在 9.4T 下测量动脉自旋标记信号的双指数横向弛豫,以估计动脉血氧饱和度和标记血水中的水进入皮质脑组织的交换时间。
Measuring biexponential transverse relaxation of the ASL signal at 9.4 T to estimate arterial oxygen saturation and the time of exchange of labeled blood water into cortical brain tissue.
机构信息
Division of Medicine and Institute of Child Health, UCL Centre for Advanced Biomedical Imaging, University College London, London, UK.
出版信息
J Cereb Blood Flow Metab. 2013 Feb;33(2):215-24. doi: 10.1038/jcbfm.2012.156. Epub 2012 Nov 21.
Abstract
The transverse decay of the arterial spin labeling (ASL) signal was measured at four inflow times in the rat brain cortex at 9.4 T. Biexponential T2 decay was observed that appears to derive from different T2 values associated with labeled water in the intravasculature (IV) and extravascular (EV) compartments. A two compartment biexponential model was used to assess the relative contribution of the IV and EV compartments to the ASL signal, without assuming a value for T2 of labeled blood water in the vessels. This novel methodology was applied to estimate the exchange time of blood water into EV tissue space and the oxygen saturation of blood on the arterial side of the vasculature. The mean exchange time of labeled blood water was estimated to be 370±40 ms. The oxygen saturation of the arterial side of the vasculature was significantly less than 100% (∼85%), which may have implications for quantitative functional magnetic resonance imaging studies where the arterial oxygen saturation is frequently assumed to be 100%.
摘要
在 9.4T 下,对大鼠大脑皮层的四个流入时间的动脉自旋标记 (ASL) 信号的横向衰减进行了测量。观察到双指数 T2 衰减,似乎源自血管内 (IV) 和血管外 (EV) 腔室内标记水的不同 T2 值。使用双指数双室模型来评估 IV 和 EV 腔室对 ASL 信号的相对贡献,而无需假设血管中标记血水中的 T2 值。该新方法应用于估计血水中 EV 组织空间的交换时间和血管侧血液的氧饱和度。标记血水中的平均交换时间估计为 370±40ms。血管侧的氧饱和度明显低于 100%(约 85%),这可能对定量功能磁共振成像研究有影响,其中动脉氧饱和度通常假定为 100%。
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