On the generalized inverse for MRI reconstruction

2022 14th Biomedical Engineering International Conference (BMEiCON) Pub Date : 2022-11-10 DOI:10.1109/BMEiCON56653.2022.10012099

Tzu-Hsueh Tsai, Hsin-Chia Chen, Hao Yang, Yu-Chieh Chao, Jyh-Miin Lin, Chih-Ching Chen, Hing-Chiu Chang, Chin-Kuo Chang, Wei-Hsuan Yu, F. Hwang, M. Graves

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引用次数: 1

Abstract

Recent studies have suggested that the boundary between data-driven deep-learning non-Cartesian magnetic resonance imaging (MRI) reconstruction methods and conventional optimization-based, iterative reconstruction methods is becoming blurred. For instance, the unrolled iterative reconstruction method can be regarded as a trainable neural network. Another example is that the Moore-Penrose pseudoinverse plays a central role in finding the predefined solution to many imaging processes. However, the application of pseudoinverse in MRI reconstruction was obstructed in clinical imaging, mostly due to the excessive storage required for singular vectors. Since the spatial encoding of MRI is fully determined by the known k-space trajectory, the generalized inverse can be ”iteratively learning in a data-free fashion”, which leads to surprising but realizable properties. To compare our method with other conventional methods, numerical simulations were performed using in vivo MRI. The proposed method leads to nearly equivalent image quality with a much shorter run-time (only 0.68%) than the conjugate gradient (CG) method. We discuss the potential impact of the generalized inverse as a feasible reconstruction method for non-Cartesian MRI.

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MRI重构的广义逆

最近的研究表明，数据驱动的深度学习非笛卡尔磁共振成像(MRI)重建方法与传统的基于优化的迭代重建方法之间的界限正在变得模糊。例如，展开迭代重建方法可以看作是一个可训练的神经网络。另一个例子是Moore-Penrose伪逆在寻找许多成像过程的预定义解决方案中起着核心作用。然而，伪逆在MRI重建中的应用在临床成像中受到阻碍，主要是由于奇异向量需要过多的存储。由于MRI的空间编码完全由已知的k空间轨迹决定，因此广义逆可以“以无数据的方式迭代学习”，这导致了令人惊讶但可实现的特性。为了与其他传统方法进行比较，我们使用体内MRI进行了数值模拟。与共轭梯度(CG)方法相比，该方法的运行时间(仅为0.68%)大大缩短，图像质量几乎相等。我们讨论了广义逆作为一种可行的非笛卡儿MRI重建方法的潜在影响。

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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2022 14th Biomedical Engineering International Conference (BMEiCON)

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