{"title":"基于改进型 U-Net 的医学图像分割方法研究3。","authors":"Chaoying Wang, Jianxin Li, Huijun Zheng, Jiajun Li, Hongxing Huang, Lai Jiang","doi":"10.1615/CritRevBiomedEng.2024052258","DOIUrl":null,"url":null,"abstract":"<p><p>Computer assisted diagnostic technology has been widely used in clinical practice, specifically focusing on medical image segmentation. Its purpose is to segment targets with certain special meanings in medical images and extract relevant features, providing reliable basis for subsequent clinical diagnosis and research. However, because of different shapes and complex structures of segmentation targets in different medical images, some imaging techniques have similar characteristics, such as intensity, color, or texture, for imaging different organs and tissues. The localization and segmentation of targets in medical images remains an urgent technical challenge to be solved. As such, an improved full scale skip connection network structure for the CT liver image segmentation task is proposed. This structure includes a biomimetic attention module between the shallow encoder and the deep decoder, and the feature fusion proportion coefficient between the two is learned to enhance the attention of the overall network to the segmented target area. In addition, based on the traditional point sampling mechanism, an improved point sampling strategy is proposed for characterizing medical images to further enhance the edge segmentation effect of CT liver targets. The experimental results on the commonly used combined (CT-MR) health absolute organ segmentation (CHAOS) dataset show that the average dice similarity coefficient (DSC) can reach 0.9467, the average intersection over union (IOU) can reach 0.9623, and the average F1 score can reach 0.9351. This indicates that the model can effectively learn image detail features and global structural features, leading to improved segmentation of liver images.</p>","PeriodicalId":94308,"journal":{"name":"Critical reviews in biomedical engineering","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Research on Medical Image Segmentation Method Based on Improved U-Net3.\",\"authors\":\"Chaoying Wang, Jianxin Li, Huijun Zheng, Jiajun Li, Hongxing Huang, Lai Jiang\",\"doi\":\"10.1615/CritRevBiomedEng.2024052258\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Computer assisted diagnostic technology has been widely used in clinical practice, specifically focusing on medical image segmentation. Its purpose is to segment targets with certain special meanings in medical images and extract relevant features, providing reliable basis for subsequent clinical diagnosis and research. However, because of different shapes and complex structures of segmentation targets in different medical images, some imaging techniques have similar characteristics, such as intensity, color, or texture, for imaging different organs and tissues. The localization and segmentation of targets in medical images remains an urgent technical challenge to be solved. As such, an improved full scale skip connection network structure for the CT liver image segmentation task is proposed. This structure includes a biomimetic attention module between the shallow encoder and the deep decoder, and the feature fusion proportion coefficient between the two is learned to enhance the attention of the overall network to the segmented target area. In addition, based on the traditional point sampling mechanism, an improved point sampling strategy is proposed for characterizing medical images to further enhance the edge segmentation effect of CT liver targets. The experimental results on the commonly used combined (CT-MR) health absolute organ segmentation (CHAOS) dataset show that the average dice similarity coefficient (DSC) can reach 0.9467, the average intersection over union (IOU) can reach 0.9623, and the average F1 score can reach 0.9351. 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引用次数: 0
摘要
计算机辅助诊断技术已被广泛应用于临床实践,尤其侧重于医学影像分割。其目的是对医学影像中具有某些特殊意义的目标进行分割,提取相关特征,为后续的临床诊断和研究提供可靠依据。然而,由于不同医学图像中的分割目标形状各异、结构复杂,有些成像技术对不同器官和组织的成像具有相似的特征,如强度、颜色或纹理等。医疗图像中目标的定位和分割仍然是亟待解决的技术难题。因此,针对 CT 肝脏图像分割任务,提出了一种改进的全尺度跳转连接网络结构。该结构包括浅层编码器和深层解码器之间的仿生物注意力模块,并学习两者之间的特征融合比例系数,以增强整个网络对分割目标区域的注意力。此外,在传统点采样机制的基础上,提出了一种改进的医疗图像特征点采样策略,以进一步增强 CT 肝脏靶标的边缘分割效果。在常用的联合(CT-MR)健康绝对器官分割(CHAOS)数据集上的实验结果表明,平均骰子相似系数(DSC)可达 0.9467,平均交集大于联合(IOU)可达 0.9623,平均 F1 分数可达 0.9351。这表明该模型能有效地学习图像细节特征和全局结构特征,从而改进肝脏图像的分割。
Research on Medical Image Segmentation Method Based on Improved U-Net3.
Computer assisted diagnostic technology has been widely used in clinical practice, specifically focusing on medical image segmentation. Its purpose is to segment targets with certain special meanings in medical images and extract relevant features, providing reliable basis for subsequent clinical diagnosis and research. However, because of different shapes and complex structures of segmentation targets in different medical images, some imaging techniques have similar characteristics, such as intensity, color, or texture, for imaging different organs and tissues. The localization and segmentation of targets in medical images remains an urgent technical challenge to be solved. As such, an improved full scale skip connection network structure for the CT liver image segmentation task is proposed. This structure includes a biomimetic attention module between the shallow encoder and the deep decoder, and the feature fusion proportion coefficient between the two is learned to enhance the attention of the overall network to the segmented target area. In addition, based on the traditional point sampling mechanism, an improved point sampling strategy is proposed for characterizing medical images to further enhance the edge segmentation effect of CT liver targets. The experimental results on the commonly used combined (CT-MR) health absolute organ segmentation (CHAOS) dataset show that the average dice similarity coefficient (DSC) can reach 0.9467, the average intersection over union (IOU) can reach 0.9623, and the average F1 score can reach 0.9351. This indicates that the model can effectively learn image detail features and global structural features, leading to improved segmentation of liver images.