Cherenkov Imaged Bio-morphological Features Verify Patient Positioning with Deformable Tissue Translocation in Breast Radiotherapy

arXiv - PHYS - Medical Physics Pub Date : 2024-09-09 DOI:arxiv-2409.05680

Yao Chen, Savannah M. Decker, Petr Bruza, David J. Gladstone, Lesley A. Jarvis, Brian W. Pogue, Kimberley S. Samkoe, Rongxiao Zhang

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Abstract

Accurate patient positioning is critical for precise radiotherapy dose delivery, as positioning errors can significantly affect treatment outcomes. This study introduces a novel method for tracking loco-regional tissue deformation through Cherenkov image analysis during fractionated breast cancer radiotherapy. The primary goal was to develop and test an algorithm for Cherenkov-based regional position accuracy quantification, specifically for loco-regional deformations, which lack ideal quantification methods in radiotherapy. Blood vessel detection and segmentation were developed in Cherenkov images using a tissue phantom with incremental movements, and later applied to images from fractionated whole breast radiotherapy in human patients (n=10). A combined rigid and non-rigid registration technique was used to detect inter- and intra-fractional positioning variations. This approach quantified positioning variations in two parts: a global shift from rigid registration and a two-dimensional variation map of loco-regional deformation from non-rigid registration. The methodology was validated using an anthropomorphic chest phantom experiment, where known treatment couch translations and respiratory motion were simulated to assess inter- and intra-fractional uncertainties, yielding an average accuracy of 0.83 mm for couch translations up to 20 mm. Analysis of clinical Cherenkov data from ten breast cancer patients showed an inter-fraction setup variation of 3.7 plus minus 2.4 mm relative to the first fraction and loco-regional deformations (95th percentile) of up to 3.3 plus minus 1.9 mm. This study presents a Cherenkov-based approach to quantify global and local positioning variations, demonstrating feasibility in addressing loco-regional deformations that conventional imaging techniques fail to capture.

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利用切伦科夫成像生物形态特征验证乳腺放疗中可变形组织移位的患者定位

准确的患者定位对于精确的放射治疗剂量投放至关重要，因为定位误差会严重影响治疗效果。本研究介绍了一种新方法，在乳腺癌分次放射治疗过程中通过切伦科夫图像分析追踪局部区域组织变形。主要目的是开发和测试一种基于切伦科夫的区域位置精度量化算法，特别是针对放疗中缺乏理想量化方法的局部-区域变形。研究人员利用增量运动的组织模型开发了切伦科夫图像中的血管检测和分割算法，随后将其应用于人类患者（10 人）的全乳腺分次放疗图像。采用刚性和非刚性联合配准技术检测分段间和分段内的定位变化。这种方法将定位变化分为两部分进行量化：刚性配准产生的全局偏移和非刚性配准产生的局部区域变形的二维变化图。该方法通过人形胸部模型实验进行了验证，实验中模拟了已知的治疗床平移和呼吸运动，以评估分数间和分数内的不确定性，结果显示治疗床平移达 20 毫米时的平均精确度为 0.83 毫米。对十名乳腺癌患者的临床切伦科夫数据进行的分析表明，相对于第一部分，各部分之间的设置差异为 3.7 正负 2.4 毫米，局部区域变形（第 95 百分位数）最多为 3.3 正负 1.9 毫米。这项研究提出了一种基于切伦科夫的方法来量化全局和局部定位变化，证明了解决常规成像技术无法捕捉的局部区域变形的可行性。

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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arXiv - PHYS - Medical Physics

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