Deep neural network architectures for cardiac image segmentation

Artificial intelligence in the life sciences Pub Date : 2023-08-09 DOI:10.1016/j.ailsci.2023.100083

Jasmine El-Taraboulsi , Claudia P. Cabrera , Caroline Roney , Nay Aung

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Abstract

Imaging plays a fundamental role in the effective diagnosis, staging, management, and monitoring of various cardiac pathologies. Successful radiological analysis relies on accurate image segmentation, a technically arduous process, prone to human-error. To overcome the laborious and time-consuming nature of cardiac image analysis, deep learning approaches have been developed, enabling the accurate, time-efficient, and highly personalised diagnosis, staging and management of cardiac pathologies.

Here, we present a review of over 60 papers, proposing deep learning models for cardiac image segmentation. We summarise the theoretical basis of Convolutional Neural Networks, Fully Convolutional Neural Networks, U-Net, V-Net, No-New-U-Net (nnU-Net), Transformer Networks, DeepLab, Generative Adversarial Networks, Auto Encoders and Recurrent Neural Networks. In addition, we identify pertinent performance-enhancing measures including adaptive convolutional kernels, atrous convolutions, attention gates, and deep supervision modules.

Top-performing models in ventricular, myocardial, atrial and aortic segmentation are explored, highlighting U-Net and nnU-Net-based model architectures achieving state-of-the art segmentation accuracies. Additionally, key gaps in the current research and technology are identified, and areas of future research are suggested, aiming to guide the innovation and clinical adoption of automated cardiac segmentation methods.

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用于心脏图像分割的深度神经网络结构

影像在各种心脏疾病的有效诊断、分期、管理和监测中起着重要作用。成功的放射分析依赖于准确的图像分割，这是一个技术上艰巨的过程，容易出现人为错误。为了克服心脏图像分析的费力和耗时的性质，深度学习方法已经被开发出来，能够准确，高效，高度个性化的心脏病理诊断，分期和管理。在这里，我们回顾了60多篇论文，提出了用于心脏图像分割的深度学习模型。我们总结了卷积神经网络、全卷积神经网络、U-Net、V-Net、No-New-U-Net (nnU-Net)、变压器网络、DeepLab、生成对抗网络、自动编码器和循环神经网络的理论基础。此外，我们还确定了相关的性能增强措施，包括自适应卷积核、亚属性卷积、注意门和深度监督模块。探索了心室、心肌、心房和主动脉分割中表现最好的模型，突出了基于U-Net和nnu - net的模型架构，实现了最先进的分割精度。此外，指出了当前研究和技术的关键差距，并提出了未来的研究领域，旨在指导自动化心脏分割方法的创新和临床应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Artificial intelligence in the life sciences Pharmacology, Biochemistry, Genetics and Molecular Biology (General), Computer Science Applications, Health Informatics, Drug Discovery, Veterinary Science and Veterinary Medicine (General)

CiteScore

5.00

自引率

0.00%

发文量

审稿时长

15 days

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