Your search keyword '"Electrocorticography"' showing total 6,376 results

1. Predictive modeling of evoked intracranial EEG response to medial temporal lobe stimulation in patients with epilepsy.

Author

Acharya, Gagan, Davis, Kathryn, and Nozari, Erfan

Subjects

Humans, Temporal Lobe, Female, Male, Electrocorticography, Drug Resistant Epilepsy, Adult, Electroencephalography, Young Adult, Epilepsy, Models, Neurological

Abstract

Despite promising advancements, closed-loop neurostimulation for drug-resistant epilepsy (DRE) still relies on manual tuning and produces variable outcomes, while automated predictable algorithms remain an aspiration. As a fundamental step towards addressing this gap, here we study predictive dynamical models of human intracranial EEG (iEEG) response under parametrically rich neurostimulation. Using data from n = 13 DRE patients, we find that stimulation-triggered switched-linear models with ~300 ms of causal historical dependence best explain evoked iEEG dynamics. These models are highly consistent across different stimulation amplitudes and frequencies, allowing for learning a generalizable model from abundant STIM OFF and limited STIM ON data. Further, evoked iEEG in nearly all subjects exhibited a distance-dependent pattern, whereby stimulation directly impacts the actuation site and nearby regions (≲ 20 mm), affects medium-distance regions (20 ~ 100 mm) through network interactions, and hardly reaches more distal areas (≳ 100 mm). Peak network interaction occurs at 60 ~ 80 mm from the stimulation site. Due to their predictive accuracy and mechanistic interpretability, these models hold significant potential for model-based seizure forecasting and closed-loop neurostimulation design.

Published

2024

2. An electroencephalogram microdisplay to visualize neuronal activity on the brain surface.

Author

Cleary, Daniel, Pizarro, Patricia, Tonsfeldt, Karen, Lee, Keundong, Chen, Po, Bourhis, Andrew, Galton, Ian, Coughlin, Brian, Yang, Jimmy, Paulk, Angelique, Halgren, Eric, Cash, Sydney, Dayeh, Shadi, Tchoe, Youngbin, Wu, Tianhai, U, Hoi, Roth, David, Kim, Dongwoo, and Lee, Jihwan

Subjects

Animals, Brain, Electroencephalography, Swine, Rats, Neurons, Brain Mapping, Rats, Sprague-Dawley, Electrocorticography, Male

Abstract

Functional mapping during brain surgery is applied to define brain areas that control critical functions and cannot be removed. Currently, these procedures rely on verbal interactions between the neurosurgeon and electrophysiologist, which can be time-consuming. In addition, the electrode grids that are used to measure brain activity and to identify the boundaries of pathological versus functional brain regions have low resolution and limited conformity to the brain surface. Here, we present the development of an intracranial electroencephalogram (iEEG)-microdisplay that consists of freestanding arrays of 2048 GaN light-emitting diodes laminated on the back of micro-electrocorticography electrode grids. With a series of proof-of-concept experiments in rats and pigs, we demonstrate that these iEEG-microdisplays allowed us to perform real-time iEEG recordings and display cortical activities by spatially corresponding light patterns on the surface of the brain in the surgical field. Furthermore, iEEG-microdisplays allowed us to identify and display cortical landmarks and pathological activities from rat and pig models. Using a dual-color iEEG-microdisplay, we demonstrated coregistration of the functional cortical boundaries with one color and displayed the evolution of electrical potentials associated with epileptiform activity with another color. The iEEG-microdisplay holds promise to facilitate monitoring of pathological brain activity in clinical settings.

