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Autori principali: Wijesinghe, Isuru, Nix, Michael, Zakeri, Arezoo, Hokmabadi, Alireza, Al-Qaisieh, Bashar, Gooya, Ali, Taylor, Zeike A.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2407.06692
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author Wijesinghe, Isuru
Nix, Michael
Zakeri, Arezoo
Hokmabadi, Alireza
Al-Qaisieh, Bashar
Gooya, Ali
Taylor, Zeike A.
author_facet Wijesinghe, Isuru
Nix, Michael
Zakeri, Arezoo
Hokmabadi, Alireza
Al-Qaisieh, Bashar
Gooya, Ali
Taylor, Zeike A.
contents We propose Deep-Motion-Net: an end-to-end graph neural network (GNN) architecture that enables 3D (volumetric) organ shape reconstruction from a single in-treatment kV planar X-ray image acquired at any arbitrary projection angle. Estimating and compensating for true anatomical motion during radiotherapy is essential for improving the delivery of planned radiation dose to target volumes while sparing organs-at-risk, and thereby improving the therapeutic ratio. Achieving this using only limited imaging available during irradiation and without the use of surrogate signals or invasive fiducial markers is attractive. The proposed model learns the mesh regression from a patient-specific template and deep features extracted from kV images at arbitrary projection angles. A 2D-CNN encoder extracts image features, and four feature pooling networks fuse these features to the 3D template organ mesh. A ResNet-based graph attention network then deforms the feature-encoded mesh. The model is trained using synthetically generated organ motion instances and corresponding kV images. The latter is generated by deforming a reference CT volume aligned with the template mesh, creating digitally reconstructed radiographs (DRRs) at required projection angles, and DRR-to-kV style transferring with a conditional CycleGAN model. The overall framework was tested quantitatively on synthetic respiratory motion scenarios and qualitatively on in-treatment images acquired over full scan series for liver cancer patients. Overall mean prediction errors for synthetic motion test datasets were 0.16$\pm$0.13 mm, 0.18$\pm$0.19 mm, 0.22$\pm$0.34 mm, and 0.12$\pm$0.11 mm. Mean peak prediction errors were 1.39 mm, 1.99 mm, 3.29 mm, and 1.16 mm.
format Preprint
id arxiv_https___arxiv_org_abs_2407_06692
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Deep-Motion-Net: GNN-based volumetric organ shape reconstruction from single-view 2D projections
Wijesinghe, Isuru
Nix, Michael
Zakeri, Arezoo
Hokmabadi, Alireza
Al-Qaisieh, Bashar
Gooya, Ali
Taylor, Zeike A.
Computer Vision and Pattern Recognition
Artificial Intelligence
We propose Deep-Motion-Net: an end-to-end graph neural network (GNN) architecture that enables 3D (volumetric) organ shape reconstruction from a single in-treatment kV planar X-ray image acquired at any arbitrary projection angle. Estimating and compensating for true anatomical motion during radiotherapy is essential for improving the delivery of planned radiation dose to target volumes while sparing organs-at-risk, and thereby improving the therapeutic ratio. Achieving this using only limited imaging available during irradiation and without the use of surrogate signals or invasive fiducial markers is attractive. The proposed model learns the mesh regression from a patient-specific template and deep features extracted from kV images at arbitrary projection angles. A 2D-CNN encoder extracts image features, and four feature pooling networks fuse these features to the 3D template organ mesh. A ResNet-based graph attention network then deforms the feature-encoded mesh. The model is trained using synthetically generated organ motion instances and corresponding kV images. The latter is generated by deforming a reference CT volume aligned with the template mesh, creating digitally reconstructed radiographs (DRRs) at required projection angles, and DRR-to-kV style transferring with a conditional CycleGAN model. The overall framework was tested quantitatively on synthetic respiratory motion scenarios and qualitatively on in-treatment images acquired over full scan series for liver cancer patients. Overall mean prediction errors for synthetic motion test datasets were 0.16$\pm$0.13 mm, 0.18$\pm$0.19 mm, 0.22$\pm$0.34 mm, and 0.12$\pm$0.11 mm. Mean peak prediction errors were 1.39 mm, 1.99 mm, 3.29 mm, and 1.16 mm.
title Deep-Motion-Net: GNN-based volumetric organ shape reconstruction from single-view 2D projections
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2407.06692