Impact of sampling interval in training data acquisition on intrafractional predictive accuracy of indirect dynamic tumor‐tracking radiotherapy

Mukumoto, Nobutaka; Nakamura, Mitsuhiro; Akimoto, Mami; Miyabe, Yuki; Yokota, Kenji; Matsuo, Yukinori; Mizowaki, Takashi; Hiraoka, Masahiro

doi:10.1002/mp.12351

Cited by 7 publications

(9 citation statements)

References 25 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In a practical treatment scenario, the sampling rate of the EPID varies according to the dose rate. However, Mukumoto et al . have shown that within the sampling range of 0.08 to 0.2 s, the changes in the prediction accuracy of respiratory signals is insignificant ( P > 0.05).…”

Section: Discussionmentioning

confidence: 96%

Feasibility of predicting tumor motion using online data acquired during treatment and a generalized neural network optimized with offline patient tumor trajectories

et al. 2018

View full text Add to dashboard Cite

show abstract

Section: Discussionmentioning

confidence: 96%

Feasibility of predicting tumor motion using online data acquired during treatment and a generalized neural network optimized with offline patient tumor trajectories

et al. 2018

View full text Add to dashboard Cite

show abstract

“…Using frequently updated input data to train a prediction model may get higher prediction accuracy. It is recommended to use the data with a sampling interval of less than 1 second to build a prediction model (33). The frame rates of the OSMS were 3-6 frame/s with a sampling time interval of 0.16-0.33 seconds, and the frame rate of the fluoroscopy in this study was 15 frames/s.…”

Section: Discussionmentioning

confidence: 92%

Automatic prediction model for online diaphragm motion tracking based on optical surface monitoring by machine learning

Dai¹,

He²,

Zhu³

et al. 2023

Quant Imaging Med Surg

View full text Add to dashboard Cite

Background: The aim of this study was to establish a correlation model between external surface motion and internal diaphragm apex movement using machine learning and to realize online automatic prediction of the diaphragm motion trajectory based on optical surface monitoring. Methods:The optical body surface parameters and kilovoltage (kV) X-ray fluoroscopic images of 7 liver tumor patients were captured synchronously for 50 seconds. The location of the diaphragm apex was manually delineated by a radiation oncologist and automatically detected with a convolutional network model in fluoroscopic images. The correlation model between the body surface parameters and the diaphragm apex of each patient was developed through linear regression (LR) based on synchronous datasets before radiotherapy.Model 1 (M1) was trained with data from the first 30 seconds of the datasets and tested with data from the following 20 seconds of the datasets in the first fraction to evaluate the intra-fractional prediction accuracy.Model 2 (M2) was trained with data from the first 30 seconds of the datasets in the next fraction. The motion trajectory of the diaphragm apex during the following 20 seconds in the next fraction was predicted with M1 and M2, respectively, to evaluate the inter-fractional prediction accuracy. The prediction errors of the 2 models were compared to analyze whether the correlation model needed to be re-established. Results:The average mean absolute error (MAE) and root mean square error (RMSE) using M1 trained with automatic detection location for the first fraction were 3.12±0.80 and 3.82±0.98 mm in the superiorinferior (SI) direction and 1.38±0.24 and 1.74±0.32 mm in the anterior-posterior (AP) direction, respectively.The average MAE and RMSE of M1 versus M2 in the AP direction were 2.63±0.71 versus 1.28±0.48 mm and 3.26±0.90 versus 1.61±0.60 mm, respectively. The average MAE and RMSE of M1 versus M2 in the SI direction were 5.84±1.22 versus 3.37±0.43 mm and 7.22±1.45 versus 4.07±0.54 mm, respectively. The prediction accuracy of M2 was significantly higher than that of M1. Conclusions:This study shows that it is feasible to use optical body surface information to automatically predict the diaphragm motion trajectory. At the same time, it is necessary to establish a new correlation model for the current fraction before each treatment.

show abstract

“…The tumor and the fiducials were monitored with OBI, in real time at a minimum interval of 0.5 s. For lung tumors, EPID can visualize the tumor positions through the delivered beams. Update or rebuild of the 4D model is performed if needed [14,15]. Finally, log files are analyzed after the treatment to evaluate tracking errors [16].…”

Section: Dynamic Tumor Trackingmentioning

confidence: 99%

The gimbaled-head radiotherapy system: Rise and downfall of a dedicated system for dynamic tumor tracking with real-time monitoring and dynamic WaveArc

Hiraoka

Mizowaki

Nakamura

et al. 2020

Radiotherapy and Oncology

Self Cite

View full text Add to dashboard Cite

Impact of sampling interval in training data acquisition on intrafractional predictive accuracy of indirect dynamic tumor‐tracking radiotherapy

Cited by 7 publications

References 25 publications

Feasibility of predicting tumor motion using online data acquired during treatment and a generalized neural network optimized with offline patient tumor trajectories

Feasibility of predicting tumor motion using online data acquired during treatment and a generalized neural network optimized with offline patient tumor trajectories

Automatic prediction model for online diaphragm motion tracking based on optical surface monitoring by machine learning

The gimbaled-head radiotherapy system: Rise and downfall of a dedicated system for dynamic tumor tracking with real-time monitoring and dynamic WaveArc

Contact Info

Product

Resources

About