磁化率诱导的白质磁共振信号频率偏移——洛伦兹球体与广义洛伦兹方法的实验比较

Magnetic susceptibility induced white matter MR signal frequency shifts--experimental comparison between Lorentzian sphere and generalized Lorentzian approaches.

作者信息

Luo J, He X, Yablonskiy D A

机构信息

Department of Radiology, Washington University, St. Louis, Missouri, USA.

出版信息

Magn Reson Med. 2014 Mar;71(3):1251-63. doi: 10.1002/mrm.24762.

DOI:10.1002/mrm.24762

PMID:23637001

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3748237/

Abstract

PURPOSE

The nature of the remarkable phase contrast in high-field gradient echo MRI studies of human brain is a subject of intense debates. The generalized Lorentzian approach (He and Yablonskiy, Proc Natl Acad Sci USA 2009;106:13558-13563) provides an explanation for the anisotropy of phase contrast, the near absence of phase contrast between white matter and cerebrospinal fluid, and changes of phase contrast in multiple sclerosis. In this study, we experimentally validate the generalized Lorentzian approach.

THEORY AND METHODS

The Generalized Lorentzian Approach suggests that the local contribution to frequency shifts in white matter does not depend on the average tissue magnetic susceptibility (as suggested by Lorentzian sphere approximation), but on the distribution and symmetry of magnetic susceptibility inclusions at the cellular level. We use ex vivo rat optic nerve as a model system of highly organized cellular structure containing longitudinally arranged myelin and neurofilaments. The nerve's cylindrical shape allowed accurate measurement of its magnetic susceptibility and local frequency shifts.

RESULTS

We found that the volume magnetic susceptibility difference between nerve and water is -0.116 ppm, and the magnetic susceptibilities of longitudinal components are -0.043 ppm in fresh nerve, and -0.020 ppm in fixed nerve.

CONCLUSION

The frequency shift observed in the optic nerve as a representative of white matter is consistent with generalized Lorentzian approach but inconsistent with Lorentzian sphere approximation.

摘要

目的

在人脑的高场梯度回波磁共振成像研究中，显著的相位对比的本质是一个激烈争论的主题。广义洛伦兹方法（He和Yablonskiy，《美国国家科学院院刊》2009年；106:13558 - 13563）为相位对比的各向异性、白质与脑脊液之间几乎不存在相位对比以及多发性硬化中相位对比的变化提供了解释。在本研究中，我们通过实验验证广义洛伦兹方法。

理论与方法

广义洛伦兹方法表明，白质中对频移的局部贡献并不取决于平均组织磁化率（如洛伦兹球体近似所暗示的那样），而是取决于细胞水平上磁化率内含物的分布和对称性。我们使用离体大鼠视神经作为高度组织化细胞结构的模型系统，该结构包含纵向排列的髓磷脂和神经丝。神经的圆柱形形状使得能够准确测量其磁化率和局部频移。

结果

我们发现神经与水之间的体积磁化率差异为 - 0.116 ppm，新鲜神经中纵向成分的磁化率为 - 0.043 ppm，固定神经中为 - 0.020 ppm。

结论

作为白质代表的视神经中观察到的频移与广义洛伦兹方法一致，但与洛伦兹球体近似不一致。

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