Abstract
Event-related ICA (eICA) is a partially data-driven analysis method for event-related fMRI that is particularly suited to analysis of simultaneous EEG-fMRI of patients with epilepsy. EEG-fMRI studies in epileptic patients are typically analyzed using the general linear model (GLM), often with assumption that the onset and offset of neuronal activity match EEG event onset and offset, the neuronal activation is sustained at a constant level throughout the epileptiform event and that associated fMRI signal changes follow the canonical HRF. The eICA method allows for less constrained analyses capable of detecting early, non-canonical responses. A key step of eICA is the initial deconvolution which can be confounded by various sources of structured noise present in the fMRI signal. To help overcome this, we have extend the eICA procedure by utilizing a fully standalone and automated fMRI de-noising procedure to process the fMRI data from an EEG-fMRI acquisition prior to running eICA. Specifically we first apply ICA to the entire fMRI time-series and use a classifier to remove noise-related components. The automated objective de-noiser, “Spatially Organized Component Klassificator” (SOCK) is used; it has previously been shown to distinguish a substantial fraction of noise from true activation, without rejecting the latter, in resting-state fMRI. A second ICA is then performed, this time on the event-related response estimates derived from the denoised data (according to the usual eICA procedure). We hypothesize that SOCK + eICA has the potential to be more sensitive than eICA alone. We test the effectiveness of SOCK by comparing activation obtained in an eICA analysis of EEG-fMRI data with and without the use of SOCK for 14 patients with rolandic epilepsy who exhibited stereotypical IEDs arising from a focus in the rolandic fissure.
Highlights
Event-related functional magnetic resonance imaging is an MRI technique that can be used to detect changes in theBlood Oxygen Level Dependent (BOLD) hemodynamic response to neural activity in response to certain events
We demonstrate the effectiveness of Spatially Organized Component Klassificator” (SOCK) by comparing the extent of activation obtained in a standard Event-related independent components analysis (ICA) (eICA) analysis of EEG-functional magnetic resonance imaging (fMRI) data with and without the use of SOCK for 14 patients with rolandic epilepsy who exhibited stereotypical interictal epileptiform discharges (IEDs) arising from a focus in the rolandic fissure
SOCK classified between 27 and 53% of each subject’s components as artifact
Summary
Event-related functional magnetic resonance imaging (fMRI) is an MRI technique that can be used to detect changes in theBlood Oxygen Level Dependent (BOLD) hemodynamic response to neural activity in response to certain events. Event-related functional magnetic resonance imaging (fMRI) is an MRI technique that can be used to detect changes in the. The conventional method for detecting event-related responses in fMRI consists of modeling the expected fMRI response to an event by convolving a stimulus presentation time-course with an assumed canonical Haemodynamic Response Function (HRF) and using linear regression to identify voxels with a significant correlation to this expected response (Josephs et al, 1997). One typically assumes that the onset and offset of neuronal activity match stimuli onset and offset, the neuronal activation is sustained at a constant level throughout the stimulus and that evoked fMRI signal changes follow the canonical HRF. Carney et al (2010)
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