Published

2024

3. Patient experiences of resection versus responsive neurostimulation for drug-resistant epilepsy.

Author

Haeusermann, Tobias, Liu, Emily, Fong, Kristina, Dohan, Daniel, and Chiong, Winston

Subjects

Drug-resistant epilepsy, Patient experience, Responsive neurostimulation, Surgical resection, Humans, Drug Resistant Epilepsy, Epilepsy, Deep Brain Stimulation, Electrocorticography, Patient Outcome Assessment

Abstract

This study explored illness experiences and decision-making among patients with epilepsy who underwent two different types of surgical interventions: resection versus implantation of the NeuroPace Responsive Neurostimulation System (RNS). We recruited 31 participants from a level four epilepsy center in an academic medical institution. We observed 22 patient clinic visits (resection: n = 10, RNS: n = 12) and conducted 18 in-depth patient interviews (resection: n = seven, RNS: n = 11); most visits and interviews included patient caregivers. Using an applied ethnographic approach, we identified three major themes in the experiences of resection versus RNS patients. First, for patients in both cohorts, the therapeutic journey was circuitous in ways that defied standardized first-, second-, and third- line of care models. Second, in conceptualizing risk, resection patients emphasized the permanent loss of taking out brain tissue whereas RNS patients highlighted the reversibility of putting in a device. Lastly, in considering benefit, resection patients perceived their surgery as potentially curative while RNS patients understood implantation as primarily palliative with possible additional diagnostic benefit from chronic electrocorticography. Insight into the perspectives of patients and caregivers may help identify key topics for counseling and exploration by clinicians.

Published

2024

4. Intraoperative application and early experience with novel high-resolution, high-channel-count thin-film electrodes for human microelectrocorticography.

Author

Tan, Hao, Paulk, Angelique, Stedelin, Brittany, Cleary, Daniel, Nerison, Caleb, Tchoe, Youngbin, Brown, Erik, Bourhis, Andrew, Russman, Samantha, Tonsfeldt, Karen, Yang, Jimmy, Oh, Hongseok, Ro, Yun, Lee, Keundong, Ganji, Mehran, Galton, Ian, Siler, Dominic, Han, Seunggu, Collins, Kelly, Ben-Haim, Sharona, Halgren, Eric, Cash, Sydney, Dayeh, Shadi, Raslan, Ahmed, and Lee, Jihwan

Subjects

cortical, electrocorticography, functional neurosurgery, gamma band, high resolution, intraoperative, mapping, passive, Humans, Microelectrodes, Computer Systems, Craniotomy, Language, Peroxides

Abstract

OBJECTIVE: The study objective was to evaluate intraoperative experience with newly developed high-spatial-resolution microelectrode grids composed of poly(3,4-ethylenedioxythiophene) with polystyrene sulfonate (PEDOT:PSS), and those composed of platinum nanorods (PtNRs). METHODS: A cohort of patients who underwent craniotomy for pathological tissue resection and who had high-spatial-resolution microelectrode grids placed intraoperatively were evaluated. Patient demographic and baseline clinical variables as well as relevant microelectrode grid characteristic data were collected. The primary and secondary outcome measures of interest were successful microelectrode grid utilization with usable resting-state or task-related data, and grid-related adverse intraoperative events and/or grid dysfunction. RESULTS: Included in the analysis were 89 cases of patients who underwent a craniotomy for resection of neoplasms (n = 58) or epileptogenic tissue (n = 31). These cases accounted for 94 grids: 58 PEDOT:PSS and 36 PtNR grids. Of these 94 grids, 86 were functional and used successfully to obtain cortical recordings from 82 patients. The mean cortical grid recording duration was 15.3 ± 1.15 minutes. Most recordings in patients were obtained during experimental tasks (n = 52, 58.4%), involving language and sensorimotor testing paradigms, or were obtained passively during resting state (n = 32, 36.0%). There were no intraoperative adverse events related to grid placement. However, there were instances of PtNR grid dysfunction (n = 8) related to damage incurred by suboptimal preoperative sterilization (n = 7) and improper handling (n = 1); intraoperative recordings were not performed. Vaporized peroxide sterilization was the most optimal sterilization method for PtNR grids, providing a significantly greater number of usable channels poststerilization than did steam-based sterilization techniques (median 905.0 [IQR 650.8-935.5] vs 356.0 [IQR 18.0-597.8], p = 0.0031). CONCLUSIONS: High-spatial-resolution microelectrode grids can be readily incorporated into appropriately selected craniotomy cases for clinical and research purposes. Grids are reliable when preoperative handling and sterilization considerations are accounted for. Future investigations should compare the diagnostic utility of these high-resolution grids to commercially available counterparts and assess whether diagnostic discrepancies relate to clinical outcomes.

