Self-navigated 3D diffusion MRI using an optimized CAIPI sampling and structured low-rank reconstruction estimated navigator.

Ziyu Li, Karla L Miller, Xi Chen, Mark Chiew, Wenchuan Wu
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Abstract

3D multi-slab acquisitions are an appealing approach for diffusion MRI because they are compatible with the imaging regime delivering optimal SNR efficiency. In conventional 3D multi-slab imaging, shot-to-shot phase variations caused by motion pose challenges due to the use of multi-shot k-space acquisition. Navigator acquisition after each imaging echo is typically employed to correct phase variations, which prolongs scan time and increases the specific absorption rate (SAR). The aim of this study is to develop a highly efficient, self-navigated method to correct for phase variations in 3D multi-slab diffusion MRI without explicitly acquiring navigators. The sampling of each shot is carefully designed to intersect with the central kz=0 plane of each slab, and the multi-shot sampling is optimized for self-navigation performance while retaining decent reconstruction quality. The kz=0 intersections from all shots are jointly used to reconstruct a 2D phase map for each shot using a structured low-rank constrained reconstruction that leverages the redundancy in shot and coil dimensions. The phase maps are used to eliminate the shot-to-shot phase inconsistency in the final 3D multi-shot reconstruction. We demonstrate the method's efficacy using retrospective simulations and prospectively acquired in-vivo experiments at 1.22 mm and 1.09 mm isotropic resolutions. Compared to conventional navigated 3D multi-slab imaging, the proposed self-navigated method achieves comparable image quality while shortening the scan time by 31.7% and improving the SNR efficiency by 15.5%. The proposed method produces comparable quality of DTI and white matter tractography to conventional navigated 3D multi-slab acquisition with a much shorter scan time.

使用优化 CAIPI 采样和结构化低秩重建估计导航器的自导航三维弥散 MRI。
三维多片采集是一种极具吸引力的弥散核磁共振成像方法,因为它与可提供最佳信噪比效率的成像机制相兼容。在传统的三维多平板成像中,由于使用多拍 k 空间采集,运动造成的拍间相位变化带来了挑战。通常在每次成像回波后采用导航仪采集来校正相位变化,这会延长扫描时间并增加比吸收率(SAR)。本研究的目的是开发一种高效的自导航方法,用于校正三维多片扩散磁共振成像中的相位变化,而无需明确采集导航器。每个镜头的采样都经过精心设计,以与每个板片的中心 kz=0 平面相交,多镜头采样经过优化,既能实现自导航性能,又能保持较好的重建质量。所有镜头的 kz=0 交点被联合用于重建每个镜头的二维相位图,采用结构化低秩约束重建,充分利用镜头和线圈维度的冗余。相位图用于消除最终三维多镜头重建中镜头间相位的不一致性。我们利用回顾性模拟和在 1.22 毫米和 1.09 毫米各向同性分辨率下进行的前瞻性活体实验证明了该方法的功效。与传统的导航式三维多平板成像相比,所提出的自导航方法可获得相当的图像质量,同时扫描时间缩短了 31.7%,信噪比效率提高了 15.5%。与传统的导航式三维多切片成像相比,该方法能以更短的扫描时间获得质量相当的 DTI 和白质束成像。
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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