的针尖曲率补偿方法。我们通过人工各向同性和不均匀动物组织的实验验证了我们的方法,分别使用三维立体视觉和锥形束计算机断层扫描(CBCT)采集建立了地面实况。根据所选空间分辨率的不同,我们的结果得出了从 0.58 ± 0.21 毫米到 0.66 ± 0.20 毫米的平均 RMSE 值,达到了介入手术所需的亚毫米级精度。
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Towards a Unified Approach for Continuously-Variable Impedance Control of Powered Prosthetic Legs over Walking Speeds and Inclines. Cooperative vs. Teleoperation Control of the Steady Hand Eye Robot with Adaptive Sclera Force Control: A Comparative Study. Bevel-Tip Needle Deflection Modeling, Simulation, and Validation in Multi-Layer Tissues. Exploring the Needle Tip Interaction Force with Retinal Tissue Deformation in Vitreoretinal Surgery. Fully Distributed Shape Sensing of a Flexible Surgical Needle Using Optical Frequency Domain Reflectometry for Prostate Interventions.
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