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Main Authors: Sun, Rui, Yang, Yiwen, Guo, Kaiyu, Jiang, Chen, Xu, Dongli, Liu, Zhaonan, Pan, Tan, Han, Limei, Jiang, Xue, Wei, Wu, Cheng, Yuan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.05420
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author Sun, Rui
Yang, Yiwen
Guo, Kaiyu
Jiang, Chen
Xu, Dongli
Liu, Zhaonan
Pan, Tan
Han, Limei
Jiang, Xue
Wei, Wu
Cheng, Yuan
author_facet Sun, Rui
Yang, Yiwen
Guo, Kaiyu
Jiang, Chen
Xu, Dongli
Liu, Zhaonan
Pan, Tan
Han, Limei
Jiang, Xue
Wei, Wu
Cheng, Yuan
contents Accurate cell instance segmentation is foundational for digital pathology analysis. Existing methods based on contour detection and distance mapping still face significant challenges in processing complex and dense cellular regions. Graph coloring-based methods provide a new paradigm for this task, yet the effectiveness of this paradigm in real-world scenarios with dense overlaps and complex topologies has not been verified. Addressing this issue, we release a large-scale dataset GBC-FS 2025, which contains highly complex and dense sub-cellular nuclear arrangements. We conduct the first systematic analysis of the chromatic properties of cell adjacency graphs across four diverse datasets and reveal an important discovery: most real-world cell graphs are non-bipartite, with a high prevalence of odd-length cycles (predominantly triangles). This makes simple 2-coloring theory insufficient for handling complex tissues, while higher-chromaticity models would cause representational redundancy and optimization difficulties. Building on this observation of complex real-world contexts, we propose Disco (Densely-overlapping Cell Instance Segmentation via Adjacency-aware COllaborative Coloring), an adjacency-aware framework based on the "divide and conquer" principle. It uniquely combines a data-driven topological labeling strategy with a constrained deep learning system to resolve complex adjacency conflicts. First, "Explicit Marking" strategy transforms the topological challenge into a learnable classification task by recursively decomposing the cell graph and isolating a "conflict set." Second, "Implicit Disambiguation" mechanism resolves ambiguities in conflict regions by enforcing feature dissimilarity between different instances, enabling the model to learn separable feature representations.
format Preprint
id arxiv_https___arxiv_org_abs_2602_05420
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Disco: Densely-overlapping Cell Instance Segmentation via Adjacency-aware Collaborative Coloring
Sun, Rui
Yang, Yiwen
Guo, Kaiyu
Jiang, Chen
Xu, Dongli
Liu, Zhaonan
Pan, Tan
Han, Limei
Jiang, Xue
Wei, Wu
Cheng, Yuan
Computer Vision and Pattern Recognition
Artificial Intelligence
Accurate cell instance segmentation is foundational for digital pathology analysis. Existing methods based on contour detection and distance mapping still face significant challenges in processing complex and dense cellular regions. Graph coloring-based methods provide a new paradigm for this task, yet the effectiveness of this paradigm in real-world scenarios with dense overlaps and complex topologies has not been verified. Addressing this issue, we release a large-scale dataset GBC-FS 2025, which contains highly complex and dense sub-cellular nuclear arrangements. We conduct the first systematic analysis of the chromatic properties of cell adjacency graphs across four diverse datasets and reveal an important discovery: most real-world cell graphs are non-bipartite, with a high prevalence of odd-length cycles (predominantly triangles). This makes simple 2-coloring theory insufficient for handling complex tissues, while higher-chromaticity models would cause representational redundancy and optimization difficulties. Building on this observation of complex real-world contexts, we propose Disco (Densely-overlapping Cell Instance Segmentation via Adjacency-aware COllaborative Coloring), an adjacency-aware framework based on the "divide and conquer" principle. It uniquely combines a data-driven topological labeling strategy with a constrained deep learning system to resolve complex adjacency conflicts. First, "Explicit Marking" strategy transforms the topological challenge into a learnable classification task by recursively decomposing the cell graph and isolating a "conflict set." Second, "Implicit Disambiguation" mechanism resolves ambiguities in conflict regions by enforcing feature dissimilarity between different instances, enabling the model to learn separable feature representations.
title Disco: Densely-overlapping Cell Instance Segmentation via Adjacency-aware Collaborative Coloring
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2602.05420