Automatic lung segmentation of magnetic resonance images: A new approach applied to healthy volunteers undergoing enhanced Deep-Inspiration-Breath-Hold for motion-mitigated 4D proton therapy of lung tumors

John H. Missimer , Frank Emert , Antony J. Lomax , Damien C. Weber
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Abstract

Background and purpose

Respiratory suppression techniques represent an effective motion mitigation strategy for 4D-irradiation of lung tumors with protons. A magnetic resonance imaging (MRI)-based study applied and analyzed methods for this purpose, including enhanced Deep-Inspiration-Breath-Hold (eDIBH). Twenty-one healthy volunteers (41–58 years) underwent thoracic MR scans in four imaging sessions containing two eDIBH-guided MRIs per session to simulate motion-dependent irradiation conditions. The automated MRI segmentation algorithm presented here was critical in determining the lung volumes (LVs) achieved during eDIBH.

Materials and methods

The study included 168 MRIs acquired under eDIBH conditions. The lung segmentation algorithm consisted of four analysis steps: (i) image preprocessing, (ii) MRI histogram analysis with thresholding, (iii) automatic segmentation, (iv) 3D-clustering. To validate the algorithm, 46 eDIBH-MRIs were manually contoured. Sørensen-Dice similarity coefficients (DSCs) and relative deviations of LVs were determined as similarity measures. Assessment of intrasessional and intersessional LV variations and their differences provided estimates of statistical and systematic errors.

Results

Lung segmentation time for 100 2D-MRI planes was ∼ 10 s. Compared to manual lung contouring, the median DSC was 0.94 with a lower 95 % confidence level (CL) of 0.92. The relative volume deviations yielded a median value of 0.059 and 95 % CLs of −0.013 and 0.13. Artifact-based volume errors, mainly of the trachea, were estimated. Estimated statistical and systematic errors ranged between 6 and 8 %.

Conclusions

The presented analytical algorithm is fast, precise, and readily available. The results are comparable to time-consuming, manual segmentations and other automatic segmentation approaches. Post-processing to remove image artifacts is under development.

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磁共振图像的自动肺部分割:一种新方法,应用于接受增强型深吸气-屏气治疗的健康志愿者,用于肺部肿瘤的运动诱导型四维质子治疗
背景和目的呼吸抑制技术是利用质子对肺部肿瘤进行四维照射的一种有效的运动缓解策略。一项基于磁共振成像(MRI)的研究为此应用并分析了各种方法,包括增强型深吸气-呼吸保持(eDIBH)。21 名健康志愿者(41-58 岁)接受了四次胸部磁共振扫描,每次扫描包含两次 eDIBH 引导的磁共振成像,以模拟运动相关的辐照条件。本文介绍的自动磁共振成像分割算法对于确定 eDIBH 期间实现的肺容积 (LV) 至关重要。肺分割算法包括四个分析步骤:(i) 图像预处理,(ii) 带阈值的 MRI 直方图分析,(iii) 自动分割,(iv) 三维聚类。为了验证该算法,对 46 幅 eDIBH-MRI 图像进行了人工轮廓分析。索伦森-戴斯相似性系数(DSC)和左心室相对偏差被确定为相似性度量。结果 100 个 2D-MRI 平面的肺部分割时间为 10 秒。与人工肺部轮廓制作相比,DSC 的中位数为 0.94,95% 置信度(CL)为 0.92。相对容积偏差的中值为 0.059,95 % 置信度为-0.013 和 0.13。对基于伪影的容积误差进行了估计,主要是气管的误差。估计的统计误差和系统误差介于 6% 和 8% 之间。其结果可与耗时的人工分割和其他自动分割方法相媲美。消除图像伪影的后期处理正在开发中。
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来源期刊
Physics and Imaging in Radiation Oncology
Physics and Imaging in Radiation Oncology Physics and Astronomy-Radiation
CiteScore
5.30
自引率
18.90%
发文量
93
审稿时长
6 weeks
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