Anisotropy of spin-echo T2 relaxation by magnetic resonance imaging in the human brain in vivo

IF 0.3 Q4 SPECTROSCOPY Biomedical Spectroscopy and Imaging Pub Date : 2015-06-30 DOI:10.3233/BSI-150114

Michael J. Knight, B. Wood, Elizabeth Couthard, R. Kauppinen

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引用次数: 34

Abstract

BACKGROUND: The use of T2 relaxation contrast, as measured by MRI, is particularly commonplace in non-invasive assessment of the brain. However, the mechanisms and uses of T2 relaxation in the brain are still not fully understood. The hypothesis that T2 relaxation may show anisotropy in the human brain was studied at 3 T. T2 anisotropy refers to the variation of T2 in ordered structures with respect to the direction of the applied magnetic field. METHODS: Using a 3 T clinical MRI scanner, we made quantitative multi-contrast spin-echo T2 and diffusion tensor imaging (DTI) measurements in healthy volunteers, repeating the measurements with the subject’s head oriented differently relative to the applied field, for the measurement of possible spin-echo T2 anisotropy. RESULTS: We report T2 relaxation anisotropy measurements and present a means for visualising it according to the principal orientation of ordered structures in the brain parenchyma. We introduce a parameter for the model-free description of T2 anisotropy, namely the T2 “fractional anisotropy”, similar to that used to describe anisotropy of translational diffusion. This parameterisation enables the overall level of anisotropy in T2 across a chosen region or tissue to be calculated. Anisotropic T2 relaxation was observed in both gray and white matter, though to a greater extent in the latter, with a strong relationship with the anisotropy of translational diffusion. This is evidenced by making repeat measurements with the subject’s head tilted to different angles relative to the applied magnetic field, by which means we observed the T2 at the same anatomical site to change. CONCLUSIONS: Relaxation anisotropy has a significant effect on T2 in the brain parenchyma. It has the potential to offer non-invasive access to tissue microstructure not available by other imaging modalities, and may be sensitive to pathology or noxious factors not detected by other means.

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活体人脑磁共振成像自旋回波T2弛豫的各向异性

背景:使用磁共振成像测量的T2松弛对比，在对大脑的非侵入性评估中尤其普遍。然而，大脑中T2松弛的机制和用途仍未完全了解。T2各向异性是指T2在有序结构中随外加磁场方向的变化。方法:使用3t临床MRI扫描仪，对健康志愿者进行定量多对比自旋回波T2和扩散张量成像(DTI)测量，在受试者头部相对于应用场的不同方向重复测量，以测量可能的自旋回波T2各向异性。结果:我们报告了T2弛豫各向异性的测量结果，并根据脑实质中有序结构的主要方向提出了一种可视化方法。我们引入了一个参数用于T2各向异性的无模型描述，即T2“分数各向异性”，类似于用于描述平移扩散各向异性的参数。这种参数化使T2在选定区域或组织中的各向异性总体水平得以计算。在灰质和白质中均观察到各向异性T2弛豫，但后者的弛豫程度更大，与平动扩散的各向异性有很强的关系。这是通过重复测量受试者的头部相对于外加磁场倾斜不同角度来证明的，通过这意味着我们观察到T2在同一解剖部位的变化。结论:松弛各向异性对脑实质T2有显著影响。它具有提供其他成像方式无法获得的非侵入性组织微观结构的潜力，并且可能对其他方法无法检测到的病理或有害因素敏感。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Biomedical Spectroscopy and Imaging SPECTROSCOPY-

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期刊介绍： Biomedical Spectroscopy and Imaging (BSI) is a multidisciplinary journal devoted to the timely publication of basic and applied research that uses spectroscopic and imaging techniques in different areas of life science including biology, biochemistry, biotechnology, bionanotechnology, environmental science, food science, pharmaceutical science, physiology and medicine. Scientists are encouraged to submit their work for publication in the form of original articles, brief communications, rapid communications, reviews and mini-reviews. Techniques covered include, but are not limited, to the following: • Vibrational Spectroscopy (Infrared, Raman, Teraherz) • Circular Dichroism Spectroscopy • Magnetic Resonance Spectroscopy (NMR, ESR) • UV-vis Spectroscopy • Mössbauer Spectroscopy • X-ray Spectroscopy (Absorption, Emission, Photoelectron, Fluorescence) • Neutron Spectroscopy • Mass Spectroscopy • Fluorescence Spectroscopy • X-ray and Neutron Scattering • Differential Scanning Calorimetry • Atomic Force Microscopy • Surface Plasmon Resonance • Magnetic Resonance Imaging • X-ray Imaging • Electron Imaging • Neutron Imaging • Raman Imaging • Infrared Imaging • Terahertz Imaging • Fluorescence Imaging • Near-infrared spectroscopy.