Published

2024

5. Multi-night cortico-basal recordings reveal mechanisms of NREM slow-wave suppression and spontaneous awakenings in Parkinsons disease.

Author

Anjum, Md, Smyth, Clay, Zuzuárregui, Rafael, Dijk, Derk, Starr, Philip, Denison, Timothy, and Little, Simon

Subjects

Humans, Parkinson Disease, Subthalamic Nucleus, Sleep, Polysomnography, Electrocorticography

Abstract

Sleep disturbance is a prevalent and disabling comorbidity in Parkinsons disease (PD). We performed multi-night (n = 57) at-home intracranial recordings from electrocorticography and subcortical electrodes using sensing-enabled Deep Brain Stimulation (DBS), paired with portable polysomnography in four PD participants and one with cervical dystonia (clinical trial: NCT03582891). Cortico-basal activity in delta increased and in beta decreased during NREM (N2 + N3) versus wakefulness in PD. DBS caused further elevation in cortical delta and decrease in alpha and low-beta compared to DBS OFF state. Our primary outcome demonstrated an inverse interaction between subcortical beta and cortical slow-wave during NREM. Our secondary outcome revealed subcortical beta increases prior to spontaneous awakenings in PD. We classified NREM vs. wakefulness with high accuracy in both traditional (30 s: 92.6 ± 1.7%) and rapid (5 s: 88.3 ± 2.1%) data epochs of intracranial signals. Our findings elucidate sleep neurophysiology and impacts of DBS on sleep in PD informing adaptive DBS for sleep dysfunction.

Published

2024

6. Differential neural mechanisms underlie cortical gating of visual spatial attention mediated by alpha-band oscillations.

Author

Xiaofang Yang, Fiebelkorn, Ian C., Jensen, Ole, Knight, Robert T., and Kastner, Sabine

Subjects

*FUNCTIONAL connectivity, *VISUAL cortex, *SENSORIMOTOR integration, *SELECTIVITY (Psychology), *ELECTROENCEPHALOGRAPHY

Abstract

Selective attention relies on neural mechanisms that facilitate processing of behaviorally relevant sensory information while suppressing irrelevant information, consistently linked to alpha-band oscillations in human M/EEG studies. We analyzed cortical alpha responses from intracranial electrodes implanted in eight epilepsy patients, who performed a visual spatial attention task. Electrocorticographic data revealed a spatiotemporal dissociation between attention-modulated alpha desynchronization, associated with the enhancement of sensory processing, and alpha synchronization, associated with the suppression of sensory processing, during the cue-target interval. Dorsal intraparietal areas contralateral to the attended hemifield primarily exhibited a delayed and sustained alpha desynchronization, while ventrolateral extrastriatal areas ipsilateral to the attended hemifield primarily exhibited an earlier and sustained alpha synchronization. Analyses of cross-frequency coupling between alpha phase and broadband high-frequency activity (HFA) further revealed cross-frequency interactions along the visual hierarchy contralateral to the attended locations. Directionality analyses indicate that alpha phase in early and extrastriatal visual areas modulated HFA power in downstream visual areas, thus potentially facilitating the feedforward processing of an upcoming, spatially predictable target. In contrast, in areas ipsilateral to the attended locations, HFA power modulated local alpha phase in early and extrastriatal visual areas, with suppressed interareal interactions, potentially attenuating the processing of distractors. Our findings reveal divergent alpha-mediated neural mechanisms underlying target enhancement and distractor suppression during the deployment of spatial attention, reflecting enhanced functional connectivity at attended locations, while suppressed functional connectivity at unattended locations. The collective dynamics of these alpha-mediated neural mechanisms play complementary roles in the efficient gating of sensory information. [ABSTRACT FROM AUTHOR]

