人工智能
分割
计算机科学
模式识别(心理学)
一般化
特征(语言学)
编码器
图像分割
Boosting(机器学习)
像素
医学影像学
计算机视觉
特征向量
噪音(视频)
混乱
特征提取
监督学习
约束(计算机辅助设计)
图像(数学)
特征学习
深度学习
稳健性(进化)
尺度空间分割
数学形态学
回归
推论
机器学习
作者
Wenzhen Zhang,Yankun Cao,Xifeng Hu,Guanjie Sun,Yuezhong Zhang,Yujun Li,Qing Cai,Zhi Liu
标识
DOI:10.1109/tbme.2025.3609344
摘要
Excellent performance has been achieved on medical image segmentation. Still, existing algorithms perform relatively poorly for annular objects with high intra-class variability and inter-class similarity, which easily leads to regional confusion, especially in medical images with annular regions. In this paper, we first propose an annular prior prompt learning method based on MedSAM, coined APPL, which not only can strengthen the learning for annular region features, but also effectively handles the regional confusion caused by high intra-class variability and inter-class similarity. Specifically, a novel annular prior prompt encoder (APPE) is proposed based on our designed annular constraint to alleviate the negative impact of inter-class similarity, which maps multiple prompt points into a linear regression feature space to provide the standardized annular prompt feature for the mask decoder. In addition, a new region connectivity enhanced image encoder (RCEIE) is developed to introduce morphology attention into supervised training, which reduces feature noise caused by intra-class variability, significantly improving the connectivity of region features. Powered by the collaboration across different annular features, the mask decoder can effectively avoid inter-class confusion to reduce the impact of weak boundaries, further boosting the performance for tackling highly diverse pixel distributions in medical images. Compared with most state-of-the-art methods, the proposed method achieves 90.07% of the mIoU and 94.71% of the DSC on an in-house dataset, and shows strong generalization on two public heart segmentation datasets with end-diastolic DSC scores of 94.2% and 83.9%, and end-systolic DSC scores of 95.5% and 87.3%. The experimental results demonstrate the consistently superior performance of our method quantitatively and qualitatively.
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