利用之字形中心 ky - kz k 空间轨迹和指数重聚焦翻转角度恢复纵向磁化,实现快速非对比 MR 血管造影。

Vadim Malis, Diana Vucevic, Won C Bae, Asako Yamamoto, Yoshimori Kassai, John Lane, Albert Hsiao, Katsumi Nakamura, Mitsue Miyazaki
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引用次数: 0

摘要

目的:新鲜血液成像(FBI)利用舒张期和收缩期的生理血液信号差异,导致采集时间较长。本研究的目的是利用中心 ky - kz k 空间轨迹(cFBI)和指数再聚焦翻转角(eFA)方案,开发一种具有快速纵向恢复功能的快速 FBI 技术:本研究使用临床 3-Tesla MRI 扫描仪,在知情同意的情况下,对 8 名健康受试者和 2 名患者(外周动脉疾病和血管疾病)进行了研究。然后在腘动脉站对健康受试者进行 cFBI 采集,以评估不同的高/低翻转比对纵向恢复效果的影响。此外,由于人字形中心 ky - kz k 空间轨迹的采集窗口较长,因此对 cFBI 的触发延迟进行了优化。优化后,cFBI 图像与标准联邦调查局(sFBI)图像在扫描时间、运动伪影、奈奎斯特 N/2 伪影、模糊和整体图像质量方面进行了比较。我们还进行了双向重复测量方差分析。结果:与 sFBI 相比,采用 eFA 的 cFBI 扫描时间缩短了近 50%。180/2 度的高/低翻转角和较低的再聚焦脉冲显示出快速的纵向还原,血液信号最高,但对背景信号也更敏感。总体而言,180/30 度图像显示了合理的血液信号恢复,同时最大限度地减少了背景信号伪影。经过触发延迟优化后,收缩-舒张减影后的 cFBI 最大强度投影图像比 sFBI 的运动和 N/2 伪影更少:结论:结合用于快速纵向信号恢复的 eFA,所提出的 cFBI 技术可将扫描时间缩短 2 倍,并提高图像质量,且无重大伪影。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fast Non-contrast MR Angiography Using a Zigzag Centric ky - kz k-space Trajectory and Exponential Refocusing Flip Angles with Restoration of Longitudinal Magnetization.

Purpose: Fresh blood imaging (FBI) utilizes physiological blood signal differences between diastole and systole, causing a long acquisition time. The purpose of this study is to develop a fast FBI technique using a centric ky - kz k-space trajectory (cFBI) and an exponential refocusing flip angle (eFA) scheme with fast longitudinal restoration.

Methods: This study was performed on 8 healthy subjects and 2 patients (peripheral artery disease and vascular disease) with informed consent, using a clinical 3-Tesla MRI scanner. A numeric simulation using extended phase graph (EPG) and phantom studies of eFA were carried out to investigate the restoration of longitudinal signal by lowering refocusing flip angles in later echoes. cFBI was then acquired on healthy subjects at the popliteal artery station to assess the effect of varying high/low flip ratios on the longitudinal restoration effects. In addition, trigger-delays of cFBI were optimized owing to the long acquisition window in zigzag centric ky - kz k-space trajectory. After optimizations, cFBI images were compared against standard FBI (sFBI) images in terms of scan time, motion artifacts, Nyquist N/2 artifacts, blurring, and overall image quality. We also performed two-way repeated measures analysis of variance.

Results: cFBI with eFA achieved nearly a 50% scan time reduction compared to sFBI. The high/low flip angle of 180/2 degrees with lower refocusing pulses shows fast longitudinal restoration with the highest blood signals, yet also more sensitive to the background signals. Overall, 180/30 degrees images show reasonable blood signal recovery while minimizing the background signal artifacts. After the trigger delay optimization, maximum intensity projection image of cFBI after systole-diastole subtraction demonstrates less motion and N/2 artifacts than that of sFBI.

Conclusion: Together with eFA for fast longitudinal signal restoration, the proposed cFBI technique achieved a 2-fold reduction in scan time and improved image quality without major artifacts.

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