Inception-UDet: An Improved U-Net Architecture for Brain Tumor Segmentation

Q1 Decision Sciences

Annals of Data Science Pub Date : 2023-07-01 DOI:10.1007/s40745-023-00480-6

Ilyasse Aboussaleh, Jamal Riffi, Adnane Mohamed Mahraz, Hamid Tairi

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Abstract

Brain tumor segmentation is an important field and a sensitive task in tumor diagnosis. The treatment research in this area has helped specialists in detecting the tumor’s location in order to deal with it in its early stages. Numerous methods based on deep learning, have been proposed, including the symmetric U-Net architectures, which revealed great results in the medical imaging field, precisely brain tumor segmentation. In this paper, we proposed an improved U-Net architecture called Inception U-Det inspired by U-Det. This work aims at employing the inception block instead of the convolution one used in the bi-directional feature pyramid neural (Bi-FPN) network during the skip connection U-Det phase. Furthermore, a comparison study has been performed between our proposed approach and the three known architectures in medical imaging segmentation; U-Net, DC-Unet, and U-Det. Several segmentation metrics have been computed and then taken into account in these methods, by means of the publicly available BraTS datasets. Thus, our obtained results have showed promising results in terms of accuracy, dice similarity coefficient (DSC), and intersection–union ratio (IOU). Moreover, the proposed method has achieved a DSC of 87.9%, 85.5%, and 83.9% on BraTS2020, BraTS2018, and BraTS2017, respectively, calculated from the best fold in fourfold cross-validation employed in the present approach.

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Inception-UDet:一种改进的U-Net结构用于脑肿瘤分割

脑肿瘤分割是肿瘤诊断的一个重要领域和敏感任务。该领域的治疗研究有助于专家检测肿瘤的位置，以便在早期阶段进行治疗。目前已经提出了许多基于深度学习的方法，包括对称 U-Net 架构，这些方法在医学成像领域，尤其是脑肿瘤分割领域取得了巨大的成果。在本文中，我们受 U-Det 的启发，提出了一种改进的 U-Net 体系结构--Inception U-Det，其目的是在跳接 U-Det 阶段使用初始块来代替双向特征金字塔神经网络（Bi-FPN）中使用的卷积块。此外，我们还对所提出的方法与医学影像分割领域的三种已知架构（U-Net、DC-Unet 和 U-Det）进行了比较研究，并通过公开的 BraTS 数据集计算了几种分割指标，然后将其纳入这些方法的考虑范围。因此，我们所获得的结果在准确度、骰子相似系数（DSC）和交集联合率（IOU）方面都显示出了良好的效果。此外，根据本方法采用的四重交叉验证中的最佳折叠计算，所提出的方法在 BraTS2020、BraTS2018 和 BraTS2017 上的 DSC 分别达到了 87.9%、85.5% 和 83.9%。

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来源期刊

Annals of Data Science Decision Sciences-Statistics, Probability and Uncertainty

CiteScore

6.50

自引率

0.00%

发文量

期刊介绍： Annals of Data Science (ADS) publishes cutting-edge research findings, experimental results and case studies of data science. Although Data Science is regarded as an interdisciplinary field of using mathematics, statistics, databases, data mining, high-performance computing, knowledge management and virtualization to discover knowledge from Big Data, it should have its own scientific contents, such as axioms, laws and rules, which are fundamentally important for experts in different fields to explore their own interests from Big Data. ADS encourages contributors to address such challenging problems at this exchange platform. At present, how to discover knowledge from heterogeneous data under Big Data environment needs to be addressed. ADS is a series of volumes edited by either the editorial office or guest editors. Guest editors will be responsible for call-for-papers and the review process for high-quality contributions in their volumes.