Tumor movements should be accurately predicted to improve delivery accuracy and reduce unnecessary radiation exposure to healthy tissue during radiotherapy. The tumor movements pertaining to respiration are divided into intra-fractional variation occurring in a single treatment session and inter-fractional variation arising between different sessions. Most studies of patients’ respiration movements deal with intra-fractional variation. Previous studies on inter-fractional variation are hardly mathematized and cannot predict movements well due to inconstant variation. Moreover, the computation time of the prediction should be reduced. To overcome these limitations, we propose a new predictor for intra- and inter-fractional data variation, called intra- and inter-fraction fuzzy deep learning (IIFDL), where FDL, equipped with breathing clustering, predicts the movement accurately and decreases the computation time. Through the experimental results, we validated that the IIFDL improved root-mean-square error (RMSE) by 29.98% and prediction overshoot by 70.93%, compared with existing methods. The results also showed that the IIFDL enhanced the average RMSE and overshoot by 59.73% and 83.27%, respectively. In addition, the average computation time of IIFDL was 1.54 ms for both intra- and inter-fractional variation, which was much smaller than the existing methods. Therefore, the proposed IIFDL might achieve real-time estimation as well as better tracking techniques in radiotherapy.
Purpose
Respiratory motion prediction using an artificial neural network
(ANN) was integrated with pseudocontinuous arterial spin labeling (pCASL)
MRI to allow free-breathing perfusion measurements in the kidney. In this
study, we evaluated the performance of the ANN to accurately predict the
location of the kidneys during image acquisition.
Methods
A pencil-beam navigator was integrated with a pCASL sequence to
measure lung/diaphragm motion during ANN training and the pCASL transit
delay. The ANN algorithm ran concurrently in the background to predict organ
location during the 0.7 s 15-slice acquisition based on the navigator data.
The predictions were supplied to the pulse sequence to prospectively adjust
the axial slice acquisition to match the predicted organ location.
Additional navigators were acquired immediately after the multislice
acquisition to assess the performance and accuracy of the ANN. The technique
was tested in eight healthy volunteers.
Results
The root mean square error (RMSE) and mean absolute error (MAE) for
the eight volunteers were 1.91 ± 0.17 mm and 1.43 ± 0.17 mm,
respectively, for the ANN. The RMSE increased with transit delay. The MAE
typically increased from the first to last prediction in the image
acquisition. The overshoot was 23.58% ± 3.05% using
the target prediction accuracy of ± 1 mm.
Conclusion
Respiratory motion prediction with prospective motion correction was
successfully demonstrated for free-breathing perfusion MRI of the kidney.
The method serves as an alternative to multiple breathholds and requires
minimal effort from the patient.
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