Brain Imaging Centre, Research Centre for Natural Sciences, Hungarian Academy of Sciences, Budapest, Hungary.
Department of Nuclear Techniques, Budapest University of Technology and Economics, Budapest, Hungary.
Magn Reson Med. 2019 Sep;82(3):1073-1090. doi: 10.1002/mrm.27799. Epub 2019 May 13.
In this study we propose a method to combine the parallel virtual conjugate coil (VCC) reconstruction with partial Fourier (PF) acquisition to improve reconstruction conditioning and reduce noise amplification in accelerated MRI where PF is used.
Accelerated measurements are reconstructed in k-space by GRAPPA, with a VCC reconstruction kernel trained and applied in the central, symmetrically sampled part of k-space, while standard reconstruction is performed on the asymmetrically sampled periphery. The two reconstructed regions are merged to form a full reconstructed dataset, followed by PF reconstruction. The method is tested in vivo using T1-weighted spin-echo and T2*-weighted gradient-echo echo planar imaging (EPI) sequences, using both in-plane and simultaneous multislice (SMS) acceleration, at 1.5T and 3T field strengths. Noise amplification is estimated with theoretical calculations and pseudo-multiple-replica computations, for different PF factors, using zero-filling, homodyne, and projection onto convex sets (POCS) PF reconstruction.
Depending on the PF algorithm and the inherent benefit of VCC reconstruction without PF, approximately 35% to 80%, 15% to 60%, and 5% to 30% of that intrinsic SNR gain can be retained for PF factors 7/8, 6/8, and 5/8, respectively, by including the VCC signals in the reconstruction. Compared with VCC-reconstructed acquisitions of higher acceleration, without PF, but having the same net acceleration, the combined method can provide a higher SNR if the inherent benefit of VCC is low or moderate.
The proposed technique enables the partial application of VCC reconstruction to measurements with PF using either in-plane or SMS acceleration, and therefore can reduce the noise amplification of such acquisitions.
本研究提出一种方法,将平行虚拟共轭线圈(VCC)重建与部分傅里叶(PF)采集相结合,以改善重建条件,并在使用 PF 的加速 MRI 中减少噪声放大。
通过 GRAPPA 在 k 空间中重建加速测量值,在 k 空间的中心、对称采样部分训练和应用 VCC 重建核,而在非对称采样的外围进行标准重建。两个重建区域合并形成完整的重建数据集,然后进行 PF 重建。该方法在 1.5T 和 3T 场强下,使用 T1 加权自旋回波和 T2*-加权梯度回波平面成像(EPI)序列,分别在平面内和同时多切片(SMS)加速中进行了体内测试。使用零填充、同相和凸集投影(POCS)PF 重建,针对不同的 PF 因子,通过理论计算和伪多次复制计算来估计噪声放大。
根据 PF 算法和没有 PF 的 VCC 重建的固有优势,对于 PF 因子 7/8、6/8 和 5/8,分别可以保留约 35%至 80%、15%至 60%和 5%至 30%的固有 SNR 增益,将 VCC 信号包含在重建中。与没有 PF 的更高加速的 VCC 重建采集相比,但具有相同的净加速,如果 VCC 的固有优势较低或中等,则组合方法可以提供更高的 SNR。
所提出的技术允许将 VCC 重建的部分应用于使用平面内或 SMS 加速的具有 PF 的测量值,从而可以减少此类采集的噪声放大。
