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Integrating augmentation-aware manifold smoothing and momentum-adjusted loss for handling class imbalance in thoracic disease detection.

June 17, 2026pubmed logopapers

Authors

H R S,B A

Affiliations (2)

  • Department of Information Science and Engineering, Nitte Meenakshi Institute of Technology (NMIT), Nitte (Deemed to be University), Bangalore, India.
  • Depatment of Computer Science and Engineering, National Institute of Technology Karnataka (NITK), Surathkal, India.

Abstract

Class imbalance is a fundamental challenge in medical image analysis, where certain disease categories occur far less frequently than others. This uneven data distribution often causes learning algorithms to favor common conditions while underperforming on rare but clinically significant cases. In chest X-ray analysis, the deployment of artificial intelligence is particularly hindered by the long-tailed distribution of thoracic diseases, as conventional deep learning models exhibit optimization bias toward majority classes, leading to reduced sensitivity for rare yet critical pathologies. To address this challenge, this paper presents Dynamic Adaptive Weighting with Hybrid Networks (DAWN-Net), a unified framework that synergizes data-level and algorithm-level interventions. Unlike conventional approaches that treat augmentation and re-weighting in isolation, DAWN-Net introduces a Hybrid Synergy mechanism. At the data level, we propose <i>Augmentation-Aware Manifold Smoothing</i>, which generates synthetic variations in the local tangent space of minority samples to densify their feature representation. Architecturally, the model employs a dual-stream design comprising a <i>Hierarchical Feature Propagation Network (HFPN)</i> to capture high-frequency local textural details, and a <i>Semantic Context Modeling Network (SCMN)</i> to enforce global anatomical consistency. These components are jointly optimized using a novel <i>Momentum-Adjusted Gradient Harmonization</i> loss, which dynamically recalibrates gradient contributions based on batch-wise class statistics and augmentation intensity. Validation on three large-scale benchmarks-NIH ChestXray14, CheXpert, and PadChest-demonstrates that DAWN-Net consistently outperforms state-of-the-art baselines, particularly in the detection of rare diseases such as Hernia and Fibrosis. By mitigating the optimization bias and improving sensitivity for rare yet critical pathologies, DAWN-Net overcomes the limitations of conventional deep learning models, thereby offering a more reliable solution for safety-critical radiological diagnosis.

Topics

Journal Article

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