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Autores principales: Yu, Qinkai, Zhang, Chong, Jin, Gaojie, Huang, Tianjin, Zhou, Wei, Li, Wenhui, Jin, Xiaobo, Huang, Bo, Zhao, Yitian, Yang, Guang, Lip, Gregory Y. H., Zheng, Yalin, Villavicencio, Aline, Meng, Yanda
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2601.17107
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author Yu, Qinkai
Zhang, Chong
Jin, Gaojie
Huang, Tianjin
Zhou, Wei
Li, Wenhui
Jin, Xiaobo
Huang, Bo
Zhao, Yitian
Yang, Guang
Lip, Gregory Y. H.
Zheng, Yalin
Villavicencio, Aline
Meng, Yanda
author_facet Yu, Qinkai
Zhang, Chong
Jin, Gaojie
Huang, Tianjin
Zhou, Wei
Li, Wenhui
Jin, Xiaobo
Huang, Bo
Zhao, Yitian
Yang, Guang
Lip, Gregory Y. H.
Zheng, Yalin
Villavicencio, Aline
Meng, Yanda
contents Annotating medical data for training AI models is often costly and limited due to the shortage of specialists with relevant clinical expertise. This challenge is further compounded by privacy and ethical concerns associated with sensitive patient information. As a result, well-trained medical segmentation models on private datasets constitute valuable intellectual property requiring robust protection mechanisms. Existing model protection techniques primarily focus on classification and generative tasks, while segmentation models-crucial to medical image analysis-remain largely underexplored. In this paper, we propose a novel, stealthy, and harmless method, StealthMark, for verifying the ownership of medical segmentation models under black-box conditions. Our approach subtly modulates model uncertainty without altering the final segmentation outputs, thereby preserving the model's performance. To enable ownership verification, we incorporate model-agnostic explanation methods, e.g. LIME, to extract feature attributions from the model outputs. Under specific triggering conditions, these explanations reveal a distinct and verifiable watermark. We further design the watermark as a QR code to facilitate robust and recognizable ownership claims. We conducted extensive experiments across four medical imaging datasets and five mainstream segmentation models. The results demonstrate the effectiveness, stealthiness, and harmlessness of our method on the original model's segmentation performance. For example, when applied to the SAM model, StealthMark consistently achieved ASR above 95% across various datasets while maintaining less than a 1% drop in Dice and AUC scores, significantly outperforming backdoor-based watermarking methods and highlighting its strong potential for practical deployment. Our implementation code is made available at: https://github.com/Qinkaiyu/StealthMark.
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spellingShingle StealthMark: Harmless and Stealthy Ownership Verification for Medical Segmentation via Uncertainty-Guided Backdoors
Yu, Qinkai
Zhang, Chong
Jin, Gaojie
Huang, Tianjin
Zhou, Wei
Li, Wenhui
Jin, Xiaobo
Huang, Bo
Zhao, Yitian
Yang, Guang
Lip, Gregory Y. H.
Zheng, Yalin
Villavicencio, Aline
Meng, Yanda
Computer Vision and Pattern Recognition
Annotating medical data for training AI models is often costly and limited due to the shortage of specialists with relevant clinical expertise. This challenge is further compounded by privacy and ethical concerns associated with sensitive patient information. As a result, well-trained medical segmentation models on private datasets constitute valuable intellectual property requiring robust protection mechanisms. Existing model protection techniques primarily focus on classification and generative tasks, while segmentation models-crucial to medical image analysis-remain largely underexplored. In this paper, we propose a novel, stealthy, and harmless method, StealthMark, for verifying the ownership of medical segmentation models under black-box conditions. Our approach subtly modulates model uncertainty without altering the final segmentation outputs, thereby preserving the model's performance. To enable ownership verification, we incorporate model-agnostic explanation methods, e.g. LIME, to extract feature attributions from the model outputs. Under specific triggering conditions, these explanations reveal a distinct and verifiable watermark. We further design the watermark as a QR code to facilitate robust and recognizable ownership claims. We conducted extensive experiments across four medical imaging datasets and five mainstream segmentation models. The results demonstrate the effectiveness, stealthiness, and harmlessness of our method on the original model's segmentation performance. For example, when applied to the SAM model, StealthMark consistently achieved ASR above 95% across various datasets while maintaining less than a 1% drop in Dice and AUC scores, significantly outperforming backdoor-based watermarking methods and highlighting its strong potential for practical deployment. Our implementation code is made available at: https://github.com/Qinkaiyu/StealthMark.
title StealthMark: Harmless and Stealthy Ownership Verification for Medical Segmentation via Uncertainty-Guided Backdoors
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2601.17107