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Open-Set Active Learning for Nucleus Detection From the Histopathological Images.

Jiao Tang, Yagao Yue, Wei Chu

    IEEE Transactions on Medical Imaging
    |October 6, 2025
    PubMed
    Summary
    This summary is machine-generated.

    This study introduces OpAL4ND, a novel active learning framework for nucleus detection in open-set environments. It efficiently reduces annotation burden while improving detection accuracy for histopathological examination.

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    Area of Science:

    • Computational pathology
    • Artificial intelligence in medicine
    • Deep learning for medical imaging

    Background:

    • Deep learning models for nucleus detection require extensive labeled data.
    • Active learning aims to reduce annotation efforts but struggles in open-set environments with unknown classes.
    • Nucleus detection in open-set environments using active learning is an underexplored area.

    Purpose of the Study:

    • To propose an effective active learning framework for nucleus detection in open-set environments.
    • To address the challenge of non-target samples from unknown classes in active learning.
    • To reduce the annotation burden for expert histopathologists.

    Main Methods:

    • A two-stage active learning framework, OpAL4ND, is proposed.
    • Stage 1: A prototype-based query strategy using an auxiliary detector selects pure candidate samples from known classes.
    • Stage 2: The target detector queries uncertain and representative samples from the candidate set.

    Main Results:

    • OpAL4ND improves the purity of selected samples from known classes.
    • The framework achieves higher nucleus detection accuracy compared to existing methods.
    • OpAL4ND significantly lowers the annotation burden required for training.

    Conclusions:

    • The proposed OpAL4ND framework effectively handles nucleus detection in open-set environments.
    • This method enhances the efficiency and accuracy of histopathological examination through reduced annotation.
    • OpAL4ND offers a promising solution for applying active learning in challenging medical imaging scenarios.