eoe sub articles

EoE Sub Articles

<figure class='table'><table class='ck-table-resized' style='border-collapse:collapse;font-family:Calibri;font-size:11pt;table-layout:fixed;' cellspacing='0' cellpadding='0' dir='ltr' border='1' data-sheets-root='1' data-sheets-baot='1'><colgroup><col style='width:25%;' width='144'><col style='width:25%;' width='144'><col style='width:25%;' width='144'><col style='width:25%;' width='144'></colgroup><tbody><tr style='height:20px;'><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>VectorView MEG system</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Elekta-Neuromag, Finland</td><td style='background-color:#ffffff;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>MEG System</td></tr><tr style='height:20px;'><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Magentically Shielded Room</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Imedco, Hagendorf, Switzerland</td><td style='background-color:#ffffff;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Three-layer MSR</td></tr><tr style='height:20px;'><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>EEG system</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Elekta-Neuromag, Finland</td><td style='background-color:#ffffff;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>70 Channel EEG system</td></tr><tr style='height:20px;'><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>3D digitizer</td><td style='background-color:#ffffff;color:#1a202c;font-family:Roboto;font-size:12pt;font-weight:normal;overflow:hidden;padding:0px 3px;vertical-align:bottom;white-space:normal;word-wrap:break-word;wrap-strategy:4;'>Polhemus, Colchester, VT</td><td style='background-color:#ffffff;overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td><td style='overflow:hidden;padding:0px 3px;vertical-align:bottom;'>&#160;</td></tr></tbody></table></figure>

 simultaneous electroencephalography and magnetoencephalography to identify seizure-prone brain regions 

Source:&#160;<a style='text-decoration:none;' href='https://app-jove-com.remotexs.ntu.edu.sg/v/54883/interictal-high-frequency-oscillations-detected-with-simultaneous'><span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'>Papadelis, C.,&#160;et al.,<span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'> Interictal High Frequency Oscillations Detected with Simultaneous Magnetoencephalography and Electroencephalography as Biomarker of Pediatric Epilepsy.&#160;J. Vis. Exp.<span style='-webkit-text-decoration-skip:none;font-family:Arial,sans-serif;font-size:12pt;font-style:normal;font-variant:normal;font-weight:400;text-decoration-skip-ink:none;vertical-align:baseline;white-space:pre-wrap;'> (2016).</a> &#160;This video demonstrates the method of using electroencephalography (EEG) and magnetoencephalography (MEG) recordings to identify interictal epileptiform discharges (IEDs) and high-frequency oscillations (HFOs) to locate seizure-prone regions in the brain.

 Simultaneous Electroencephalography and Magnetoencephalography to Identify Seizure-Prone Brain Regions 

Source:&#160;Papadelis, C.,&#160;et al., Interictal High Frequency Oscillations Detected with Simultaneous Magnetoencephalography and ...

Begin with a human participant wearing electroencephalography or EEG electrodes and additional electrodes, lying in the magnetoencephalography or MEG chamber.The EEG records the electrical signals from neurons and generates the EEG data.&#160;Simultaneously, MEG detects magnetic signals generated by neuronal electrical activity and produces the MEG data.&#160;With the additional electrodes, record peripheral signals from the body movements.Remove the participant and record the background signal to remove noise from the data.Compare EEG and MEG data to identify segments with interictal epileptiform discharges or IEDs.IEDs are linked to recurrent abnormal brain activity associated with seizures.Apply algorithms and detect high-frequency oscillations, or HFOs, representing rapid neuronal activity near or within IEDs, and compare them with peripheral signals to exclude body movement signals.This ensures accurate localization of HFOs to seizure-prone regions.Using an algorithm, EEG and MEG data generate a 3D brain map highlighting HFO regions linked to seizure-prone areas.

simultaneous-electroencephalography-magnetoencephalography-to

Research

JoVE Encyclopedia of Experiments

Neuroscience

Neuroimaging

Developmental & Regenerative Neuroimaging

24 Views. Source: Papadelis, C., et al., Interictal High Frequency Oscillations Detected with Simultaneous Magnetoencephalography and Electroencephalography as Biomarker of Pediatric Epilepsy. J. Vis. Exp. (2016).  This video demonstrates the method of using electroencephalography (EEG) and magnetoencephalography (MEG) recordings to identify interictal epileptiform discharges (IEDs) and high-frequency oscillations (HFOs) to locate seizure-prone regions in the brain. 

