3D 螺旋叠加 turbo FLASH 采集在伪连续和速度选择 ASL 衍生脑灌注成像中的评估。
Evaluation of 3D stack-of-spiral turbo FLASH acquisitions for pseudo-continuous and velocity-selective ASL-derived brain perfusion mapping.
机构信息
F.M. Kirby Research Center for Functional Brain Imaging, Kennedy Krieger Institute, Baltimore, Maryland, USA.
The Russell H. Morgan Department of Radiology and Radiological Science, Johns Hopkins University School of Medicine, Baltimore, Maryland, USA.
出版信息
Magn Reson Med. 2023 Sep;90(3):939-949. doi: 10.1002/mrm.29681. Epub 2023 May 1.
PURPOSE
The most-used 3D acquisitions for ASL are gradient and spin echo (GRASE)- and stack-of-spiral (SOS)-based fast spin echo, which require multiple shots. Alternatively, turbo FLASH (TFL) allows longer echo trains, and SOS-TFL has the potential to reduce the number of shots to even single-shot, thus improving the temporal resolution. Here we compare the performance of 3D SOS-TFL and 3D GRASE for ASL at 3T.
METHODS
The 3D SOS-TFL readout was optimized with respect to fat suppression and excitation flip angles for pseudo-continuous ASL- and velocity-selective (VS)ASL-derived cerebral blood flow (CBF) mapping as well as for VSASL-derived cerebral blood volume (CBV) mapping. Results were compared with 3D GRASE readout on healthy volunteers in terms of perfusion quantification and temporal SNR (tSNR) efficiency. CBF and CBV mapping derived from 3D SOS-TFL-based ASL was demonstrated on one stroke patient, and the potential for single-shot acquisitions was exemplified.
RESULTS
SOS-TFL with a 15° flip angle resulted in adequate tSNR efficiency with negligible image blurring. Selective water excitation was necessary to eliminate fat-induced artifacts. For pseudo-continuous ASL- and VSASL-based CBF and CBV mapping, compared to the employed four-shot 3D GRASE with an acceleration factor of 2, the fully sampled 3D SOS-TFL delivered comparable performance (with a similar scan time) using three shots, which could be further undersampled to achieve single-shot acquisition with higher tSNR efficiency. SOS-TFL had reduced CSF contamination for VSASL-CBF.
CONCLUSION
3D SOS-TFL acquisition was found to be a viable substitute for 3D GRASE for ASL with sufficient tSNR efficiency, minimal relaxation-induced blurring, reduced CSF contamination, and the potential of single-shot, especially for VSASL.
目的
动脉自旋标记(ASL)最常用的 3D 采集方式是梯度回波(GRASE)和基于堆栈螺旋(SOS)的快速自旋回波,这些采集方式需要多次激发。相比之下,涡轮 FLASH(TFL)可以允许更长的回波链,而 SOS-TFL 有可能将激发次数减少到单次,从而提高时间分辨率。本研究旨在比较 3T 下 3D SOS-TFL 和 3D GRASE 用于 ASL 的性能。
方法
我们针对 3D SOS-TFL 的读出优化了脂肪抑制和激发翻转角,以进行伪连续 ASL 和速度选择(VS)ASL 衍生的脑血流(CBF)映射,以及 VSASL 衍生的脑血容量(CBV)映射。我们在健康志愿者中比较了这两种方法在灌注定量和时间 SNR(tSNR)效率方面的表现。我们在一名脑卒中患者中展示了基于 3D SOS-TFL 的 ASL 的 CBF 和 CBV 映射,并举例说明了单次激发采集的潜力。
结果
采用 15°翻转角的 SOS-TFL 可实现足够的 tSNR 效率,同时几乎没有图像模糊。需要选择性的水激发来消除脂肪引起的伪影。对于伪连续 ASL 和 VSASL 衍生的 CBF 和 CBV 映射,与采用的 3D GRASE 相比,具有 2 倍加速因子的四激发 3D GRASE 相比,完全采样的 3D SOS-TFL 仅需三激发即可实现类似的性能(扫描时间相似),并且可以进一步欠采样以实现更高 tSNR 效率的单次激发采集。SOS-TFL 对 VSASL-CBF 的 CSF 污染较少。
结论
3D SOS-TFL 采集是 ASL 的一种可行的 3D GRASE 替代方法,具有足够的 tSNR 效率、最小的弛豫诱导模糊、减少的 CSF 污染,以及单次激发的潜力,特别是对于 VSASL。
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