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动脉自旋标记在急性卒中中的应用:实际考虑因素。

Arterial spin labeling for acute stroke: practical considerations.

机构信息

Department of Radiology, Stanford University, Stanford, CA, 94305-5488, USA,

出版信息

Transl Stroke Res. 2012 Jun;3(2):228-35. doi: 10.1007/s12975-012-0159-8. Epub 2012 Apr 14.

Abstract

Arterial spin labeling (ASL) is a non-contrast method of measuring cerebral perfusion with MRI. It has several advantages over traditional contrast-based perfusion-weighted imaging, including non-invasiveness, more straightforward cerebral blood flow (CBF) quantification, and repeatability. However, because of its lower signal-to-noise ratio (SNR) per unit time and its high sensitivity to arterial transit delays, it has not been used frequently in acute stroke, where arterial delays and time-efficiency are of the essence. This is beginning to change, driven by higher SNR implementations of ASL and the increasing use of 3T scanners. Furthermore, velocity-selective ASL sequences that are largely insensitive to arrival times are beginning to be applied to patients with cerebrovascular disease and promise the ability to quantify CBF even in regions supplied by late-arriving collateral flow. Despite these advances, many practical issues must be addressed to optimize ASL for its use in acute stroke studies. These include optimizing the trade-off between time, SNR, imaging resolution, and sensitivity to slow flow. Rapid and robust post-processing of image data must be made routine, such that CBF maps are available in real time so that they can be considered when making treatment decisions. Lastly, automated software needs to be developed in order to delineate hypoperfused tissue volumes, which is challenging due to the inherent differences between gray and white matter CBF. Attention to these details is critical to translate this promising research tool into mainstream clinical trials and practice in acute stroke.

摘要

动脉自旋标记 (ASL) 是一种使用 MRI 测量脑灌注的无对比方法。与传统的基于对比的灌注加权成像相比,它具有几个优点,包括非侵入性、更直接的脑血流 (CBF) 定量和可重复性。然而,由于其单位时间的信号噪声比 (SNR) 较低,并且对动脉传输延迟高度敏感,因此在急性中风中尚未广泛应用,在急性中风中,动脉延迟和时间效率至关重要。这一情况正在发生变化,原因是 ASL 的 SNR 实施更高,以及 3T 扫描仪的使用越来越多。此外,对到达时间基本不敏感的速度选择 ASL 序列开始应用于脑血管疾病患者,有望能够量化即使在由迟来的侧支血流供应的区域中的 CBF。尽管取得了这些进展,但为了优化 ASL 在急性中风研究中的应用,仍必须解决许多实际问题。这些问题包括在时间、SNR、成像分辨率和对缓慢血流的敏感性之间进行优化权衡。必须使图像数据的快速和稳健的后处理成为常规操作,以便实时提供 CBF 图,以便在做出治疗决策时可以考虑这些图。最后,需要开发自动化软件来描绘低灌注组织体积,这由于灰质和白质 CBF 之间的固有差异而具有挑战性。关注这些细节对于将这一有前途的研究工具转化为急性中风的主流临床试验和实践至关重要。

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