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利用结构磁共振成像对人体初级听觉皮层进行体内定位。

Localizing the human primary auditory cortex in vivo using structural MRI.

机构信息

Special-Lab Non-Invasive Brain Imaging, Leibniz-Institute for Neurobiology Magdeburg, Germany.

Special-Lab Non-Invasive Brain Imaging, Leibniz-Institute for Neurobiology Magdeburg, Germany.

出版信息

Neuroimage. 2014 Jun;93 Pt 2:237-51. doi: 10.1016/j.neuroimage.2013.07.046. Epub 2013 Jul 25.

DOI:10.1016/j.neuroimage.2013.07.046
PMID:23891882
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3902056/
Abstract

Currently there are no routine methods to delineate the primary auditory cortex (PAC) of humans in vivo. Due to the large differences in the location of the PAC between subjects, labels derived from post-mortem brains may be inaccurate when applied to different samples of in vivo brains. Recent magnetic resonance (MR) imaging studies suggested that MR-tissue properties can be used to define the location of the PAC region in vivo. The basis for such an approach is that the PAC region is more strongly myelinated than the secondary areas. We developed a fully automatic method to identify the PAC in conventional anatomical data using a combination of two complementary MR contrasts, i.e., T1 and T2, at 3T with 0.7mm isotropic resolution. Our algorithm maps the anatomical MR data to reconstructed cortical surfaces and uses a classification approach to create an artificial contrast that is highly sensitive to the effects of an increased myelination of the cortex. Consistent with the location of the PAC defined in post-mortem brains, we found a compact region on the medial two thirds of Heschl's gyrus in both hemispheres of all 39 subjects. With further improvements in signal-to-noise ratio of the anatomical data and manual correction of segmentation errors, the results suggest that the primary auditory cortex can be defined in the living brain of single subjects.

摘要

目前,尚无常规方法可在活体中描绘人类的初级听觉皮层 (PAC)。由于 PAC 在不同个体之间的位置存在很大差异,因此从死后大脑中得出的标签在应用于不同的活体大脑样本时可能不准确。最近的磁共振 (MR) 成像研究表明,MR 组织特性可用于在活体中定义 PAC 区域的位置。这种方法的基础是 PAC 区域比次要区域具有更强的髓鞘化。我们开发了一种全自动方法,可在 3T 下使用两种互补的 MR 对比(即 T1 和 T2),以 0.7mm 各向同性分辨率,在常规解剖数据中识别 PAC。我们的算法将解剖 MR 数据映射到重建的皮质表面,并使用分类方法创建一种人工对比,该对比对皮质髓鞘化增加的影响高度敏感。与死后大脑中定义的 PAC 位置一致,我们在所有 39 个受试者的每个半球的 Heschl 回的内三分之二处都发现了一个紧凑的区域。随着解剖数据信噪比的进一步提高以及对分割错误的手动校正,结果表明可以在单个受试者的活体大脑中定义初级听觉皮层。

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