Noninvasive electromagnetic source imaging of spatiotemporally distributed epileptogenic brain sources

Sohrabpour, Abbas; Cai, Zhengxiang; Ye, Shuai; Brinkmann, Benjamin H.; Worrell, Gregory A.; He, Bin

doi:10.1038/s41467-020-15781-0

Cited by 69 publications

(73 citation statements)

References 69 publications

(90 reference statements)

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“…Second, the source imaging analysis of pHFOs can provide estimation of the underlying EZ in individual patients with focal epilepsy, which could further facilitate in planning for surgical intervention, such as resection or neuromodulation, and provide evaluation of the treatment outcomes. Third, our results raise the possibility of accurately investigating epilepsy without having to record seizures, which is resource consuming and prone to induce additional risks of secondary generalization due to medication reduction or cessation for prolonged video-monitoring prior to neurosurgery (89). Together, our findings suggest that the utility of concurrent HFOs with spikes in scalp recordings is highly desirable, which might be a critical resource for clinical translation in numerous patients and extend the application from presurgical diagnosis to monitoring of disease severity, tracking therapeutic progress, and providing postsurgical evaluation in vulnerable patient populations.…”

Section: Discussionmentioning

confidence: 97%

Noninvasive high-frequency oscillations riding spikes delineates epileptogenic sources

Cai

Sohrabpour

Jiang

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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High-frequency oscillations (HFOs) are a promising biomarker for localizing epileptogenic brain and guiding successful neurosurgery. However, the utility and translation of noninvasive HFOs, although highly desirable, is impeded by the difficulty in differentiating pathological HFOs from nonepileptiform high-frequency activities and localizing the epileptic tissue using noninvasive scalp recordings, which are typically contaminated with high noise levels. Here, we show that the consistent concurrence of HFOs with epileptiform spikes (pHFOs) provides a tractable means to identify pathological HFOs automatically, and this in turn demarks an epileptiform spike subgroup with higher epileptic relevance than the other spikes in a cohort of 25 temporal epilepsy patients (including a total of 2,967 interictal spikes and 1,477 HFO events). We found significant morphological distinctions of HFOs and spikes in the presence/absence of this concurrent status. We also demonstrated that the proposed pHFO source imaging enhanced localization of epileptogenic tissue by 162% (∼5.36 mm) for concordance with surgical resection and by 186% (∼12.48 mm) with seizure-onset zone determined by invasive studies, compared to conventional spike imaging, and demonstrated superior congruence with the surgical outcomes. Strikingly, the performance of spike imaging was selectively boosted by the presence of spikes with pHFOs, especially in patients with multitype spikes. Our findings suggest that concurrent HFOs and spikes reciprocally discriminate pathological activities, providing a translational tool for noninvasive presurgical diagnosis and postsurgical evaluation in vulnerable patients.

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Section: Discussionmentioning

confidence: 97%

Noninvasive high-frequency oscillations riding spikes delineates epileptogenic sources

Cai

Sohrabpour

Jiang

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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“…These 11 seizures might be amenable to source reconstruction with corresponding ictal HDEEG signals (the subject of our future work in a larger cohort). Ictal source signals have been reconstructed using ictal scalp EEG in prior studies 47,48,49 .…”

Section: Discussionmentioning

confidence: 99%

“…However, as opposed to MEG, scalp EEG signals are more distorted when the electrical eld propagates through inhomogeneous head tissue. More sophisticated techniques are needed to process and analyse the EEG signals in source space 49 .…”

Section: Discussionmentioning

confidence: 99%

Virtual intracranial electroencephalography for epilepsy surgery using ictal magnetoencephalography

Cao

Galvis

Vogrin

et al. 2021

Preprint

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Modelling the interactions that arise from neural dynamics in seizure genesis is challenging but important in the effort to improve the success of epilepsy surgery. Dynamical network models developed from physiological evidence offer insights into rapidly evolving brain networks in the epileptic seizure. A major limitation of previous studies in this field is the dependence on invasive cortical recordings with constrained spatial sampling of brain regions that might be involved in seizure dynamics. Here, we propose a novel approach, virtual intracranial electroencephalography (ViEEG), that combines non-invasive ictal magnetoencephalographic imaging (MEG), dynamical network models and a virtual resection technique. In this proof-of-concept study, we show that ViEEG signals reconstructed from MEG alone preserve critical temporospatial characteristics for dynamical approaches to identify brain areas involved in seizure generation. Our findings demonstrate the advantages of non-invasive ViEEG over the current presurgical ‘gold-standard’ – intracranial electroencephalography (iEEG). Our approach promises to optimise the surgical strategy for patients with complex refractory focal epilepsy.

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“…The dipole source localization methods need to know the number of sources a priori [4], and when that information is not available, distributed-source models can be used [5] with regularization priors to restrict the solution space. Regularization terms could be based on imposing constraints on solutions' energy [6][7][8], covariance [9,10], sparsity level [11][12][13] or multiple different constrains [14]. These methods require parameter tuning to balance between fitting the recorded data and satisfying the regularization constraints when solving every instance of a given problem, i.e.…”

Section: Conventional Approaches In Electrophysiological Source Imagingmentioning

confidence: 99%

“…Estimating the underlying sources' extent is also an important issue that needs further investigation. Some recent developments in the field suggest that underlying source sizes can be reliably estimated from noninvasive scalp measurements such as EEG [13]. Additionally, estimating the temporal dynamics of estimated sources, rather than just identifying the location of activity in the brain, is of utmost importance when studying a dynamic system like the brain.…”

Section: Limitationsmentioning

confidence: 99%

SIFNet: Electromagnetic Source Imaging Framework Using Deep Neural Networks

Sun

Sohrabpour

et al. 2020

Preprint

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AbstractElectroencephalography (EEG) and magnetoencephalography (MEG) are used to measure brain activity, noninvasively, and are useful tools for brain research and clinical management of brain disorders. Tremendous effort has been made in solving the inverse source imaging problem from EEG/MEG measurements. This is a challenging ill-posed problem, since the number of measurements is much smaller than the number of possible sources in the brain. Various methods have been developed to estimate underlying brain sources from noninvasive EEG/MEG as this can offer insight about the underlying brain electrical activity with significantly improved spatial resolution. In this work, we propose a novel data-driven Source Imaging Framework using deep learning neural networks (SIFNet), where (1) a simulation pipeline is designed to model realistic brain activation and EEG/MEG signals to train generalizable neural networks, (2) and a residual convolutional neural network is trained using the simulated data, capable of estimating source distributions from EEG/MEG recordings. The performance of our proposed SIFNet approach is evaluated in a series of computer simulations, which indicates the excellent performance of SIFNet outperforming conventional weighted minimum norm algorithms that were tested in this work. The SIFNet is further tested by analyzing interictal EEG data recorded in a clinical setting from a focal epilepsy patient. The results of this clinical data analysis indicate accurate localization of epileptogenic activity as validated by the epileptogenic zone clinically determined in this patient. In sum, the proposed SIFNet approach promises to offer an alternative solution to the EEG/MEG inverse source imaging problem, shows promising signs of being robust against measurement noise, and is easy to implement, therefore, being translatable to clinical practice.

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Noninvasive electromagnetic source imaging of spatiotemporally distributed epileptogenic brain sources

Cited by 69 publications

References 69 publications

Noninvasive high-frequency oscillations riding spikes delineates epileptogenic sources

Noninvasive high-frequency oscillations riding spikes delineates epileptogenic sources

Virtual intracranial electroencephalography for epilepsy surgery using ictal magnetoencephalography

SIFNet: Electromagnetic Source Imaging Framework Using Deep Neural Networks

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