Published

2024

7. Camphor alters occipital electrocorticographic patterns during sleep deprivation in Wistar rats.

Author

Gurgel do Amaral, Anthony Lucas, Brito Barbosa, Gabriela, Farias dos Santos, Murilo, Vasconcelos de Souza, Luana, Gonçalves dos Santos, Rodrigo, Mata Câmara, Tays, de Sousa Reis, Thaysa, Pacheco Hartcopff, Priscille Fidelis, Eiró-Quirino, Luciana, Araújo da Paz, Clarissa, de Araújo, Daniella Bastos, Favacho Lopes, Dielly Catrina, Miki Taketomi Saito, and Hamoy, Moisés

Subjects

CAMPHOR, SLEEP deprivation, INSOMNIA treatment, ELECTROENCEPHALOGRAPHY, NEUROPHARMACOLOGY

Abstract

Introduction: Sleep disorders are common in the general population, necessitating the search for new strategies to address this public health challenge. The study aims to describe the electrocorticographic and behavioral changes in sleep deprived Wistar rats exposed to varying doses of camphor, to assess its effects on sleep and its potential as a sleep-inducing drug. Materials and Methods: For the electrocorticographic evaluation, seventy-two rats were randomly assigned to distinct groups: a control group, a sleep-deprived group, three sleep-deprived groups receiving 10, 20, and 30 mg/kg i.p. of camphor respectively, and three groups that received these doses without sleep deprivation. For the behavioral analysis, twenty-seven rats were divided into three groups, each receiving the same doses as the previous test. Results and Discussion: Our results showed that there was a decrease in the frequency of brain oscillatory patterns when camphor was administered at 10 mg/kg i.p. whereas there was a dose-dependent increase in the spectral power and distribution following the administration of 20 and 30 mg/kg i.p., with the emergence of Delta, Theta, Alpha, and Beta waves. As for the behavioral analysis, it was demonstrated that testicular relaxation, decreased motility, and light sleep induction also occurred in a dose-dependent manner. Thus, we conclude that camphor administration intensifies occipital electrocorticographic patterns in sleep-deprived rats, and its electrocorticographic and behavioral analysis could indicate a potential as a supporting agent in the insomnia treatment. [ABSTRACT FROM AUTHOR]

Published

2024

8. A review of acute symptomatic seizures during awake craniotomy for tumour resection.

Author

Freund, Brin E., Barrios, Maria L., Feyissa, Anteneh M., Sabsevitz, David, Grewal, Sanjeet S., Freeman, William D., Middlebrooks, Erik H., Sanchez-Garavito, Jesus E., Quinones-Hinojosa, Alfredo, and Tatum, William O.

Subjects

*EPILEPTIFORM discharges, *INTRACRANIAL hemorrhage, *ELECTRIC stimulation, *BRAIN tumors, *CRANIOTOMY, TUMOR surgery

Abstract

AbstractPurposeMaterials and MethodsResults and ConclusionsAwake craniotomy (AC) is a procedure often performed concomitantly with direct electrical cortical stimulation (DES) and electrocorticography (ECoG) during functional brain mapping. Patients undergoing AC are at risk of acute symptomatic seizures, including intraoperative (IS) and early postoperative seizures (EPS) which can lead to higher risk of morbidity. Predicting those who are at risk of IS and EPS could alert clinicians and provide the ability to closely monitor and consider management changes in the acute setting to prevent seizures.This is a narrative review of previous studies on IS and EPS during awake craniotomy, including a summary of studies from our center using a novel circular grid electrode.There are a number of clinical features with variable association with a higher risk of EPS and IS. Surgeries involving the anterior and central head regions are a risk factor for IS. EPS is more likely to occur in patients with perioperative intracranial hemorrhage. Improving grid/electrode technology for ECoG can allow for better sensitivity of detecting epileptiform activity which can help to diagnose and predict perioperative seizures. [ABSTRACT FROM AUTHOR]

Published

2024

9. Dopamine and deep brain stimulation accelerate the neural dynamics of volitional action in Parkinson's disease.

Author

Köhler, Richard M, Binns, Thomas S, Merk, Timon, Zhu, Guanyu, Yin, Zixiao, Zhao, Baotian, Chikermane, Meera, Vanhoecke, Jojo, Busch, Johannes L, Habets, Jeroen G V, Faust, Katharina, Schneider, Gerd-Helge, Cavallo, Alessia, Haufe, Stefan, Zhang, Jianguo, Kühn, Andrea A, Haynes, John-Dylan, and Neumann, Wolf-Julian

