Comparisons of MR and EM inferred tissue microstructure properties using a human autopsy corpus callosum sample

IF 2.1 4区 医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Emma Friesen , Rubeena Gosal , Sheryl Herrera , Morgan Mercredi , Richard Buist , Kant Matsuda , Melanie Martin
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引用次数: 0

Abstract

Degeneration of white matter (WM) microstructure in the central nervous system is characteristic of many neurodegenerative conditions. Previous research indicates that axonal degeneration visible in ex vivo electron microscopy (EM) photomicrographs precede the onset of clinical symptoms. Measuring WM microstructural features, such as axon diameter and packing fraction, currently require these highly invasive methods of analysis and it is therefore of great importance to develop methods for in vivo measurements. Diffusion weighted Magnetic Resonance Imaging (MRI) is a non-invasive method which can be used in conjunction with temporal diffusion spectroscopy (TDS) and an oscillating gradient spin echo (OGSE) pulse sequence to probe micron-scale structures within neural tissue. The current experiment aims to compare axon diameter measurements, mean effective axon diameter (AxD¯), and packing fractions calculated from EM histopathological analysis and inferred values from MR images. Mathematical models of axon diameters used for analysis include the ActiveAx Frequency-Dependent Extra-Axonal Diffusion (AAD) model and the AxCaliber Frequency-Dependent Extra-Axonal Diffusion (ACD) model using ROI (Region of Interest) based analysis (RBA) and voxel-based analysis (VBA), respectively. Overall, it was observed that MRI inferred WM microstructural parameters overestimate those calculated from EM. This may be attributable to tissue shrinkage during EM dehydration, the sensitivity of MR pulse sequences to larger diameter axons, and/or inaccurate model assumptions. The results of the current study provide a means to characterize the precision and accuracy of RBA-ACD and VBA-AAD OGSE-TDS and highlight the need for further research investigating the relationship between ex vivo MRI and EM, with the goal of reaching in vivo MRI.
使用人体尸检胼胝体样本比较磁共振和电磁波推断的组织微观结构特性。
中枢神经系统白质(WM)微结构的退化是许多神经退行性疾病的特征。以往的研究表明,体内外电子显微镜(EM)显微照片显示的轴突变性先于临床症状的出现。目前,测量轴突直径和堆积分数等 WM 显微结构特征需要这些高侵入性的分析方法,因此开发体内测量方法具有重要意义。弥散加权磁共振成像(MRI)是一种非侵入性方法,可与时间弥散光谱(TDS)和振荡梯度自旋回波(OGSE)脉冲序列结合使用,探测神经组织内的微米级结构。目前的实验旨在比较轴突直径测量值、平均有效轴突直径(AxD¯)和EM组织病理学分析计算出的堆积分数,以及核磁共振图像的推断值。用于分析的轴突直径数学模型包括ActiveAx频率依赖性轴外扩散(AAD)模型和AxCaliber频率依赖性轴外扩散(ACD)模型,分别使用基于ROI(感兴趣区)的分析(RBA)和基于体素的分析(VBA)。总体而言,MRI推断出的WM微结构参数高估了EM计算出的参数。这可能是由于电磁脱水过程中组织收缩、磁共振脉冲序列对直径较大轴突的敏感性和/或模型假设不准确造成的。目前的研究结果为描述RBA-ACD和VBA-AAD OGSE-TDS的精确度和准确性提供了一种方法,并强调了进一步研究体内外核磁共振成像和电磁波之间关系的必要性,其目标是达到体内核磁共振成像的水平。
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来源期刊
Magnetic resonance imaging
Magnetic resonance imaging 医学-核医学
CiteScore
4.70
自引率
4.00%
发文量
194
审稿时长
83 days
期刊介绍: Magnetic Resonance Imaging (MRI) is the first international multidisciplinary journal encompassing physical, life, and clinical science investigations as they relate to the development and use of magnetic resonance imaging. MRI is dedicated to both basic research, technological innovation and applications, providing a single forum for communication among radiologists, physicists, chemists, biochemists, biologists, engineers, internists, pathologists, physiologists, computer scientists, and mathematicians.
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