MSA-DCNN: A Data-Efficient Multi-Scale Deformable CNN for Medical Image Classification

📅 2026-07-07
📈 Citations: 0
Influential: 0
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🤖 AI Summary
This work addresses the challenges of multi-scale morphological variations and scarce annotated data in medical image classification, where existing methods struggle to simultaneously achieve adaptive sampling, effective multi-scale fusion, and label-efficient learning. We propose the MSA-DCNN framework, which uniquely integrates deformable convolutions with a multi-scale attention mechanism within a unified optimization paradigm. This integration enables adaptive multi-scale sampling, intra-scale saliency refinement, cross-scale feature fusion, and auxiliary self-distillation regularization. Evaluated on multiple public medical imaging benchmarks and an external leukemia test set, MSA-DCNN achieves significantly superior performance over Vision Transformers, conventional CNNs, and MICCAI semi-supervised baselines—using fewer parameters—while demonstrating exceptional generalization and data efficiency under distribution shifts and limited labeling scenarios.
📝 Abstract
Existing deep learning methods perform well in medical image classification but struggle with multi-scale morphology and limited annotations due to fixed sampling and data-hungry training. Existing approaches address these challenges in isolation: DCN-based models provide adaptive sampling but lack explicit multi-scale attention fusion and label-efficient regularisation; multi-scale architectures typically rely on static fusion; and semi-supervised methods target label scarcity without jointly modelling adaptive cross-scale representations. We propose MSA-DCNN, a scale-consistent deformable attention learning framework that introduces adaptive multi-scale sampling, within-scale saliency refinement, learned cross-scale fusion, and auxiliary self-distillation within a unified optimisation scheme, with potential to generalise to structurally heterogeneous anatomy. We evaluate on three public benchmarks and an external hold-out set for leukaemia. MSA-DCNN demonstrates competitive and often better performance against ViT baselines, CNN baselines, and a MICCAI semi-supervised baseline under distribution shift and label scarcity in accuracy, F1, and AUC (binary), while using fewer parameters. Ablations confirm complementary component contributions, supporting MSA-DCNN as a practical foundation for data-efficient medical image classification.
Problem

Research questions and friction points this paper is trying to address.

multi-scale morphology
limited annotations
medical image classification
data efficiency
adaptive sampling
Innovation

Methods, ideas, or system contributions that make the work stand out.

multi-scale deformable CNN
adaptive sampling
cross-scale fusion
self-distillation
data-efficient learning
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