Weakly-supervised positional contrastive learning: application to cirrhosis classification
This work addresses the problem of limited access to high-confidence labels in medical imaging for researchers and clinicians, though it is incremental as it builds on existing contrastive learning methods.
The paper tackles the challenge of leveraging weakly-labeled medical imaging data for cirrhosis classification by proposing a weakly-supervised positional contrastive learning strategy that integrates spatial context and weak labels, resulting in a 5% AUC improvement on an internal dataset and a 26% improvement on a public dataset.
Large medical imaging datasets can be cheaply and quickly annotated with low-confidence, weak labels (e.g., radiological scores). Access to high-confidence labels, such as histology-based diagnoses, is rare and costly. Pretraining strategies, like contrastive learning (CL) methods, can leverage unlabeled or weakly-annotated datasets. These methods typically require large batch sizes, which poses a difficulty in the case of large 3D images at full resolution, due to limited GPU memory. Nevertheless, volumetric positional information about the spatial context of each 2D slice can be very important for some medical applications. In this work, we propose an efficient weakly-supervised positional (WSP) contrastive learning strategy where we integrate both the spatial context of each 2D slice and a weak label via a generic kernel-based loss function. We illustrate our method on cirrhosis prediction using a large volume of weakly-labeled images, namely radiological low-confidence annotations, and small strongly-labeled (i.e., high-confidence) datasets. The proposed model improves the classification AUC by 5% with respect to a baseline model on our internal dataset, and by 26% on the public LIHC dataset from the Cancer Genome Atlas. The code is available at: https://github.com/Guerbet-AI/wsp-contrastive.