[Multi-scale medical image segmentation based on pixel encoding and spatial attention mechanism].

Yulong Wan, Dongming Zhou, Changcheng Wang, Yisong Liu, Chongbin Bai
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Abstract

In response to the issues of single-scale information loss and large model parameter size during the sampling process in U-Net and its variants for medical image segmentation, this paper proposes a multi-scale medical image segmentation method based on pixel encoding and spatial attention. Firstly, by redesigning the input strategy of the Transformer structure, a pixel encoding module is introduced to enable the model to extract global semantic information from multi-scale image features, obtaining richer feature information. Additionally, deformable convolutions are incorporated into the Transformer module to accelerate convergence speed and improve module performance. Secondly, a spatial attention module with residual connections is introduced to allow the model to focus on the foreground information of the fused feature maps. Finally, through ablation experiments, the network is lightweighted to enhance segmentation accuracy and accelerate model convergence. The proposed algorithm achieves satisfactory results on the Synapse dataset, an official public dataset for multi-organ segmentation provided by the International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI), with Dice similarity coefficient (DSC) and 95% Hausdorff distance (HD95) scores of 77.65 and 18.34, respectively. The experimental results demonstrate that the proposed algorithm can enhance multi-organ segmentation performance, potentially filling the gap in multi-scale medical image segmentation algorithms, and providing assistance for professional physicians in diagnosis.

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[基于像素编码和空间注意力机制的多尺度医学图像分割]。
针对 U-Net 及其变体在医学图像分割中采样过程中存在的单尺度信息丢失和模型参数体积过大的问题,本文提出了一种基于像素编码和空间注意力的多尺度医学图像分割方法。首先,通过重新设计变换器结构的输入策略,引入像素编码模块,使模型能够从多尺度图像特征中提取全局语义信息,获得更丰富的特征信息。此外,还在变换器模块中加入了可变形卷积,以加快收敛速度,提高模块性能。其次,引入了具有残差连接的空间关注模块,使模型能够关注融合特征图的前景信息。最后,通过消融实验,对网络进行轻量化处理,以提高分割精度,加快模型收敛速度。提出的算法在国际医学影像计算和计算机辅助干预会议(MICCAI)提供的多器官分割官方公开数据集 Synapse 数据集上取得了令人满意的结果,Dice 相似系数(DSC)和 95% Hausdorff 距离(HD95)得分分别为 77.65 和 18.34。实验结果表明,提出的算法可以提高多器官分割性能,有望填补多尺度医学图像分割算法的空白,为专业医生的诊断提供帮助。
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来源期刊
生物医学工程学杂志
生物医学工程学杂志 Medicine-Medicine (all)
CiteScore
0.80
自引率
0.00%
发文量
4868
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