Video:  Simultaneous Electroencephalography and Magnetoencephalography to Identify Seizure-Prone Brain Regions  - Concept

Simultaneous Scalp Electroencephalography (EEG), Electromyography (EMG), and Whole-body Segmental Inertial Recording for Multi-modal Neural Decoding

Recent studies support the involvement of supraspinal networks in control of bipedal human walking. Part of this evidence encompasses studies, including our previous work, demonstrating that gait kinematics and limb coordination during treadmill walking can be inferred from the scalp electroencephalogram (EEG) with reasonably high decoding accuracies. These results provide impetus for development of non-invasive brain-machine-interface (BMI) systems for use in restoration and/or augmentation of gait- a primary goal of rehabilitation research. To date, studies examining EEG decoding of activity during gait have been limited to treadmill walking in a controlled environment. However, to be practically viable a BMI system must be applicable for use in everyday locomotor tasks such as over ground walking and turning. Here, we present a novel protocol for non-invasive collection of brain activity (EEG), muscle activity (electromyography (EMG)), and whole-body kinematic data (head, torso, and limb trajectories) during both treadmill and over ground walking tasks. By collecting these data in the uncontrolled environment insight can be gained regarding the feasibility of decoding unconstrained gait and surface EMG from scalp EEG.

Simultaneous Scalp Electroencephalography EEG, Electromyography EMG, and Whole-body Segmental Inertial Recording for Multi-modal Neural Decoding

Development of an effective brain-machine-interface (BMI) system for restoration and rehabilitation of bipedal locomotion requires accurate decoding of user's intent. Here we present a novel experimental protocol and data collection technique for simultaneous non-invasive acquisition of neural activity, muscle activity, and whole-body kinematics during various locomotion tasks and conditions.

Recent  studies support the involvement of supraspinal networks in control of bipedal  human walking. Part of this evidence  encompasses studies, ...

JoVE Journal

Behavior

Recording Brain Electromagnetic Activity During the Administration of the Gaseous Anesthetic Agents Xenon and Nitrous Oxide in Healthy Volunteers

Anesthesia arguably provides one of the only systematic ways to study the neural correlates of global consciousness/unconsciousness. However to date most neuroimaging or neurophysiological investigations in humans have been confined to the study of &#947;-Amino-Butyric-Acid-(GABA)-receptor-agonist-based anesthetics, while the effects of dissociative N-Methyl-D-Aspartate-(NMDA)-receptor-antagonist-based anesthetics ketamine, nitrous oxide (N2O) and xenon (Xe) are largely unknown. This paper describes the methods underlying the simultaneous recording of magnetoencephalography (MEG) and electroencephalography (EEG) from healthy males during inhalation of the gaseous anesthetic agents N2O and Xe. Combining MEG and EEG data enables the assessment of electromagnetic brain activity during anesthesia at high temporal, and moderate spatial, resolution. Here we describe a detailed protocol, refined over multiple recording sessions, that includes subject recruitment, anesthesia equipment setup in the MEG scanner room, data collection and basic data analysis. In this protocol each participant is exposed to varying levels of Xe and N2O in a repeated measures cross-over design. Following relevant baseline recordings participants are exposed to step-wise increasing inspired concentrations of Xe and N2O of 8, 16, 24 and 42%, and 16, 32 and 47% respectively, during which their level of responsiveness is tracked with an auditory continuous performance task (aCPT). Results are presented for a number of recordings to highlight the sensor-level properties of the raw data, the spectral topography, the minimization of head movements, and the unequivocal level dependent effects on the auditory evoked responses. This paradigm describes a general approach to the recording of electromagnetic signals associated with the action of different kinds of gaseous anesthetics, which can be readily adapted to be used with volatile and intravenous anesthetic agents. It is expected that the method outlined can contribute to the understanding of the macro-scale mechanisms of anesthesia by enabling methodological extensions involving source space imaging and functional network analysis.

