并行磁共振成像重建开源网络的鲁棒性数值和临床评估。

IF 2.5 3区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Magnetic Resonance in Medical Sciences Pub Date : 2024-10-01 Epub Date: 2023-07-28 DOI:10.2463/mrms.mp.2023-0031
Naoto Fujita, Suguru Yokosawa, Toru Shirai, Yasuhiko Terada
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引用次数: 0

摘要

目的:用于磁共振成像重建的深度神经网络(DNN)通常需要大型数据集进行训练。然而,在临床环境中,数据集的领域多种多样,DNN 对训练数据集和测试数据集之间的领域差异的鲁棒性如何一直是个未决问题。在此,我们从数值和临床角度评估了重建网络在临床实际条件下对不同领域的泛化能力,并就临床应用中选择模型时应考虑的要点提供了实际指导:我们比较了四种网络模型的重建性能:方法:我们比较了四种网络模型的重建性能:U-Net、深度级联卷积神经网络(DC-CNNs)、混合级联和变异网络(VarNet)。我们使用公开的多卷积数据集 fastMRI 进行训练和测试,并进行了单域测试(用于训练和测试的数据集域相同)和跨域测试(源域和目标域不同)。我们进行了单域测试(实验 1)和跨域测试(实验 2-4),重点关注六个因素(图像数量、采样模式、加速因子、噪声水平、对比度和解剖结构)的数值和临床表现:结果:U-Net 的性能低于三个基于模型的网络,而且对训练和测试数据集之间的领域转移的鲁棒性较差。在三种基于模型的网络中,VarNet 的性能和鲁棒性最高,其次是混合级联和 DC-CNN。特别是,VarNet 即使在训练图像数量有限(200 张图像/10 个案例)的情况下也表现出了很高的性能。与其他基于模型的网络相比,U-Net 对噪声水平的域偏移具有更强的鲁棒性。混合级联的性能和鲁棒性略优于 DC-CNN,但对噪声级域偏移的鲁棒性除外。临床评估结果与定量指标结果基本一致:在这项研究中,我们利用多扰数据对公开网络的鲁棒性进行了数值和临床评估。因此,本研究为临床应用提供了实际指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical and Clinical Evaluation of the Robustness of Open-source Networks for Parallel MR Imaging Reconstruction.

Purpose: Deep neural networks (DNNs) for MRI reconstruction often require large datasets for training. Still, in clinical settings, the domains of datasets are diverse, and how robust DNNs are to domain differences between training and testing datasets has been an open question. Here, we numerically and clinically evaluate the generalization of the reconstruction networks across various domains under clinically practical conditions and provide practical guidance on what points to consider when selecting models for clinical application.

Methods: We compare the reconstruction performance between four network models: U-Net, the deep cascade of convolutional neural networks (DC-CNNs), Hybrid Cascade, and variational network (VarNet). We used the public multicoil dataset fastMRI for training and testing and performed a single-domain test, where the domains of the dataset used for training and testing were the same, and cross-domain tests, where the source and target domains were different. We conducted a single-domain test (Experiment 1) and cross-domain tests (Experiments 2-4), focusing on six factors (the number of images, sampling pattern, acceleration factor, noise level, contrast, and anatomical structure) both numerically and clinically.

Results: U-Net had lower performance than the three model-based networks and was less robust to domain shifts between training and testing datasets. VarNet had the highest performance and robustness among the three model-based networks, followed by Hybrid Cascade and DC-CNN. Especially, VarNet showed high performance even with a limited number of training images (200 images/10 cases). U-Net was more robust to domain shifts concerning noise level than the other model-based networks. Hybrid Cascade showed slightly better performance and robustness than DC-CNN, except for robustness to noise-level domain shifts. The results of the clinical evaluations generally agreed with the results of the quantitative metrics.

Conclusion: In this study, we numerically and clinically evaluated the robustness of the publicly available networks using the multicoil data. Therefore, this study provided practical guidance for clinical applications.

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来源期刊
Magnetic Resonance in Medical Sciences
Magnetic Resonance in Medical Sciences RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
5.80
自引率
20.00%
发文量
71
审稿时长
>12 weeks
期刊介绍: Magnetic Resonance in Medical Sciences (MRMS or Magn Reson Med Sci) is an international journal pursuing the publication of original articles contributing to the progress of magnetic resonance in the field of biomedical sciences including technical developments and clinical applications. MRMS is an official journal of the Japanese Society for Magnetic Resonance in Medicine (JSMRM).
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