具有轴对称性和可变各向异性的核磁共振扩散编码:区分取向分布未知的长形和扁形微观扩散张量。
NMR diffusion-encoding with axial symmetry and variable anisotropy: Distinguishing between prolate and oblate microscopic diffusion tensors with unknown orientation distribution.
作者信息
Eriksson Stefanie, Lasič Samo, Nilsson Markus, Westin Carl-Fredrik, Topgaard Daniel
机构信息
Division of Physical Chemistry, Department of Chemistry, Lund University, Lund, Sweden.
CR Development AB, Lund, Sweden.
出版信息
J Chem Phys. 2015 Mar 14;142(10):104201. doi: 10.1063/1.4913502.
Abstract
We introduce a nuclear magnetic resonance method for quantifying the shape of axially symmetric microscopic diffusion tensors in terms of a new diffusion anisotropy metric, DΔ, which has unique values for oblate, spherical, and prolate tensor shapes. The pulse sequence includes a series of equal-amplitude magnetic field gradient pulse pairs, the directions of which are tailored to give an axially symmetric diffusion-encoding tensor b with variable anisotropy bΔ. Averaging of data acquired for a range of orientations of the symmetry axis of the tensor b renders the method insensitive to the orientation distribution function of the microscopic diffusion tensors. Proof-of-principle experiments are performed on water in polydomain lyotropic liquid crystals with geometries that give rise to microscopic diffusion tensors with oblate, spherical, and prolate shapes. The method could be useful for characterizing the geometry of fluid-filled compartments in porous solids, soft matter, and biological tissues.
摘要
我们介绍了一种核磁共振方法,用于根据一种新的扩散各向异性度量DΔ来量化轴对称微观扩散张量的形状,该度量对于扁长形、球形和长形张量形状具有独特的值。脉冲序列包括一系列等幅磁场梯度脉冲对,其方向经过调整,以产生具有可变各向异性bΔ的轴对称扩散编码张量b。对张量b对称轴的一系列方向采集的数据进行平均,使得该方法对微观扩散张量的方向分布函数不敏感。在多畴溶致液晶中的水上进行了原理验证实验,这些液晶的几何形状会产生具有扁长形、球形和长形形状的微观扩散张量。该方法可用于表征多孔固体、软物质和生物组织中充满流体的隔室的几何形状。
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