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Auteurs principaux: Huang, Zuqi, Tian, Mengxin, Liu, Huan, Li, Wentao, Liang, Baobao, Wu, Jie, Yan, Fang, Tang, Zhaoqing, Li, Zhongyu
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2511.12588
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author Huang, Zuqi
Tian, Mengxin
Liu, Huan
Li, Wentao
Liang, Baobao
Wu, Jie
Yan, Fang
Tang, Zhaoqing
Li, Zhongyu
author_facet Huang, Zuqi
Tian, Mengxin
Liu, Huan
Li, Wentao
Liang, Baobao
Wu, Jie
Yan, Fang
Tang, Zhaoqing
Li, Zhongyu
contents Accurate cell counting in immunohistochemistry (IHC) images is critical for quantifying protein expression and aiding cancer diagnosis. However, the task remains challenging due to the chromogen overlap, variable biomarker staining, and diverse cellular morphologies. Regression-based counting methods offer advantages over detection-based ones in handling overlapped cells, yet rarely support end-to-end multi-class counting. Moreover, the potential of foundation models remains largely underexplored in this paradigm. To address these limitations, we propose a rank-aware agglomeration framework that selectively distills knowledge from multiple strong foundation models, leveraging their complementary representations to handle IHC heterogeneity and obtain a compact yet effective student model, CountIHC. Unlike prior task-agnostic agglomeration strategies that either treat all teachers equally or rely on feature similarity, we design a Rank-Aware Teacher Selecting (RATS) strategy that models global-to-local patch rankings to assess each teacher's inherent counting capacity and enable sample-wise teacher selection. For multi-class cell counting, we introduce a fine-tuning stage that reformulates the task as vision-language alignment. Discrete semantic anchors derived from structured text prompts encode both category and quantity information, guiding the regression of class-specific density maps and improving counting for overlapping cells. Extensive experiments demonstrate that CountIHC surpasses state-of-the-art methods across 12 IHC biomarkers and 5 tissue types, while exhibiting high agreement with pathologists' assessments. Its effectiveness on H&E-stained data further confirms the scalability of the proposed method.
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publishDate 2025
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spellingShingle Rank-Aware Agglomeration of Foundation Models for Immunohistochemistry Image Cell Counting
Huang, Zuqi
Tian, Mengxin
Liu, Huan
Li, Wentao
Liang, Baobao
Wu, Jie
Yan, Fang
Tang, Zhaoqing
Li, Zhongyu
Computer Vision and Pattern Recognition
Accurate cell counting in immunohistochemistry (IHC) images is critical for quantifying protein expression and aiding cancer diagnosis. However, the task remains challenging due to the chromogen overlap, variable biomarker staining, and diverse cellular morphologies. Regression-based counting methods offer advantages over detection-based ones in handling overlapped cells, yet rarely support end-to-end multi-class counting. Moreover, the potential of foundation models remains largely underexplored in this paradigm. To address these limitations, we propose a rank-aware agglomeration framework that selectively distills knowledge from multiple strong foundation models, leveraging their complementary representations to handle IHC heterogeneity and obtain a compact yet effective student model, CountIHC. Unlike prior task-agnostic agglomeration strategies that either treat all teachers equally or rely on feature similarity, we design a Rank-Aware Teacher Selecting (RATS) strategy that models global-to-local patch rankings to assess each teacher's inherent counting capacity and enable sample-wise teacher selection. For multi-class cell counting, we introduce a fine-tuning stage that reformulates the task as vision-language alignment. Discrete semantic anchors derived from structured text prompts encode both category and quantity information, guiding the regression of class-specific density maps and improving counting for overlapping cells. Extensive experiments demonstrate that CountIHC surpasses state-of-the-art methods across 12 IHC biomarkers and 5 tissue types, while exhibiting high agreement with pathologists' assessments. Its effectiveness on H&E-stained data further confirms the scalability of the proposed method.
title Rank-Aware Agglomeration of Foundation Models for Immunohistochemistry Image Cell Counting
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2511.12588