Department of Radiation Oncology and Image-applied Therapy, Graduate School of Medicine, Kyoto University, Kyoto 606-8507, Japan.
Med Phys. 2013 Sep;40(9):091705. doi: 10.1118/1.4817236.
To quantify the predictive uncertainty in infrared (IR)-marker-based dynamic tumor tracking irradiation (IR Tracking) with Vero4DRT (MHI-TM2000) for lung cancer using logfiles.
A total of 110 logfiles for 10 patients with lung cancer who underwent IR Tracking were analyzed. Before beam delivery, external IR markers and implanted gold markers were monitored for 40 s with the IR camera every 16.7 ms and with an orthogonal kV x-ray imaging subsystem every 80 or 160 ms. A predictive model [four-dimensional (4D) model] was then created to correlate the positions of the IR markers (PIR) with the three-dimensional (3D) positions of the tumor indicated by the implanted gold markers (Pdetect). The sequence of these processes was defined as 4D modeling. During beam delivery, the 4D model predicted the future 3D target positions (Ppredict) from the PIR in real-time, and the gimbaled x-ray head then tracked the target continuously. In clinical practice, the authors updated the 4D model at least once during each treatment session to improve its predictive accuracy. This study evaluated the predictive errors in 4D modeling (E4DM) and those resulting from the baseline drift of PIR and Pdetect during a treatment session (EBD). E4DM was defined as the difference between Ppredict and Pdetect in 4D modeling, and EBD was defined as the mean difference between Ppredict calculated from PIR in updated 4D modeling using (a) a 4D model created from training data before the model update and (b) an updated 4D model created from new training data.
The mean E4DM was 0.0 mm with the exception of one logfile. Standard deviations of E4DM ranged from 0.1 to 1.0, 0.1 to 1.6, and 0.2 to 1.3 mm in the left-right (LR), anterior-posterior (AP), and superior-inferior (SI) directions, respectively. The median elapsed time before updating the 4D model was 13 (range, 2-33) min, and the median frequency of 4D modeling was twice (range, 2-3 times) per treatment session. EBD ranged from -1.0 to 1.0, -2.1 to 3.3, and -2.0 to 3.5 mm in the LR, AP, and SI directions, respectively. EBD was highly correlated with BDdetect in the LR (R = -0.83) and AP directions (R = -0.88), but not in the SI direction (R = -0.40). Meanwhile, EBD was highly correlated with BDIR in the SI direction (R = -0.67), but not in the LR (R = 0.15) or AP (R = -0.11) direction. If the 4D model was not updated in the presence of intrafractional baseline drift, the predicted target position deviated from the detected target position systematically.
Application of IR Tracking substantially reduced the geometric error caused by respiratory motion; however, an intrafractional error due to baseline drift of >3 mm was occasionally observed. To compensate for EBD, the authors recommend checking the target and IR marker positions constantly and updating the 4D model several times during a treatment session.
利用 Vero4DRT(MHI-TM2000)的红外(IR)标记物动态肿瘤跟踪照射(IR Tracking)的日志文件,定量分析肺癌中基于预测不确定性。
分析了 10 例肺癌患者共 110 份日志文件。在束流传输之前,每 16.7ms 用 IR 相机和 80 或 160ms 的正交千伏 X 射线成像子系统对外部 IR 标记物和植入的金标记物进行 40s 的监测。然后创建一个预测模型(四维模型),将 IR 标记物的位置(PIR)与植入金标记物指示的三维(3D)肿瘤位置(Pdetect)相关联。这个过程的顺序被定义为 4D 建模。在束流传输过程中,4D 模型从 PIR 实时预测未来的 3D 目标位置(Ppredict),然后万向架的 X 射线头连续跟踪目标。在临床实践中,作者在每次治疗过程中至少更新一次 4D 模型,以提高其预测精度。本研究评估了 4D 建模中的预测误差(E4DM)和治疗过程中 PIR 和 Pdetect 基线漂移引起的误差(EBD)。E4DM 定义为 4D 建模中 Ppredict 和 Pdetect 之间的差异,EBD 定义为使用(a)更新前的模型更新后,使用训练数据创建的 4D 模型和(b)使用新训练数据创建的更新 4D 模型计算的从 PIR 预测的 Ppredict 之间的平均差异。
除了一个日志文件外,平均 E4DM 为 0.0mm。E4DM 的标准差分别在左右(LR)、前后(AP)和上下(SI)方向上为 0.1 至 1.0、0.1 至 1.6 和 0.2 至 1.3mm。更新 4D 模型之前的中位时间间隔为 13(范围 2-33)min,4D 建模的中位频率为每治疗过程两次(范围 2-3 次)。EBD 在 LR(R = -0.83)和 AP 方向(R = -0.88)上分别为-1.0 至 1.0、-2.1 至 3.3 和-2.0 至 3.5mm,在 SI 方向上相关性不高(R = -0.40)。同时,EBD 在 SI 方向上与 BDIR 高度相关(R = -0.67),但在 LR 方向上(R = 0.15)或 AP 方向上(R = -0.11)相关性不高。如果在分次内存在基线漂移的情况下不更新 4D 模型,则预测的目标位置会系统地偏离检测到的目标位置。
IR Tracking 的应用显著降低了呼吸运动引起的几何误差;然而,偶尔会观察到大于 3mm 的分次内误差。为了补偿 EBD,作者建议在治疗过程中定期检查目标和 IR 标记物的位置,并多次更新 4D 模型。
