A deep-learning method using single phantom to enhance megavoltage image quality for patient positioning in chest radiotherapy: a feasibility study

A deep-learning method using single phantom to enhance megavoltage image quality for patient positioning in chest radiotherapy: a feasibility study

Image-guided radiation treatment (IGRT) is essential for verifying patient positioning during modern radiotherapy. Although megavoltage digital radiographs (MV-DR) are available on most therapeutic linear accelerators and can be used for checking treatment beam shapes, they are much inferior to kilo...

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Veröffentlicht in:Journal of the Korean Physical Society 2023-07, Vol.83 (1), p.72-80
Hauptverfasser: Jeon, Hosang, Kim, Dong Woon, Joo, Ji Hyeon, Ki, Yongkan, Kim, Wontaek, Park, Dahl, Nam, Jiho, Kim, Dong Hyeon
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Datasets
Deep learning
Digital imaging
Feasibility studies
Image acquisition
Image contrast
Image enhancement
Image quality
Linear accelerators
Mathematical and Computational Physics
Original Paper - Cross-Disciplinary Physics and Related Areas of Science and Technology
Particle and Nuclear Physics
Patient positioning
Physics
Physics and Astronomy
Radiation therapy
Radiographs
Similarity
Synthesis
Theoretical
Training
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container_end_page 80
container_issue 1
container_start_page 72
container_title Journal of the Korean Physical Society
container_volume 83
creator Jeon, Hosang
Kim, Dong Woon
Joo, Ji Hyeon
Ki, Yongkan
Kim, Wontaek
Park, Dahl
Nam, Jiho
Kim, Dong Hyeon
description Image-guided radiation treatment (IGRT) is essential for verifying patient positioning during modern radiotherapy. Although megavoltage digital radiographs (MV-DR) are available on most therapeutic linear accelerators and can be used for checking treatment beam shapes, they are much inferior to kilovoltage digital radiographs (KV-DR) in terms of image quality. As it is generally challenging to obtain a well-aligned MV − KV training dataset of patients in clinical scenarios, there is a lack of sufficient information on the accuracy of KV-DR synthesized using supervised training. Therefore, we aimed to synthesize pseudo KV-DR (pKV-DR) from MV-DR using a training dataset developed with a single anthropomorphic chest phantom. The phantom was adopted to obtain MV − KV image pairs at various gantry angles because these image pairs of patients are highly difficult to acquire and exactly align with each other. A deep-learning model based on U-net architecture was trained with the phantom image pairs using the mean absolute error (MAE) and structure similarity (SSIM) indices as loss functions. The mean MAEs of MV-DR and pKV-DR against KV-DR as the ground truth were 0.1152 and 0.0169, respectively, and their mean SSIM values were 0.9693 and 0.9942, respectively. Finally, pKV-DR showed a relatively high image similarity to that of KV-DR with smaller MAE (14.7%) and higher SSIM (2.5%), compared with MV-DR. The image contrast was also improved by 37.1% in clinical cases. The proposed method is expected to enable the implementation of improved IGRT with high image quality of KV-DR level, even in clinics where MV-DR is only available.
doi_str_mv 10.1007/s40042-023-00852-4
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subjects Datasets
Deep learning
Digital imaging
Feasibility studies
Image acquisition
Image contrast
Image enhancement
Image quality
Linear accelerators
Mathematical and Computational Physics
Original Paper - Cross-Disciplinary Physics and Related Areas of Science and Technology
Particle and Nuclear Physics
Patient positioning
Physics
Physics and Astronomy
Radiation therapy
Radiographs
Similarity
Synthesis
Theoretical
Training
title A deep-learning method using single phantom to enhance megavoltage image quality for patient positioning in chest radiotherapy: a feasibility study
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