Improved outcome models with denoising diffusion

•DDPM generating treatment planning data was developed and verified (FID  10 %.•Other techniques for imbalanced training improved performance by less than 4%.•DDPM model can diminish the negative effect of event imbalance in outcome models.•Introduced approach can help in clinical translation of rad...

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Bibliographic Details
Published in:Physica medica 2024-03, Vol.119, p.103307-103307, Article 103307
Main Authors: Dudas, D., Dilling, T.J., El Naqa, I.
Format: Article
Language:English
Subjects:
Class imbalance Deep Learning
Denoising Diffusion Probabilistic Models
Lung cancer
Outcome modelling
Radiotherapy
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Summary:•DDPM generating treatment planning data was developed and verified (FID  10 %.•Other techniques for imbalanced training improved performance by less than 4%.•DDPM model can diminish the negative effect of event imbalance in outcome models.•Introduced approach can help in clinical translation of radiotherapy outcome models. Radiotherapy outcome modelling often suffers from class imbalance in the modelled endpoints. One of the main options to address this issue is by introducing new synthetically generated datapoints, using generative models, such as Denoising Diffusion Probabilistic Models (DDPM). In this study, we implemented DDPM to improve performance of a tumor local control model, trained on imbalanced dataset, and compare this approach with other common techniques. A dataset of 535 NSCLC patients treated with SBRT (50 Gy/5 fractions) was used to train a deep learning outcome model for tumor local control prediction. The dataset included complete treatment planning data (planning CT images, 3D planning dose distribution and patient demographics) with sparsely distributed endpoints (6–7 % experiencing local failure). Consequently, we trained a novel conditional 3D DDPM model to generate synthetic treatment planning data. Synthetically generated treatment planning datapoints were used to supplement the real training dataset and the improvement in the model’s performance was studied. Obtained results were also compared to other common techniques for class imbalanced training, such as Oversampling, Undersampling, Augmentation, Class Weights, SMOTE and ADASYN. Synthetic DDPM-generated data were visually trustworthy, with Fréchet inception distance (FID) below 50. Extending the training dataset with the synthetic data improved the model’s performance by more than 10%, while other techniques exhibited only about 4% improvement. DDPM introduces a novel approach to class-imbalanced outcome modelling problems. The model generates realistic synthetic radiotherapy planning data, with a strong potential to increase performance and robustness of outcome models.
ISSN:1120-1797
1724-191X
DOI:10.1016/j.ejmp.2024.103307