Department of Radiation Oncology and Image-applied Therapy, Graduate School of Medicine, Kyoto University, Kyoto, Japan.
Med Phys. 2017 Aug;44(8):3899-3908. doi: 10.1002/mp.12351. Epub 2017 Jul 10.
To explore the effect of sampling interval of training data acquisition on the intrafractional prediction error of surrogate signal-based dynamic tumor-tracking using a gimbal-mounted linac.
Twenty pairs of respiratory motions were acquired from 20 patients (ten lung, five liver, and five pancreatic cancer patients) who underwent dynamic tumor-tracking with the Vero4DRT. First, respiratory motions were acquired as training data for an initial construction of the prediction model before the irradiation. Next, additional respiratory motions were acquired for an update of the prediction model due to the change of the respiratory pattern during the irradiation. The time elapsed prior to the second acquisition of the respiratory motion was 12.6 ± 3.1 min. A four-axis moving phantom reproduced patients' three dimensional (3D) target motions and one dimensional surrogate motions. To predict the future internal target motion from the external surrogate motion, prediction models were constructed by minimizing residual prediction errors for training data acquired at 80 and 320 ms sampling intervals for 20 s, and at 500, 1,000, and 2,000 ms sampling intervals for 60 s using orthogonal kV x-ray imaging systems. The accuracies of prediction models trained with various sampling intervals were estimated based on training data with each sampling interval during the training process. The intrafractional prediction errors for various prediction models were then calculated on intrafractional monitoring images taken for 30 s at the constant sampling interval of a 500 ms fairly to evaluate the prediction accuracy for the same motion pattern. In addition, the first respiratory motion was used for the training and the second respiratory motion was used for the evaluation of the intrafractional prediction errors for the changed respiratory motion to evaluate the robustness of the prediction models.
The training error of the prediction model was 1.7 ± 0.7 mm in 3D for all sampling intervals. The intrafractional prediction error for the same motion pattern was 1.9 ± 0.7 mm in 3D for an 80 ms sampling interval, which increased larger than 1 mm in 10.0% of prediction models trained at a 2,000 ms sampling interval with a significant difference (P < 0.01) and up to 2.5% for the other sampling intervals without a significant difference (P > 0.05). The intrafractional prediction error for the changed respiratory motion pattern increased to 5.1 ± 2.4 mm in 3D for an 80 ms sampling interval; however, there was not a significant difference in the robustness of the prediction model between the 80 ms sampling interval and other sampling intervals (P > 0.05).
Although the training error of the prediction model was consistent for the all sampling intervals, the prediction model using the larger sampling interval of the 2,000 ms increased the intrafractional prediction error for the same motion pattern. The realistic accuracy of the prediction model was difficult to estimate using the larger sampling interval during the training process. It is recommended to construct the prediction model at sampling interval ≤ 1,000 ms and to reconstruct the model during treatment.
探讨在使用带有万向架的直线加速器对基于替代信号的动态肿瘤跟踪进行分次内预测误差时,采集训练数据的采样间隔对预测的影响。
从 20 名接受 Vero4DRT 动态肿瘤跟踪的患者(10 名肺癌、5 名肝癌和 5 名胰腺癌患者)中采集了 20 对呼吸运动。首先,在照射前采集呼吸运动作为训练数据,以初步构建预测模型。接下来,由于照射过程中呼吸模式的变化,需要采集额外的呼吸运动来更新预测模型。第二次采集呼吸运动前的时间间隔为 12.6±3.1 分钟。一个四轴运动体模再现了患者的三维(3D)靶运动和一维替代运动。为了从外部替代运动预测未来的内部靶运动,使用正交千伏 X 射线成像系统,以 80ms 和 320ms 的采样间隔采集 20 秒,以 500ms、1000ms 和 2000ms 的采样间隔采集 60 秒的训练数据,构建预测模型,以最小化预测误差。基于训练过程中每个采样间隔的训练数据,估计使用不同采样间隔训练的预测模型的准确性。然后,在相同的采样间隔下,对 30 秒的分次内监测图像进行计算,评估各种预测模型的分次内预测误差,以评估相同运动模式的预测准确性。此外,使用第一次呼吸运动进行训练,使用第二次呼吸运动进行评估,以评估对变化的呼吸运动的分次内预测误差,以评估预测模型的稳健性。
所有采样间隔的预测模型的训练误差均为 3D 方向上的 1.7±0.7mm。对于相同的运动模式,80ms 采样间隔的分次内预测误差为 3D 方向上的 1.9±0.7mm,而在 2000ms 采样间隔训练的预测模型中,10.0%的预测模型的分次内预测误差增加了 1mm 以上,差异有统计学意义(P<0.01),而其他采样间隔的预测模型的分次内预测误差没有显著差异(P>0.05)。对于变化的呼吸运动模式,80ms 采样间隔的分次内预测误差增加到 3D 方向上的 5.1±2.4mm;然而,在 80ms 采样间隔和其他采样间隔之间,预测模型的稳健性没有显著差异(P>0.05)。
尽管预测模型的训练误差在所有采样间隔上是一致的,但使用较大的 2000ms 采样间隔的预测模型增加了相同运动模式的分次内预测误差。在训练过程中使用较大的采样间隔很难准确估计预测模型的实际精度。建议在采样间隔≤1000ms 时构建预测模型,并在治疗过程中重建模型。
