[Ischemic stroke infarct segmentation model based on depthwise separable convolution for multimodal magnetic resonance imaging].

Yidong Jin, Mengfei Wang, Jingjing Chen, Yuehua Li
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Abstract

Magnetic resonance imaging (MRI) plays a crucial role in the diagnosis of ischemic stroke. Accurate segmentation of the infarct is of great significance for selecting intervention treatment methods and evaluating the prognosis of patients. To address the issue of poor segmentation accuracy of existing methods for multiscale stroke lesions, a novel encoder-decoder architecture network based on depthwise separable convolution is proposed. Firstly, this network replaces the convolutional layer modules of the U-Net with redesigned depthwise separable convolution modules. Secondly, an modified Atrous spatial pyramid pooling (MASPP) is introduced to enlarge the receptive field and enhance the extraction of multiscale features. Thirdly, an attention gate (AG) structure is incorporated at the skip connections of the network to further enhance the segmentation accuracy of multiscale targets. Finally, Experimental evaluations are conducted using the ischemic stroke lesion segmentation 2022 challenge (ISLES2022) dataset. The proposed algorithm in this paper achieves Dice similarity coefficient (DSC), Hausdorff distance (HD), sensitivity (SEN), and precision (PRE) scores of 0.816 5, 3.668 1, 0.889 2, and 0.894 6, respectively, outperforming other mainstream segmentation algorithms. The experimental results demonstrate that the method in this paper effectively improves the segmentation of infarct lesions, and is expected to provide a reliable support for clinical diagnosis and treatment.

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[基于多模态磁共振成像深度可分离卷积的缺血性中风梗塞分割模型]。
磁共振成像(MRI)在缺血性脑卒中的诊断中起着至关重要的作用。准确分割梗死区对选择干预治疗方法和评估患者预后具有重要意义。针对现有方法对多尺度脑卒中病灶分割准确性差的问题,提出了一种基于深度可分离卷积的新型编码器-解码器架构网络。首先,该网络用重新设计的深度可分离卷积模块取代了 U-Net 的卷积层模块。其次,引入了改进的阿特鲁斯空间金字塔池化(MASPP)技术,以扩大感受野,增强多尺度特征的提取。第三,在网络的跳转连接处加入注意门(AG)结构,进一步提高多尺度目标的分割精度。最后,利用缺血性中风病灶分割 2022 挑战赛(ISLES2022)数据集进行了实验评估。本文提出的算法在 Dice 相似系数(DSC)、Hausdorff 距离(HD)、灵敏度(SEN)和精度(PRE)方面的得分分别为 0.816 5、3.668 1、0.889 2 和 0.894 6,优于其他主流分割算法。实验结果表明,本文方法有效提高了梗死病灶的分割效果,有望为临床诊断和治疗提供可靠的支持。
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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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