TransAttU-Net深度神经网络在磁共振成像中的脑肿瘤分割

IF 2.1 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE IEEE Canadian Journal of Electrical and Computer Engineering Pub Date : 2023-11-02 DOI:10.1109/ICJECE.2023.3289609
Hariharan Ramamoorthy;Mohan Ramasundaram;Raja Soosaimarian Peter Raj;Krunal Randive
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引用次数: 0

摘要

脑肿瘤是组织中的一种畸形,细胞分裂迅速且不受控制。结果,肿瘤扩大了。据推测,神经网络可以成功地识别和预测脑肿瘤,这是目前医生面临的两个最具挑战性的医学问题。丰富的信息增强了磁共振成像(MRI)的诊断潜力,磁共振成像提供了脑肿瘤的解剖特征。为了提高语义分割架构的效率,我们引入了一种新的基于变压器的注意力u型网络TransAttU-Net,该网络多级引导注意力和多尺度跳跃连接同时运行,并用于提取肿瘤区域上的像素。首先,输入的图像数据被改变,并使用各种预处理技术进行进一步处理。诸如此类的方法可用于调整特征的大小或重新缩放、数据增强、反转或翻转数据,以及更改数据的方向。在将数据发送到TransAttU-Net深度学习(DL)模型之前,需要执行这些程序。该算法在BraTS 2019(即多模态脑肿瘤图像分割挑战中提供的数据集)和BraTS 2020数据集上取得了一定程度的准确率,表明该算法在BraTS 2020数据集上具有良好的性能。本文对模型的性能指标进行了评估,并对结果进行了讨论。
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TransAttU-Net Deep Neural Network for Brain Tumor Segmentation in Magnetic Resonance Imaging
A brain tumor is a deformity in the tissue where cells divide promptly and uncontrollably. As a consequence, the tumor expands. It is hypothesized that a neural network can successfully identify and predict brain tumors, two of the most challenging medical problems now facing doctors. The abundance of information enhances the diagnostic potential of magnetic resonance imaging (MRI) which provides the anatomical features of brain tumors. To improve the efficiency of the semantic segmentation architecture, we introduce a novel transformer-based attention U-shaped network called TransAttU-Net, in which the multilevel guided attention and multiscale skip connection operate simultaneously and which is also used to extract the pixel on the tumor area. Initially, the input image data are altered and undergo further processing using various preprocessing techniques. Methods such as these can be used to resize or rescale features, data augmentation, reverse or flip data, and alter the orientation of data. These procedures are required before sending data to the TransAttU-Net deep learning (DL) model. The algorithm attained a degree of accuracy on the BraTS 2019, i.e., the dataset provided in multimodal brain tumor image segmentation challenge and BraTS 2020 dataset, indicating great performance on BraTS 2020 dataset. The performance metrics of the models are evaluated using and results are discussed in this article.
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