使用 DT-MREIT 对人体头部进行低频电导率张量成像的体内研究:初步研究。
Low-Frequency Conductivity Tensor Imaging of the Human Head In Vivo Using DT-MREIT: First Study.
出版信息
IEEE Trans Med Imaging. 2018 Apr;37(4):966-976. doi: 10.1109/TMI.2017.2783348.
Abstract
We present the first in vivo images of anisotropic conductivity distribution in the human head, measured at a frequency of approximately 10 Hz. We used magnetic resonance electrical impedance tomography techniques to encode phase changes caused by current flow within the head via two independent electrode pairs. These results were then combined with diffusion tensor imaging data to reconstruct full anisotropic conductivity distributions in 5-mm-thick slices of the brains of two participants. Conductivity values recovered in this paper were broadly consistent with literature values. We anticipate that this technique will be of use in many areas of neuroscience, most importantly in functional imaging via inverse electroencephalogram. Future studies will involve pulse sequence acceleration to maximize brain coverage and resolution.
摘要
我们展示了在约 10 Hz 的频率下,人体头部各向异性电导率分布的首次体内图像。我们使用磁共振电阻抗断层成像技术,通过两对独立的电极对,对头部内电流产生的相位变化进行编码。然后,我们将这些结果与扩散张量成像数据相结合,重建了两名参与者大脑中 5 毫米厚切片的全各向异性电导率分布。本文中恢复的电导率值与文献值基本一致。我们预计,这项技术将在神经科学的许多领域得到应用,特别是在通过反向脑电图进行功能成像方面。未来的研究将涉及脉冲序列加速,以最大限度地提高大脑的覆盖范围和分辨率。
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