Abstract

PurposeThe purpose of this study is to propose algorithms and methods for achieving high accuracy in tracking and interception irradiation technology for tumors that move by respiration using MR-linac (MRIdian®, ViewRay Inc.) and to use deep learning to predict the movement of moving tumors in real time during radiation therapy and reconstruct cine magnetic resonance imaging (cine-MRI) into four-dimensional (4D) movies.MethodsIn this study, we propose a reconstruction algorithm using 4DCT for treatment planning taken before irradiation as training data in consideration of the actual treatment flow. In the algorithm, two neural networks made before treatment are used to reconstruct 4D movies that predict tumor movement in real time during treatment. Cycle GAN (generative adversarial network) was used to convert MR images to CT images, and long short-term memory was used to convert cine-MRI to 4D movies and predict tumor movement.ResultsWe succeeded in predicting the time including the imaging time of the MR images, the lag until irradiation, and the calculation time in the algorithm. In addition, the conversion and prediction results at each phase of reconstruction were generally good so that they could be clinically applied.ConclusionsThe reconstruction algorithm proposed in this study enables high-precision radiotherapy while predicting the volume information of the tumor and the actual tumor position, which could not be obtained during radiotherapy.

Highlights

  • Research backgroundIn recent years, image-guided technology has been used as a standard position matching method in highprecision radiotherapy, and the results of radiotherapy have improved

  • We succeeded in predicting the time including the imaging time of the MR images, the lag until irradiation, and the calculation time in the algorithm

  • The reconstruction algorithm proposed in this study enables high-precision radiotherapy while predicting the volume information of the tumor and the actual tumor position, which could not be obtained during radiotherapy

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Summary

Introduction

Research backgroundIn recent years, image-guided technology has been used as a standard position matching method in highprecision radiotherapy, and the results of radiotherapy have improved. Image-guided radiotherapy (IGRT) has been mainly performed by cone-beam computed tomography (CBCT) or electronic portal image detector (EPID) installed in radiotherapy equipment [1,2]. While CBCT can directly and accurately visualize tumors in three dimensions with a tomographic image, EPID is characterized by being able to be observed in real time during irradiation by fluoroscopy. IGRT technology, which combines the advantages of both "direct 3D tumor visualization" and "real-time observation", was first put to practical use by MRI-linac (MRIdian®, ViewRay Inc., Oakwood Village, OH) equipped with an MR image guided device [3-5]. Real-time observation of tumors is very effective for radiation therapy for lung cancer, which moves significantly with breathing. The purpose of this study is to realize high-precision radiotherapy for moving tumors by MRIdian

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