4D VQ-GAN: synthesising medical scans at any time point for personalised disease progression modelling of idiopathic pulmonary fibrosis
4D VQ-GAN: synthesising medical scans at any time point for personalised disease progression modelling of idiopathic pulmonary fibrosis
Understanding the progression trajectories of diseases is crucial for early diagnosis and effective treatment planning. This is especially vital for life-threatening conditions such as Idiopathic Pulmonary Fibrosis (IPF), a chronic, progressive lung disease with a prognosis comparable to many cancers. Computed tomography (CT) imaging has been established as a reliable diagnostic tool for IPF. Accurately predicting future CT scans of early-stage IPF patients can aid in developing better treatment strategies, thereby improving survival outcomes. In this paper, we propose 4D Vector Quantised Generative Adversarial Networks (4D-VQ-GAN), a model capable of generating realistic CT volumes of IPF patients at any time point. The model is trained using a two-stage approach. In the first stage, a 3D-VQ-GAN is trained to reconstruct CT volumes. In the second stage, a Neural Ordinary Differential Equation (ODE) based temporal model is trained to capture the temporal dynamics of the quantised embeddings generated by the encoder in the first stage. We evaluate different configurations of our model for generating longitudinal CT scans and compare the results against ground truth data, both quantitatively and qualitatively. For validation, we conduct survival analysis using imaging biomarkers derived from generated CT scans and achieve a C-index comparable to that of biomarkers derived from the real CT scans. The survival analysis results demonstrate the potential clinical utility inherent to generated longitudinal CT scans, showing that they can reliably predict survival outcomes.
eess.IV, cs.AI, cs.CV, cs.LG
Zhao, An
ef4fafd7-56c5-4295-a5ac-fe3e27dd9196
Xu, Moucheng
91eaa8d2-beac-48f1-b475-3f92f398d887
Shahin, Ahmed H.
7a6e22f0-0fd3-4cf0-9c1b-04a077c1a2fd
Wuyts, Wim
10be264e-5be4-42f4-9e90-43fa6474f82a
Jones, Mark G.
a1264258-5fa5-4063-95e1-d7ff7c52a2de
Jacob, Joseph
b93a90c4-de81-4001-8f6f-bfd9f54a3d29
Alexander, Daniel C.
c637ee53-e5aa-49e2-b14a-91b1a3b4a576
8 February 2025
Zhao, An
ef4fafd7-56c5-4295-a5ac-fe3e27dd9196
Xu, Moucheng
91eaa8d2-beac-48f1-b475-3f92f398d887
Shahin, Ahmed H.
7a6e22f0-0fd3-4cf0-9c1b-04a077c1a2fd
Wuyts, Wim
10be264e-5be4-42f4-9e90-43fa6474f82a
Jones, Mark G.
a1264258-5fa5-4063-95e1-d7ff7c52a2de
Jacob, Joseph
b93a90c4-de81-4001-8f6f-bfd9f54a3d29
Alexander, Daniel C.
c637ee53-e5aa-49e2-b14a-91b1a3b4a576
[Unknown type: UNSPECIFIED]
Abstract
Understanding the progression trajectories of diseases is crucial for early diagnosis and effective treatment planning. This is especially vital for life-threatening conditions such as Idiopathic Pulmonary Fibrosis (IPF), a chronic, progressive lung disease with a prognosis comparable to many cancers. Computed tomography (CT) imaging has been established as a reliable diagnostic tool for IPF. Accurately predicting future CT scans of early-stage IPF patients can aid in developing better treatment strategies, thereby improving survival outcomes. In this paper, we propose 4D Vector Quantised Generative Adversarial Networks (4D-VQ-GAN), a model capable of generating realistic CT volumes of IPF patients at any time point. The model is trained using a two-stage approach. In the first stage, a 3D-VQ-GAN is trained to reconstruct CT volumes. In the second stage, a Neural Ordinary Differential Equation (ODE) based temporal model is trained to capture the temporal dynamics of the quantised embeddings generated by the encoder in the first stage. We evaluate different configurations of our model for generating longitudinal CT scans and compare the results against ground truth data, both quantitatively and qualitatively. For validation, we conduct survival analysis using imaging biomarkers derived from generated CT scans and achieve a C-index comparable to that of biomarkers derived from the real CT scans. The survival analysis results demonstrate the potential clinical utility inherent to generated longitudinal CT scans, showing that they can reliably predict survival outcomes.
Text
2502.05713v1
- Author's Original
More information
Published date: 8 February 2025
Additional Information:
4D image synthesis, VQ-GAN, neural ODEs, spatial temporal disease progression modelling, CT, IPF
Keywords:
eess.IV, cs.AI, cs.CV, cs.LG
Identifiers
Local EPrints ID: 510937
URI: http://eprints.soton.ac.uk/id/eprint/510937
PURE UUID: f0e26a7f-4672-44ba-bda2-b949dfb5628e
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Date deposited: 27 Apr 2026 16:45
Last modified: 27 Apr 2026 16:45
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Contributors
Author:
An Zhao
Author:
Moucheng Xu
Author:
Ahmed H. Shahin
Author:
Wim Wuyts
Author:
Mark G. Jones
Author:
Joseph Jacob
Author:
Daniel C. Alexander
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