Simultaneous magnetoencephalography and electroencephalography provides a useful tool to search for common and distinct macro-scale mechanisms of reductions in consciousness induced by different anesthetics. This paper illustrates the empirical methods underlying the recording of such data from healthy humans during N-Methyl-D-Aspartate-(NMDA)-receptor-antagonist-based anesthesia during inhalation of nitrous oxide and xenon.

Anesthesia arguably provides one of the only systematic ways to study the neural correlates of global consciousness/unconsciousness. However to date most ...

Integrating MEG and HD-EEG in Pediatric Epilepsy Localization

Electromagnetic Source Imaging in Presurgical Evaluation of Children with Drug-Resistant Epilepsy

For children with drug-resistant epilepsy (DRE), seizure freedom relies on the delineation and resection (or ablation/disconnection) of the epileptogenic zone (EZ) while preserving the eloquent brain areas. The development of a reliable and noninvasive localization method that provides clinically useful information for the localization of the EZ is, therefore, crucial to achieving successful surgical outcomes. Electric and magnetic source imaging (ESI and MSI) have been increasingly utilized in the presurgical evaluation of these patients showing promising findings in the delineation of epileptogenic as well as eloquent brain areas. Moreover, the combination of ESI and MSI into a single solution, namely electromagnetic source imaging (EMSI), performed on simultaneous high-density electroencephalography (HD-EEG) and magnetoencephalography (MEG) recordings has shown higher source localization accuracy than either modality alone. Despite these encouraging findings, such techniques are performed in only a few tertiary epilepsy centers, are rarely recorded simultaneously, and are underutilized in pediatric cohorts. This study illustrates the experimental setup for recording simultaneous MEG and HD-EEG data as well as the methodological framework for analyzing these data aiming to localize the irritative zone, the seizure onset zone, and eloquent brain areas in children with DRE. More specifically, the experimental setups are presented for (i) recording and localizing interictal and ictal epileptiform activity during sleep and (ii) recording visual-, motor-, auditory-, and somatosensory-evoked responses and mapping relevant eloquent brain areas (i.e., visual, motor, auditory, and somatosensory) during visuomotor task, as well as auditory and somatosensory stimulations. Detailed steps of the data analysis pipeline are further presented for performing EMSI as well as individual ESI and MSI using equivalent current dipole (ECD) and dynamic statistical parametric mapping (dSPM).

Author Spotlight: Advancing Pediatric Epilepsy Surgery in Children Through Novel Biomarkers and Enhanced Localization

Magnetoencephalography (MEG) and high-density electroencephalography (HD-EEG) are rarely recorded simultaneously, although they yield confirmatory and complementary information. Here, we illustrate the experimental setup for recording simultaneous MEG and HD-EEG and the methodology for analyzing these data aiming to localize epileptogenic and eloquent brain areas in children with drug-resistant epilepsy.

For children with drug-resistant epilepsy (DRE), seizure freedom relies on the delineation and resection (or ablation/disconnection) of the epileptogenic ...

Simultaneous Electroencephalography and Magnetoencephalography to Identify Seizure-Prone Brain Regions

Transcript

Simultaneous Electroencephalography and Magnetoencephalography to Identify Seizure-Prone Brain Regions

Simultaneous Scalp Electroencephalography (EEG), Electromyography (EMG), and Whole-body Segmental Inertial Recording for Multi-modal Neural Decoding

Recording Brain Electromagnetic Activity During the Administration of the Gaseous Anesthetic Agents Xenon and Nitrous Oxide in Healthy Volunteers

Electromagnetic Source Imaging in Presurgical Evaluation of Children with Drug-Resistant Epilepsy