A new method to derive white matter conductivity from diffusion tensor MRI

Kun Wang; Shanan Zhu; Bryon A. Mueller; Kelvin O. Lim; Zhongming Liu; Bin He

doi:10.1109/TBME.2008.923159

A new method to derive white matter conductivity from diffusion tensor MRI

Kun Wang, Shanan Zhu, Bryon A. Mueller, Kelvin O. Lim, Zhongming Liu, Bin He

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33 Scopus citations

Abstract

We propose a new algorithm to derive the anisotropic conductivity of the cerebral white matter (WM) from the diffusion tensor MRI (DT-MRI) data. The transportation processes for both water molecules and electrical charges are described through a common multicompartment model that consists of axons, glia, or the cerebrospinal fluid (CSF). The volume fraction (VF) of each compartment varies from voxel to voxel and is estimated from the measured diffusion tensor. The conductivity tensor at each voxel is then computed from the estimated VF values and the decomposed eigenvectors of the diffusion tensor. The proposed VF algorithm was applied to the DT-MRI data acquired from two healthy human subjects. The extracted anisotropic conductivity distribution was compared with those obtained by using two existing algorithms, which were based upon a linear conductivity-to-diffusivity relationship and a volume constraint, respectively. The present results suggest that the VF algorithm is capable of incorporating the partial volume effects of the CSF and the intravoxel fiber crossing structure, both of which are not addressed altogether by existing algorithms. Therefore, it holds potential to provide a more accurate estimate of the WM anisotropic conductivity, and may have important applications to neuroscience research or clinical applications in neurology and neurophysiology.

Original language	English (US)
Article number	21
Pages (from-to)	2481-2486
Number of pages	6
Journal	IEEE Transactions on Biomedical Engineering
Volume	55
Issue number	10
DOIs	https://doi.org/10.1109/TBME.2008.923159
State	Published - Oct 2008

Bibliographical note

Funding Information:
Manuscript received August 15, 2007; revised November 18, 2007. First published June 10, 2008; current version published September 26, 2008. This work was supported in part by the National Institutes of Health under Grant RO1EB007920, Grant RO1EB00178, and Grant R21EB006070, in part by the National Science Foundation under Grant BES-0411898, Grant BES-0602957, and Grant NSFC-50577055, and in part by a grant from the Institute for Engineering in Medicine (IEM), University of Minnesota, Minneapolis. Asterisk indicates corresponding author.

Keywords

Anisotropy
Diffusion tensor MRI (DT-MRI)
Electrical conductivity
Intravoxel fiber crossing
Partial volume effects
White matter (WM)

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title = "A new method to derive white matter conductivity from diffusion tensor MRI",

abstract = "We propose a new algorithm to derive the anisotropic conductivity of the cerebral white matter (WM) from the diffusion tensor MRI (DT-MRI) data. The transportation processes for both water molecules and electrical charges are described through a common multicompartment model that consists of axons, glia, or the cerebrospinal fluid (CSF). The volume fraction (VF) of each compartment varies from voxel to voxel and is estimated from the measured diffusion tensor. The conductivity tensor at each voxel is then computed from the estimated VF values and the decomposed eigenvectors of the diffusion tensor. The proposed VF algorithm was applied to the DT-MRI data acquired from two healthy human subjects. The extracted anisotropic conductivity distribution was compared with those obtained by using two existing algorithms, which were based upon a linear conductivity-to-diffusivity relationship and a volume constraint, respectively. The present results suggest that the VF algorithm is capable of incorporating the partial volume effects of the CSF and the intravoxel fiber crossing structure, both of which are not addressed altogether by existing algorithms. Therefore, it holds potential to provide a more accurate estimate of the WM anisotropic conductivity, and may have important applications to neuroscience research or clinical applications in neurology and neurophysiology.",

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A new method to derive white matter conductivity from diffusion tensor MRI

Abstract

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Keywords

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