利用外部呼吸替代物优化三维目标位置估计模型的训练周期。

Optimization of training periods for the estimation model of three-dimensional target positions using an external respiratory surrogate.

机构信息

Department of Nuclear Engineering, Graduate School of Engineering, Kyoto University, Nishikyo-ku, Kyoto, 615-8530, Japan.

Department of Radiation Oncology and Image-applied Therapy, Graduate School of Medicine, Kyoto University, 54 Kawahara-cho, Shogoin, Sakyo-ku, Kyoto, 606-8507, Japan.

出版信息

Radiat Oncol. 2018 Apr 19;13(1):73. doi: 10.1186/s13014-018-1019-9.

DOI:10.1186/s13014-018-1019-9

PMID:29673368

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5909266/

Abstract

BACKGROUND

During therapeutic beam irradiation, an unvisualized three-dimensional (3D) target position should be estimated using an external surrogate with an estimation model. Training periods for the developed model with no additional imaging during beam irradiation were optimized using clinical data.

METHODS

Dual-source 4D-CBCT projection data for 20 lung cancer patients were used for validation. Each patient underwent one to three scans. The actual target positions of each scan were equally divided into two equal parts: one for the modeling and the other for the validating session. A quadratic target position estimation equation was constructed during the modeling session. Various training periods for the session-i.e., modeling periods (T)-were employed: T ∈ {5,10,15,25,35} [s]. First, the equation was used to estimate target positions in the validating session of the same scan (intra-scan estimations). Second, the equation was then used to estimate target positions in the validating session of another temporally different scan (inter-scan estimations). The baseline drift of the surrogate and target between scans was corrected. Various training periods for the baseline drift correction-i.e., correction periods (Ts)-were employed: T ∈ {5,10,15; T ≤ T} [s]. Evaluations were conducted with and without the correction. The difference between the actual and estimated target positions was evaluated by the root-mean-square error (RMSE).

RESULTS

The range of mean respiratory period and 3D motion amplitude of the target was 2.4-13.0 s and 2.8-34.2 mm, respectively. On intra-scan estimation, the median 3D RMSE was within 1.5-2.1 mm, supported by previous studies. On inter-scan estimation, median elapsed time between scans was 10.1 min. All Ts exhibited 75th percentile 3D RMSEs of 5.0-6.4 mm due to baseline drift of the surrogate and the target. After the correction, those for each Ts fell by 1.4-2.3 mm. The median 3D RMSE for both the 10-s T and the T period was 2.4 mm, which plateaued when the two training periods exceeded 10 s.

CONCLUSIONS

A widely-applicable estimation model for the 3D target positions during beam irradiation was developed. The optimal T and T for the model were both 10 s, to allow for more than one respiratory cycle.

TRIAL REGISTRATION

UMIN000014825 . Registered: 11 August 2014.

摘要

背景

在治疗射束照射期间，应使用具有估计模型的外部替代物来估计不可见的三维（3D）目标位置。使用临床数据优化了在射束照射期间没有额外成像的开发模型的训练期。

方法

使用 20 例肺癌患者的双源 4D-CBCT 投影数据进行验证。每位患者进行了一次到三次扫描。每次扫描的实际目标位置均等分为两部分：一部分用于建模，另一部分用于验证会话。在建模会话期间构建了二次目标位置估计方程。为会话-i 即建模期（T）使用了各种训练期：T ∈ {5,10,15,25,35} [s]。首先，该方程用于估计同一扫描的验证会话中的目标位置（内部扫描估计）。其次，然后将该方程用于估计另一个时间上不同的扫描的验证会话中的目标位置（跨扫描估计）。在扫描之间校正了替代物和目标的基线漂移。为基线漂移校正-i 即校正期（Ts）-使用了各种训练期：T ∈ {5,10,15；T ≤ T} [s]。校正和不校正均进行了评估。通过均方根误差（RMSE）评估实际和估计目标位置之间的差异。

结果

目标的平均呼吸周期和 3D 运动幅度的范围分别为 2.4-13.0 s 和 2.8-34.2 mm。在内部扫描估计中，3D RMSE 的中位数在 1.5-2.1 mm 以内，支持先前的研究。在跨扫描估计中，扫描之间的中位间隔时间为 10.1 分钟。所有 Ts 均因替代物和目标的基线漂移而表现出 75%分位数 3D RMSE 为 5.0-6.4 mm。校正后，每个 Ts 的值降低了 1.4-2.3 mm。10 s T 和 T 期的中位数 3D RMSE 均为 2.4 mm，当两个训练期超过 10 s 时，中位数 3D RMSE 趋于稳定。