Abstract
Diffusion-weighted magnetic resonance imaging is a non-invasive imaging method that has been increasingly used in neuroscience imaging over the last decade. Partial volume effects (PVEs) exist in sampling signal for many physical and actual reasons, which lead to inaccurate fiber imaging. We overcome the influence of PVEs by separating isotropic signal from diffusion-weighted signal, which can provide more accurate estimation of fiber orientations. In this work, we use a novel response function (RF) and the correspondent fiber orientation distribution function (fODF) to construct different signal models, in which case the fODF is represented using dictionary basis function. We then put forward a new index Piso, which is a part of fODF to quantify white and gray matter. The classic Richardson-Lucy (RL) model is usually used in the field of digital image processing to solve the problem of spherical deconvolution caused by highly ill-posed least-squares algorithm. In this case, we propose an innovative model integrating RL model with spatial regularization to settle the suggested double-models, which improve noise resistance and accuracy of imaging. Experimental results of simulated and real data show that the proposal method, which we call iRL, can robustly reconstruct a more accurate fODF and the quantitative index Piso performs better than fractional anisotropy and general fractional anisotropy.
Highlights
Magnetic resonance imaging (MRI) can offer important insights into brain disease [1]
We focus on Partial volume effects (PVEs) in the reconstruction of fiber configuration, which rarely elicit interest of researchers
We usually utilize the anisotropic signal to reconstruct fiber orientation, which is affected by the isotropic signal
Summary
Magnetic resonance imaging (MRI) can offer important insights into brain disease [1]. Diffusion-weighted MRI (DW-MRI) can provide a unique, non-invasive technique to study the microscopic structure of brain white matter (WM) in vivo [2,3,4]. DW-MRI provides valuable information about the fiber architecture of tissue by measuring the diffusion of water in three-dimensional space [5, 6]. An early form of this technique, i.e., diffusion tensor imaging (DTI) [7], is widely used in clinics and provides fiber orientations of WM based on principal eigenvector of that tensor [8] and many useful quantitative indexes, including mean diffusivity (MD), fractional anisotropy (FA) [9, 10], and so on. The major shortcoming of the PLOS ONE | DOI:10.1371/journal.pone.0168864 January 12, 2017
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