English

Towards Computation- and Communication-efficient Computational Pathology

Image and Video Processing 2025-06-04 v2 Computer Vision and Pattern Recognition

Abstract

Despite the impressive performance across a wide range of applications, current computational pathology models face significant diagnostic efficiency challenges due to their reliance on high-magnification whole-slide image analysis. This limitation severely compromises their clinical utility, especially in time-sensitive diagnostic scenarios and situations requiring efficient data transfer. To address these issues, we present a novel computation- and communication-efficient framework called Magnification-Aligned Global-Local Transformer (MAG-GLTrans). Our approach significantly reduces computational time, file transfer requirements, and storage overhead by enabling effective analysis using low-magnification inputs rather than high-magnification ones. The key innovation lies in our proposed magnification alignment (MAG) mechanism, which employs self-supervised learning to bridge the information gap between low and high magnification levels by effectively aligning their feature representations. Through extensive evaluation across various fundamental CPath tasks, MAG-GLTrans demonstrates state-of-the-art classification performance while achieving remarkable efficiency gains: up to 10.7 times reduction in computational time and over 20 times reduction in file transfer and storage requirements. Furthermore, we highlight the versatility of our MAG framework through two significant extensions: (1) its applicability as a feature extractor to enhance the efficiency of any CPath architecture, and (2) its compatibility with existing foundation models and histopathology-specific encoders, enabling them to process low-magnification inputs with minimal information loss. These advancements position MAG-GLTrans as a particularly promising solution for time-sensitive applications, especially in the context of intraoperative frozen section diagnosis where both accuracy and efficiency are paramount.

Keywords

Cite

@article{arxiv.2504.02628,
  title  = {Towards Computation- and Communication-efficient Computational Pathology},
  author = {Chu Han and Bingchao Zhao and Jiatai Lin and Shanshan Lyu and Longfei Wang and Tianpeng Deng and Cheng Lu and Changhong Liang and Hannah Y. Wen and Xiaojing Guo and Zhenwei Shi and Zaiyi Liu},
  journal= {arXiv preprint arXiv:2504.02628},
  year   = {2025}
}
R2 v1 2026-06-28T22:45:23.155Z