使用模型引导的自监督深度学习进行磁共振参数映射
Magnetic resonance parameter mapping using model-guided self-supervised deep learning.
作者信息
Liu Fang, Kijowski Richard, El Fakhri Georges, Feng Li
机构信息
Department of Radiology, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts, USA.
Department of Radiology, University of Wisconsin-Madison, Madison, Wisconsin, USA.
出版信息
Magn Reson Med. 2021 Jun;85(6):3211-3226. doi: 10.1002/mrm.28659. Epub 2021 Jan 19.
PURPOSE
To develop a model-guided self-supervised deep learning MRI reconstruction framework called reference-free latent map extraction (RELAX) for rapid quantitative MR parameter mapping.
METHODS
Two physical models are incorporated for network training in RELAX, including the inherent MR imaging model and a quantitative model that is used to fit parameters in quantitative MRI. By enforcing these physical model constraints, RELAX eliminates the need for full sampled reference data sets that are required in standard supervised learning. Meanwhile, RELAX also enables direct reconstruction of corresponding MR parameter maps from undersampled k-space. Generic sparsity constraints used in conventional iterative reconstruction, such as the total variation constraint, can be additionally included in the RELAX framework to improve reconstruction quality. The performance of RELAX was tested for accelerated T and T mapping in both simulated and actually acquired MRI data sets and was compared with supervised learning and conventional constrained reconstruction for suppressing noise and/or undersampling-induced artifacts.
RESULTS
In the simulated data sets, RELAX generated good T /T maps in the presence of noise and/or undersampling artifacts, comparable to artifact/noise-free ground truth. The inclusion of a spatial total variation constraint helps improve image quality. For the in vivo T /T mapping data sets, RELAX achieved superior reconstruction quality compared with conventional iterative reconstruction, and similar reconstruction performance to supervised deep learning reconstruction.
CONCLUSION
This work has demonstrated the initial feasibility of rapid quantitative MR parameter mapping based on self-supervised deep learning. The RELAX framework may also be further extended to other quantitative MRI applications by incorporating corresponding quantitative imaging models.
目的
开发一种模型引导的自监督深度学习磁共振成像(MRI)重建框架,称为无参考潜在图提取(RELAX),用于快速定量磁共振参数映射。
方法
在RELAX中纳入两个物理模型进行网络训练,包括固有的MRI成像模型和用于定量MRI中参数拟合的定量模型。通过实施这些物理模型约束,RELAX无需标准监督学习中所需的全采样参考数据集。同时,RELAX还能够从欠采样的k空间直接重建相应的磁共振参数图。传统迭代重建中使用的通用稀疏约束,如总变差约束,可额外纳入RELAX框架以提高重建质量。在模拟和实际采集的MRI数据集中测试了RELAX在加速T和T映射方面的性能,并与监督学习和传统约束重建进行比较,以抑制噪声和/或欠采样引起的伪影。
结果
在模拟数据集中,RELAX在存在噪声和/或欠采样伪影的情况下生成了良好的T/T图,与无伪影/噪声的真实情况相当。纳入空间总变差约束有助于提高图像质量。对于体内T/T映射数据集,与传统迭代重建相比,RELAX实现了更高的重建质量,与监督深度学习重建具有相似的重建性能。
结论
这项工作证明了基于自监督深度学习进行快速定量磁共振参数映射的初步可行性。通过纳入相应的定量成像模型,RELAX框架也可能进一步扩展到其他定量MRI应用。
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