Subjects

*DEEP brain stimulation, *NEURAL stimulation, *FISHER discriminant analysis, *LARGE-scale brain networks, *PARKINSON'S disease, *SENSORIMOTOR cortex, *SUBTHALAMIC nucleus

Abstract

The ability to initiate volitional action is fundamental to human behaviour. Loss of dopaminergic neurons in Parkinson's disease is associated with impaired action initiation, also termed akinesia. Both dopamine and subthalamic deep brain stimulation (DBS) can alleviate akinesia, but the underlying mechanisms are unknown. An important question is whether dopamine and DBS facilitate de novo build-up of neural dynamics for motor execution or accelerate existing cortical movement initiation signals through shared modulatory circuit effects. Answering these questions can provide the foundation for new closed-loop neurotherapies with adaptive DBS, but the objectification of neural processing delays prior to performance of volitional action remains a significant challenge. To overcome this challenge, we studied readiness potentials and trained brain signal decoders on invasive neurophysiology signals in 25 DBS patients (12 female) with Parkinson's disease during performance of self-initiated movements. Combined sensorimotor cortex electrocorticography and subthalamic local field potential recordings were performed OFF therapy (n = 22), ON dopaminergic medication (n = 18) and on subthalamic deep brain stimulation (n = 8). This allowed us to compare their therapeutic effects on neural latencies between the earliest cortical representation of movement intention as decoded by linear discriminant analysis classifiers and onset of muscle activation recorded with electromyography. In the hypodopaminergic OFF state, we observed long latencies between motor intention and motor execution for readiness potentials and machine learning classifications. Both, dopamine and DBS significantly shortened these latencies, hinting towards a shared therapeutic mechanism for alleviation of akinesia. To investigate this further, we analysed directional cortico-subthalamic oscillatory communication with multivariate granger causality. Strikingly, we found that both therapies independently shifted cortico-subthalamic oscillatory information flow from antikinetic beta (13–35 Hz) to prokinetic theta (4–10 Hz) rhythms, which was correlated with latencies in motor execution. Our study reveals a shared brain network modulation pattern of dopamine and DBS that may underlie the acceleration of neural dynamics for augmentation of movement initiation in Parkinson's disease. Instead of producing or increasing preparatory brain signals, both therapies modulate oscillatory communication. These insights provide a link between the pathophysiology of akinesia and its' therapeutic alleviation with oscillatory network changes in other non-motor and motor domains, e.g. related to hyperkinesia or effort and reward perception. In the future, our study may inspire the development of clinical brain computer interfaces based on brain signal decoders to provide temporally precise support for action initiation in patients with brain disorders. [ABSTRACT FROM AUTHOR]

Published

2024

10. Low-Frequency Oscillations in Mid-rostral Dorsolateral Prefrontal Cortex Support Response Inhibition.

Author

Khan, Anas U., Irwin, Zachary, Mahavadi, Anil, Roller, Anna, Goodman, Adam M., Guthrie, Barton L., Visscher, Kristina, Knight, Robert T., Walker, Harrison C., and Bentley, J. Nicole

Subjects

*CONTROL (Psychology), *EXECUTIVE function, *RESPONSE inhibition, *COGNITIVE ability, *BASAL ganglia

Abstract

Executive control of movement enables inhibiting impulsive responses critical for successful navigation of the environment. Circuits mediating stop commands involve prefrontal and basal ganglia structures with fMRI evidence demonstrating increased activity during response inhibition in the dorsolateral prefrontal cortex (dlPFC)—often ascribed to maintaining task attentional demands. Using direct intraoperative cortical recordings in male and female human subjects, we investigated oscillatory dynamics along the rostral-caudal axis of dlPFC during a modified Go/No-go task, probing components of both proactive and reactive motor control. We assessed whether cognitive control is topographically organized along this axis and observed that low-frequency power increased prominently in mid-rostral dlPFC when inhibiting and delaying responses. These findings provide evidence for a key role for mid-rostral dlPFC low-frequency oscillations in sculpting motor control. [ABSTRACT FROM AUTHOR]

Published

2024

11. Novel technique of switching TIVA and sevoflurane during epilepsy surgery for combined intraoperative motor evoked potentials monitoring and electrocorticography: an illustrative case report.

