基于注意力的残差U-Net多模态MRI脑图像肿瘤分割

IF 3.4 3区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Access Pub Date : 2025-01-13 DOI:10.1109/ACCESS.2025.3528654

Najme Zehra Naqvi;K. R. Seeja

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引用次数: 0

摘要

由于复杂的大脑解剖结构和肿瘤大小、形状和位置的广泛范围，检测脑肿瘤是具有挑战性的。诊断和治疗脑肿瘤的一个关键阶段是通过脑MRI自动分割肿瘤区域。它包括在MRI扫描中精确描绘肿瘤边界，这有助于了解肿瘤的范围，监测其生长，计划治疗策略，并评估治疗反应。因此，本研究提出了一种新的基于U-Net的神经胶质瘤肿瘤分割的自动深度学习方法。在提出的模型中，对基本的U-Net模型进行了若干组件的增强，以提高其性能。U-Net的编码器具有改进的MCA（多尺度上下文注意）模块，旨在从输入图像中提取和收集丰富的空间上下文信息。提出的U-Net解码器使用挤压和激励模块和剩余块。残差块有助于减少网络退化和梯度消失，使模型在解码过程中保留重要信息。挤压和激励模块允许模型检索从编码器模块和IMCA-Block收集的高级语义属性和高级空间上下文。在BraTS 2020和BraTS 2018两个数据集上对该模型的性能进行了评估。在两个数据集上的实验表明，所提出的框架在所有评估指标上都提高了多模态MRI脑肿瘤分割性能。对于BraTS 2020，它分别实现了WT（整个肿瘤），TC（肿瘤核心）和ET（增强肿瘤）的骰子系数0.9978,0.9378和0.9478，对于BraTS 2018，它分别实现了WT（整个肿瘤），TC（肿瘤核心）和ET（增强肿瘤）的骰子系数98.32,93.32和92.32。

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An Attention-Based Residual U-Net for Tumour Segmentation Using Multi-Modal MRI Brain Images

Detecting brain tumours is challenging due to the complex brain anatomy and wide range of tumour sizes, shapes, and locations. A crucial stage in diagnosing and treating brain tumours is automatically segmenting the tumour area from brain MRI. It involves the precise delineation of tumour boundaries within MRI scans, which helps to understand the tumour’s extent, monitor its growth, plan treatment strategies, and assess treatment response over time. Hence, this research proposes a novel automated deep-learning approach based on U-Net for segmenting Glioma tumours. The basic U-Net model is enhanced with several components to improve its performance in the proposed model. The U-Net’s encoder has an improved MCA (Multi-scale Context Attention) module designed to extract and collect rich spatial contextual information from the input image. The proposed U-Net’s decoder uses a Squeeze and Excitation module and residual blocks. The residual blocks help reduce network degradation and gradient disappearance, enabling the model to retain important information during decoding. The Squeeze and Excitation module allows the model to retrieve high-level semantic properties and a high level of spatial context, which have been collected from the encoder module and IMCA-Block. The performance of proposed model is evaluated on two datasets BraTS 2020 and BraTS 2018. The experiments on both datasets demonstrate that the proposed framework enhances multi-modal MRI brain tumour segmentation performance on all metrics evaluated. For BraTS 2020 it achieved Dice Coefficient of 0.9978, 0.9378 and 0.9478 for WT (Whole tumour), TC (Tumour core), and ET (Enhancing Tumour) respectively and for BraTS 2018 it achieved Dice Coefficient 98.32, 93.32 and 92.32 for WT (Whole tumour), TC (Tumour core), and ET (Enhancing Tumour) respectively.

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来源期刊

IEEE Access COMPUTER SCIENCE, INFORMATION SYSTEMSENGIN-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

9.80

自引率

7.70%

发文量

6673

审稿时长

6 weeks

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