Abstract
BackgroundSurface-guided radiation therapy can be used to continuously monitor a patient’s surface motions during radiotherapy by a non-irradiating, noninvasive optical surface imaging technique. In this study, machine learning methods were applied to predict external respiratory motion signals and predict internal liver motion in this therapeutic context.MethodsSeven groups of interrelated external/internal respiratory liver motion samples lasting from 5 to 6 min collected simultaneously were used as a dataset, Dv. Long short-term memory (LSTM) and support vector regression (SVR) networks were then used to establish external respiratory signal prediction models (LSTMpred/SVRpred) and external/internal respiratory motion correlation models (LSTMcorr/SVRcorr). These external prediction and external/internal correlation models were then combined into an integrated model. Finally, the LSTMcorr model was used to perform five groups of model updating experiments to confirm the necessity of continuously updating the external/internal correlation model. The root-mean-square error (RMSE), mean absolute error (MAE), and maximum absolute error (MAX_AE) were used to evaluate the performance of each model.ResultsThe models established using the LSTM neural network performed better than those established using the SVR network in the tasks of predicting external respiratory signals for latency-compensation (RMSE < 0.5 mm at a latency of 450 ms) and predicting internal liver motion using external signals (RMSE < 0.6 mm). The prediction errors of the integrated model (RMSE ≤ 1.0 mm) were slightly higher than those of the external prediction and external/internal correlation models. The RMSE/MAE of the fifth model update was approximately ten times smaller than that of the first model update.ConclusionsThe LSTM networks outperform SVR networks at predicting external respiratory signals and internal liver motion because of LSTM’s strong ability to deal with time-dependencies. The LSTM-based integrated model performs well at predicting liver motion from external respiratory signals with system latencies of up to 450 ms. It is necessary to update the external/internal correlation model continuously.
Highlights
During the radiotherapy of thoracic–abdominal tumors, respiratory motion can cause tumor displacement that affects the accuracy of radiotherapy [1]
Owing to its non-radiological and non-invasive nature, the indirect real-time tracking technique can be applied in the clinic using surfaceguided radiation therapy (SGRT)
In the template matching process, phase-only correlation (POC) [58] was performed followed by normalized cross-correlation (NCC) [59] with interpolation on the target volume to determine the point of optimal registration; details on this process can be found in [47]
Summary
During the radiotherapy of thoracic–abdominal tumors, respiratory motion can cause tumor displacement that affects the accuracy of radiotherapy [1]. Owing to its non-radiological and non-invasive nature, the indirect real-time tracking technique can be applied in the clinic using surfaceguided radiation therapy (SGRT) This technique has many advantages such as imaging without the requirement of dosing, real-time feedback, 3D sub-millimeter spatial resolution, non-invasive and non-contact application, ease of use, and an enhanced field of view (FOV) [20]. These advantages make SGRT well-suited to realtime tracking and respiratory gating, and many studies have reported applications of SGRT in the treatment of lung [21] and breast tumors [22], laryngeal cancer [23], etc. Machine learning methods were applied to predict external respiratory motion signals and predict internal liver motion in this therapeutic context
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
