Liu Thomas T, Chen Conan, Guo Jia, Wong Eric C, Bolar Divya S
Center for Functional MRI, University of California San Diego, La Jolla, California, USA.
Department of Radiology, University of California San Diego, La Jolla, California, USA.
Magn Reson Med. 2024 Dec;92(6):2520-2534. doi: 10.1002/mrm.30248. Epub 2024 Aug 19.
To develop a generalized signal model for dual-module velocity-selective arterial spin labeling (dm-VSASL) that can integrate arbitrary saturation and inversion profiles.
A recently developed mathematical framework for single-module VSASL is extended to address the increased complexity of dm-VSASL and to model the use of realistic velocity-selective profiles in the label-control and vascular crushing modules. Expressions for magnetization difference, arterial delivery functions, labeling efficiency, and cerebral blood flow (CBF) estimation error are presented. Sources of error are examined and timing requirements to minimize quantification errors are derived.
For ideal velocity-selective profiles, the predicted signals match those of prior work. With realistic profiles, a CBF-dependent estimation error can occur when velocity-selective inversion (VSI) is used for the labeling modules and velocity-selective saturation (VSS) is used for the vascular crushing module. The error reflects a mismatch between the leading and trailing edges of the delivery function for the second bolus and can be minimized by choosing a nominal labeling cutoff velocity that is lower than the nominal saturation cutoff velocity. In the presence of and inhomogeneities, the labeling efficiency of dual-module VSI is more attenuated than that of dual-module VSS.
The proposed signal model will enable researchers to more accurately assess and compare the performance of realistic dm-VSASL implementations and improve the quantification of dm-VSASL CBF measures.
建立一种用于双模块速度选择性动脉自旋标记(dm-VSASL)的通用信号模型,该模型能够整合任意的饱和与反转分布。
将最近开发的单模块VSASL数学框架进行扩展,以应对dm-VSASL增加的复杂性,并对标记控制模块和血管压碎模块中实际速度选择性分布的使用进行建模。给出了磁化强度差、动脉血供函数、标记效率和脑血流量(CBF)估计误差的表达式。研究了误差来源,并推导了使量化误差最小化的时间要求。
对于理想的速度选择性分布,预测信号与先前工作的信号相匹配。对于实际分布,当标记模块使用速度选择性反转(VSI)且血管压碎模块使用速度选择性饱和(VSS)时,可能会出现与CBF相关的估计误差。该误差反映了第二次团注血供函数前后沿之间的不匹配,通过选择低于标称饱和截止速度的标称标记截止速度可将其最小化。在存在 和 不均匀性的情况下,双模块VSI的标记效率比双模块VSS的标记效率衰减更严重。
所提出的信号模型将使研究人员能够更准确地评估和比较实际dm-VSASL实现方式的性能,并改善dm-VSASL CBF测量的量化。
