In-hoc Concept Representations to Regularise Deep Learning in Medical Imaging

Publication date

2025

Authors

Corbetta, ValentinaISNI 0000000518030731
Dijkstra, Floris Six
Beets-Tan, Regina
Kervadec, Hoel
Wickstrøm, Kristoffer
Silva, WilsonORCID 0000-0002-4080-9328ISNI 0000000518163972

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Supervisors

DOI

Document Type

Part of book
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License

cc_by

Abstract

Deep learning models in medical imaging often achieve strong in-distribution performance but struggle to generalise under distribution shifts, frequently relying on spurious correlations instead of clinically meaningful features. We introduce LCRReg, a novel regularisation approach that leverages Latent Concept Representations (LCRs) (e.g., Concept Activation Vectors (CAVs)) to guide models toward semantically grounded representations. LCRReg requires no concept labels in the main training set and instead uses a small auxiliary dataset to synthesise high-quality, disentangled concept examples. We extract LCRs for predefined relevant features, and incorporate a regularisation term that guides a Convolutional Neural Network (CNN) to activate within latent subspaces associated with those concepts. We evaluate LCRReg across synthetic and real-world medical tasks. On a controlled toy dataset, it significantly improves robustness to injected spurious correlations and remains effective even in multi-concept and multiclass settings. On the diabetic retinopathy binary classification task, LCRReg enhances performance under both synthetic spurious perturbations and out-of-distribution (OOD) generalisation. Compared to baselines, including multitask learning, linear probing, and post-hoc concept-based models, LCRReg offers a lightweight, architecture-agnostic strategy for improving model robustness without requiring dense concept supervision.

Keywords

SDG 3 - Good Health and Well-being

Citation

Corbetta, V, Dijkstra, F S, Beets-Tan, R, Kervadec, H, Wickstrøm, K & Silva, W 2025, In-hoc Concept Representations to Regularise Deep Learning in Medical Imaging. in Proceedings of the IEEE/CVF International Conference on Computer Vision. IEEE, pp. 7312-7321.