Gorter Center for High-Field MRI, Department of Radiology, Leiden University Medical Center, Leiden, Netherlands.
Leiden Institute for Brain and Cognition, Leiden, Netherlands.
Magn Reson Med. 2021 May;85(5):2649-2660. doi: 10.1002/mrm.28613. Epub 2020 Nov 30.
Arterial spin labeling can be used to assess the transition time of water molecules across the blood-brain barrier when combined with sequence modules, which allow a separation of intravascular from tissue signal. The bipolar gradient technique measures the intravascular fraction by removing flowing spins. The T -relaxation-under-spin-tagging (TRUST) technique modulates the TE to differentiate between intravascular and extravascular spins based on T . These modules were combined into a single time-encoded pseudo-continuous arterial spin labeling sequence to compare their mechanisms of action as well as their assessment of water transition across the blood-brain barrier.
This protocol was acquired on a scanner with 9 healthy volunteers who provided written, informed consent. The sequence consisted of a Hadamard-encoded pseudo-continuous arterial spin labeling module, followed by the TRUST module (effective TEs of 0, 40, and 80 ms) and bipolar flow-crushing gradients (2, 4, and ∞ cm/s). An additional experiment was performed with TRUST and a 3D gradient and spin-echo readout.
Gradients imperfectly canceled the intravascular signal, as evidenced by the presence of residual signal in the arteries at early postlabeling delays as well as the underestimation of the intravascular fraction as compared with the TRUST method. The TRUST module allowed us to detect the transport of water deeper into the vascular tree through changes in T than the used crusher gradients could, with their limited b-value.
Of the implemented techniques, TRUST allowed us to follow intravascular signal deeper into the vascular tree than the approach with (relatively weak) crusher gradients when quantifying the transport time of water across the blood-brain barrier.
动脉自旋标记可与序列模块结合使用,以评估水分子穿过血脑屏障的过渡时间,这些序列模块允许将血管内信号与组织信号分离。双极梯度技术通过去除流动的自旋来测量血管内分数。T-松弛标记下的自旋(TRUST)技术通过调制 TE 基于 T 来区分血管内和血管外自旋。这些模块被组合到单个时间编码的伪连续动脉自旋标记序列中,以比较它们的作用机制以及它们对水穿过血脑屏障的过渡的评估。
该方案是在一台配备 9 名健康志愿者的扫描仪上获取的,志愿者提供了书面知情同意书。该序列由 Hadamard 编码的伪连续动脉自旋标记模块组成,随后是 TRUST 模块(有效 TE 为 0、40 和 80 ms)和双极流动粉碎梯度(2、4 和∞cm/s)。还进行了一项额外的实验,使用 TRUST 和 3D 梯度和自旋回波读出。
梯度不能完全消除血管内信号,这表现为在标记后早期残留的信号出现在动脉中,以及与 TRUST 方法相比,血管内分数被低估。TRUST 模块使我们能够通过 T 的变化检测到水更深地进入血管树的运输,而梯度的 b 值有限。
在所实施的技术中,与使用(相对较弱)粉碎梯度的方法相比,TRUST 允许我们在量化水穿过血脑屏障的传输时间时,将血管内信号更深地追踪到血管树中。
