Center for Biomedical Imaging, Medical University of South Carolina, Charleston, South Carolina.
Department of Neuroscience, Medical University of South Carolina, Charleston, South Carolina.
Magn Reson Med. 2019 May;81(5):2985-2994. doi: 10.1002/mrm.27617. Epub 2018 Dec 2.
To demonstrate how the T relaxation time of intra-axonal water (T ) in white matter can be measured with direction-averaged diffusion MRI.
For b-values larger than about 4000 s/mm , the direction-averaged diffusion MRI signal from white matter is dominated by the contribution from water within axons, which enables T to be estimated by acquiring data for multiple TE values and fitting a mono-exponential decay curve. If given a value of the intra-axonal diffusivity, an extension of the method allows the extra-axonal relaxation time (T ) to be calculated also. This approach was applied to estimate T in white matter for 3 healthy subjects at 3 T, as well as T for a selected set of assumed intra-axonal diffusivities.
The estimated T values ranged from about 50 ms to 110 ms, with considerable variation among white matter regions. For white matter tracts with primarily collinear fibers, T was found to depend on the angle of the tract relative to the main magnetic field, which is consistent with T being affected by magnetic field inhomogeneities arising from spatial differences in magnetic susceptibility. The T values were significantly smaller than the T values across white matter regions for several plausible choices of the intra-axonal diffusivity.
The relaxation time for intra-axonal water in white matter can be determined in a straightforward manner by measuring the direction-averaged diffusion MRI signal with a large b-value for multiple TEs. In healthy brain, T is greater than T and varies considerably with anatomical region.
展示如何通过各向同性平均扩散 MRI 测量轴内水的 T 弛豫时间(T )。
对于大于约 4000 s/mm 的 b 值,来自白质的各向同性平均扩散 MRI 信号主要由轴内水的贡献主导,这使得可以通过获取多个 TE 值的数据并拟合单指数衰减曲线来估计 T 。如果给定轴内扩散率的值,该方法的扩展还允许计算细胞外弛豫时间(T )。该方法应用于在 3T 下对 3 名健康受试者的白质进行 T 估计,以及对一组假定的轴内扩散率进行 T 估计。
估计的 T 值范围约为 50ms 至 110ms,不同白质区域之间存在相当大的差异。对于主要具有共线纤维的白质束,发现 T 取决于束相对于主磁场的角度,这与 T 受来自空间磁化率差异的磁场不均匀性影响一致。对于几个合理选择的轴内扩散率,T 值明显小于跨白质区域的 T 值。
通过对多个 TE 值的大 b 值测量各向同性平均扩散 MRI 信号,可以以直接的方式确定白质中轴内水的弛豫时间。在健康大脑中,T 大于 T ,并且随解剖区域变化很大。
