| Title: | Diff-Def: Diffusion-Generated Deformation Fields for Conditional Atlases |
| Journal: | IEEE Transactions on Medical Imaging |
| Published: | 4 Aug 2025 |
| Pubmed: | https://pubmed.ncbi.nlm.nih.gov/40758495/ |
| DOI: | https://doi.org/10.1109/tmi.2025.3595421 |
Publication 17771
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Abstract
Anatomical atlases are widely used for population studies and analysis. Conditional atlases target a specific sub-population defined via certain conditions, such as demographics or pathologies, and allow for the investigation of fine-grained anatomical differences like morphological changes associated with ageing or disease. Existing approaches use either registration-based methods that are often unable to handle large anatomical variations or generative adversarial models, which are challenging to train since they can suffer from training instabilities. Instead of generating atlases directly in as intensities, we propose using latent diffusion models to generate deformation fields, which transform a general population atlas into one representing a specific sub-population. Our approach ensures structural integrity, enhances interpretability and avoids hallucinations that may arise during direct image synthesis by generating this deformation field and regularising it using a neighbourhood of images. We compare our method to several state-of-the-art atlas generation methods using brain MR images from the UK Biobank. Our method generates highly realistic atlases with smooth transformations and high anatomical fidelity, outperforming existing baselines. We demonstrate the quality of these atlases through comprehensive evaluations, including quantitative metrics for anatomical accuracy, perceptual similarity, and qualitative analyses displaying the consistency and realism of the generated atlases.</p>
6 Authors
- Sophie Starck
- Vasiliki Sideri-Lampretsa
- Bernhard Kainz
- Martin J. Menten
- Tamara T. Mueller
- Daniel Rueckert
1 Application
| Application ID | Title |
|---|---|
| 87802 | Assessment of frailty and biological age using multi-modal deep learning |
Enabling scientific discoveries that improve human health