The paper presents a novel framework that combines self-supervised learning (SSL) techniques with neural ordinary differential equations (NODEs) to address the task of predicting disease progression, particularly for diabetic retinopathy. The key contributions are:
The authors first provide a brief overview of two important SSL frameworks, SimCLR and BYOL, and then describe how they adapt these frameworks to incorporate NODEs for disease progression modeling. Specifically, they introduce a "time-aware head" based on NODEs and define three novel similarity criteria (temporal evolution, temporal consistency, and disease progression alignment) to guide the learning process.
The proposed framework is evaluated on the OPHDIAT dataset of fundus photographs, demonstrating significant performance improvements in predicting diabetic retinopathy progression compared to traditional methods. The authors show that pre-training the NODE layer with their SSL-inspired approaches leads to more accurate and stable models for disease progression tasks.
Furthermore, the authors conduct an ablation study to examine the impact of different configurations for the temporal augmentation schemes, highlighting the importance of aligning the augmentation with the disease progression dynamics. The results suggest that the proposed framework can effectively leverage the strengths of continuous-time models, allowing for more flexible handling of variable progression times within the training data.
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