Abstract
EEG source imaging enables us to reconstruct current density in the brain from the electrical measurements with excellent temporal resolution (~ ms). The corresponding EEG inverse problem is an ill-posed one that has infinitely many solutions. This is due to the fact that the number of EEG sensors is usually much smaller than that of the potential dipole locations, as well as noise contamination in the recorded signals. To obtain a unique solution, regularizations can be incorporated to impose additional constraints on the solution. An appropriate choice of regularization is critically important for the reconstruction accuracy of a brain image. In this paper, we propose a novel Sparsity and SMOOthness enhanced brain TomograpHy (s-SMOOTH) method to improve the reconstruction accuracy by integrating two recently proposed regularization techniques: Total Generalized Variation (TGV) regularization and ℓ1−2 regularization. TGV is able to preserve the source edge and recover the spatial distribution of the source intensity with high accuracy. Compared to the relevant total variation (TV) regularization, TGV enhances the smoothness of the image and reduces staircasing artifacts. The traditional TGV defined on a 2D image has been widely used in the image processing field. In order to handle 3D EEG source images, we propose a voxel-based Total Generalized Variation (vTGV) regularization that extends the definition of second-order TGV from 2D planar images to 3D irregular surfaces such as cortex surface. In addition, the ℓ1−2 regularization is utilized to promote sparsity on the current density itself. We demonstrate that ℓ1−2 regularization is able to enhance sparsity and accelerate computations than ℓ1 regularization. The proposed model is solved by an efficient and robust algorithm based on the difference of convex functions algorithm (DCA) and the alternating direction method of multipliers (ADMM). Numerical experiments using synthetic data demonstrate the advantages of the proposed method over other state-of-the-art methods in terms of total reconstruction accuracy, localization accuracy and focalization degree. The application to the source localization of event-related potential data further demonstrates the performance of the proposed method in real-world scenarios.
Highlights
Functional brain imaging techniques have been developed to evaluate brain function, e.g., memory and cognition, as well as help diagnose and treat brain disorders, e.g., epilepsy, depression, schizophrenia and Alzheimer’s disease
The neural generators of P300 remain imprecisely located, a consistent pattern of P300 sources has been shown by various techniques, such as intracranial recordings, lesion studies and functional Magnetic Resonance Imaging (fMRI)-EEG combination, that the target-related responses locate in the parietal cortex and the cingulate, with stimulus specific sources in the superior temporal cortex for the auditory stimulation and in the inferior temporal, and superior parietal cortex for the visual stimulation (Linden, 2005)
The contributions of this work are threefold: (1) a voxel-based Total Generalized Variation (vTGV) regularization is defined, which incorporates the information of higher-order derivatives, is able to enhance smoothness of the reconstructed brain image as well as reduce the staircasing artifacts; (2) a new l1−2 regularization is introduced to the EEG source imaging field for the first time, which is able to reconstruct a sparser source than the widely used l1 regularization; (3) an efficient algorithm is derived to solve the proposed model based on difference of convex functions algorithm (DCA) and alternating direction method of multipliers (ADMM)
Summary
Functional brain imaging techniques have been developed to evaluate brain function, e.g., memory and cognition, as well as help diagnose and treat brain disorders, e.g., epilepsy, depression, schizophrenia and Alzheimer’s disease. A good imaging technique needs to provide brain image of both high temporal and high spatial resolution Hemodynamic imaging techniques such as functional Magnetic Resonance Imaging (fMRI) and Positron Emission Tomography (PET) have been widely used since they offer high spatial resolution (Poldrack and Sandak, 2004). Their temporal resolution is limited on the order of seconds due to the relatively slow blood flow response (Poldrack and Sandak, 2004). Appropriate constraints could be incorporated into EEG inverse problem to improve reconstruction accuracy of the brain image
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