Experimental Evaluation of a Deformable Registration Algorithm for Motion Correction in PET-CT Guided Biopsy.

Rahul Khare, Guillaume Sala, Paul Kinahan, Giuseppe Esposito, Filip Banovac, Kevin Cleary, Andinet Enquobahrie
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引用次数: 1

Abstract

Positron emission tomography computed tomography (PET-CT) images are increasingly being used for guidance during percutaneous biopsy. However, due to the physics of image acquisition, PET-CT images are susceptible to problems due to respiratory and cardiac motion, leading to inaccurate tumor localization, shape distortion, and attenuation correction. To address these problems, we present a method for motion correction that relies on respiratory gated CT images aligned using a deformable registration algorithm. In this work, we use two deformable registration algorithms and two optimization approaches for registering the CT images obtained over the respiratory cycle. The two algorithms are the BSpline and the symmetric forces Demons registration. In the first optmization approach, CT images at each time point are registered to a single reference time point. In the second approach, deformation maps are obtained to align each CT time point with its adjacent time point. These deformations are then composed to find the deformation with respect to a reference time point. We evaluate these two algorithms and optimization approaches using respiratory gated CT images obtained from 7 patients. Our results show that overall the BSpline registration algorithm with the reference optimization approach gives the best results.

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PET-CT引导下活检运动校正可变形配准算法的实验评价。
正电子发射断层扫描计算机断层扫描(PET-CT)图像越来越多地被用于经皮活检的指导。然而,由于图像采集的物理特性,PET-CT图像容易受到呼吸和心脏运动的影响,导致肿瘤定位不准确、形状失真、衰减校正。为了解决这些问题,我们提出了一种运动校正方法,该方法依赖于使用可变形配准算法对齐的呼吸门控CT图像。在这项工作中,我们使用两种可变形配准算法和两种优化方法来配准呼吸周期内获得的CT图像。这两种算法是b样条和对称力恶魔注册。在第一种优化方法中,每个时间点的CT图像被配准到单个参考时间点。在第二种方法中,获得变形图,使每个CT时间点与其相邻时间点对齐。然后将这些变形组合起来,以找到相对于参考时间点的变形。我们使用7例患者的呼吸门控CT图像对这两种算法和优化方法进行了评估。实验结果表明,采用参考优化方法的b样条配准算法总体上具有较好的配准效果。
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