Validation of a Novel Geometric Coordination Registration using Manual and Semi-automatic Registration in Cone-beam Computed Tomogram

Image Processing: Machine Vision Applications Pub Date : 2016-02-14 DOI:10.2352/ISSN.2470-1173.2016.14.IPMVA-373

W. Y. Lam, H. Luk, Henry Y. T. Ngan, R. T. Hsung, T. Goto, E. Pow

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引用次数: 1

Abstract

Cartesian coordinates define on a physical cubic corner (CC) with the corner tip as the origin and three corresponding line angles as (x, y, z)-axes. In its image (virtual) domains such as these obtained by cone-beam computed tomography (CBCT) and optical surface scanning, a single coordinate can then be registered based on the CC. The advantage of using a CC in registration is simple and accurate physical coordinate measurement. The accuracy of image-to-physical (IP) and imageto-image (II) transformations, measured by target registration error (TRE), can then be validated by comparing coordinates of target points in the virtual domains to that of the physical control. For the CBCT, the registration may be performed manually using a surgical planning software SimPlant Pro (manual registration (MR)) or semi-automatically using MeshLab and 3D Slicer (semiautomatic registration (SR)) matching the virtual display axes to the corresponding (x-y-z)-axes. This study aims to validate the use of CC as a surgical stereotactic marker by measuring TRE in MR and SR respectively. Mean TRE is 0.56 +/0.24 mm for MR and 0.39 +/0.21 mm for SR. The SR results in a more accurate registration than the MR and point-based registration with 20 fiducial points. TRE of the MR is less than 1.0 mm and still acceptable clinically.

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锥束计算机层析图手工与半自动配准的几何配准方法的验证

笛卡尔坐标在一个物理立方角(CC)上定义，以角尖为原点，三个相应的线角为(x, y, z)轴。在锥束计算机断层扫描(CBCT)和光学表面扫描获得的图像(虚拟)域中，可以基于CC进行单个坐标的配准。使用CC进行配准的优点是物理坐标测量简单准确。通过目标配准误差(TRE)测量图像到物理(IP)和图像到图像(II)转换的准确性，然后可以通过将虚拟域中目标点的坐标与物理控制的坐标进行比较来验证。对于CBCT，可以使用手术计划软件SimPlant Pro(手动配准(MR))手动进行配准，也可以使用MeshLab和3D Slicer(半自动配准(SR))将虚拟显示轴与相应的(x-y-z)轴匹配。本研究旨在通过分别在MR和SR中测量TRE来验证CC作为外科立体定向标记物的使用。MR的平均TRE为0.56 +/0.24 mm, SR为0.39 +/0.21 mm。SR的配准结果比MR和基于点的配准更准确，配准值为20个基点。MR的TRE小于1.0 mm，临床上仍可接受。

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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Image Processing: Machine Vision Applications

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