无binning非笛卡儿心脏MR成像的神经隐式k空间

Wenqi Huang, Hongwei Li, G. Cruz, Jia-Yu Pan, D. Rueckert, K. Hammernik
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引用次数: 8

摘要

在这项工作中,我们提出了一种新的图像重建框架,该框架直接学习了心电图触发的非笛卡尔心脏磁共振成像(CMR)在k空间中的神经隐式表示。虽然现有的方法是从邻近的时间点获取数据来重建心脏运动的一个阶段,但我们的框架允许连续的、无分节的和特定于受试者的k空间表示。我们为每个采样的k空间点分配一个由时间、线圈指数和频域位置组成的唯一坐标。然后,我们使用具有频域正则化的多层感知器学习从这些唯一坐标到k空间强度的主题特定映射。在推理过程中,我们获得了笛卡尔坐标的完整k空间和任意时间分辨率。一个简单的傅里叶反变换恢复图像,消除了对非笛卡尔数据的密度补偿和昂贵的非均匀傅里叶变换的需要。这个新的成像框架在来自6个受试者的42个径向采样数据集上进行了测试。所提出的方法在定性和定量上优于其他技术,使用来自四个和一个心跳(s)和30个心相的数据。我们对50个心相的一次心跳重建的结果显示,伪影去除和时空分辨率得到了改善,充分利用了实时CMR的潜力。
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Neural Implicit k-Space for Binning-free Non-Cartesian Cardiac MR Imaging
In this work, we propose a novel image reconstruction framework that directly learns a neural implicit representation in k-space for ECG-triggered non-Cartesian Cardiac Magnetic Resonance Imaging (CMR). While existing methods bin acquired data from neighboring time points to reconstruct one phase of the cardiac motion, our framework allows for a continuous, binning-free, and subject-specific k-space representation.We assign a unique coordinate that consists of time, coil index, and frequency domain location to each sampled k-space point. We then learn the subject-specific mapping from these unique coordinates to k-space intensities using a multi-layer perceptron with frequency domain regularization. During inference, we obtain a complete k-space for Cartesian coordinates and an arbitrary temporal resolution. A simple inverse Fourier transform recovers the image, eliminating the need for density compensation and costly non-uniform Fourier transforms for non-Cartesian data. This novel imaging framework was tested on 42 radially sampled datasets from 6 subjects. The proposed method outperforms other techniques qualitatively and quantitatively using data from four and one heartbeat(s) and 30 cardiac phases. Our results for one heartbeat reconstruction of 50 cardiac phases show improved artifact removal and spatio-temporal resolution, leveraging the potential for real-time CMR.
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