Author

Mukoyama, Yoko, Ichikawa, Junko, Komori, Makiko, Kodaka, Mitsuharu, Yokosako, Suguru, and Kubota, Yuichi

Subjects

EVOKED potentials (Electrophysiology), EPILEPSY surgery, TEMPORAL lobe epilepsy, BRAIN surgery, ANESTHETICS, INTRAOPERATIVE monitoring

Abstract

Background: During epilepsy surgery, it is equally important to record electrocorticography (ECoG) for detecting epileptogenic activity and guiding brain resection, and to evaluate neuromonitoring data, particularly motor evoked potentials (MEP), for avoidance of postoperative neurological complications. However, sevoflurane, which is commonly used during recording of ECoG, may attenuate the MEP response. It enforces anesthesiologists and neurosurgeons to select one anesthetic agent over another, facilitating either ECoG or MEP monitoring. Case presentation: In the presented case of a 20-year-old man, who underwent surgery for temporal lobe epilepsy, a novel technique of neuroanesthesia was introduced, integrating initial induction of the total intravenous anesthesia (TIVA) with propofol (effect-site concentration, 2.3–3.0 μg/ml), its subsequent switching to sevoflurane (end-tidal concentration, 2.5%) for ECoG recording, and further change back to TIVA for MEP monitoring during brain resection. Conclusions: Intraoperative switch of anesthetic agents according to specific intraoperative requirements may be useful for cases of brain surgery requiring both ECoG recordings and MEP monitoring. [ABSTRACT FROM AUTHOR]

Published

2024

12. The effect of acute and chronic harmaline administration on penicillin-induced epileptiform activity in rats.

Author

Ozkan, Kayhan and Demir, Serif

Subjects

MONOAMINE oxidase inhibitors, PEGANUM harmala, PENICILLIN G, ELECTROPHYSIOLOGY, GLUTATHIONE peroxidase

Abstract

Copyright of Anatolian Clinic Journal of Medical Sciences is the property of Hayat Saglik ve Sosyal Hizmetler Vakfi and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

13. Benefits of sharing neurophysiology data from the BRAIN Initiative Research Opportunities in Humans Consortium.

Author

Rahimzadeh, Vasiliki, Jones, Kathryn, Majumder, Mary, Kahana, Michael, Rutishauser, Ueli, Williams, Ziv, Cash, Sydney, Paulk, Angelique, Zheng, Jie, Beauchamp, Michael, Collinger, Jennifer, Pouratian, Nader, McGuire, Amy, and Sheth, Sameer

Subjects

BRAIN Initiative, FAIR principles, data sharing, electrocorticography, implanted human neurophysiology, intracortical human physiology, intracranial EEG, invasive human neurophysiology, Humans, Neurophysiology, Brain, Information Dissemination

Abstract

Sharing human brain data can yield scientific benefits, but because of various disincentives, only a fraction of these data is currently shared. We profile three successful data-sharing experiences from the NIH BRAIN Initiative Research Opportunities in Humans (ROH) Consortium and demonstrate benefits to data producers and to users.

Published

2023

14. Latent neural dynamics encode temporal context in speech.

Author

Stephen, Emily, Li, Yuanning, Metzger, Sean, Oganian, Yulia, and Chang, Edward

Subjects

Auditory, Electrocorticography, Latent state, Reduced-rank regression, Superior temporal gyrus, Humans, Speech, Speech Perception, Temporal Lobe, Auditory Cortex, Phonetics, Acoustic Stimulation

Abstract

Direct neural recordings from human auditory cortex have demonstrated encoding for acoustic-phonetic features of consonants and vowels. Neural responses also encode distinct acoustic amplitude cues related to timing, such as those that occur at the onset of a sentence after a silent period or the onset of the vowel in each syllable. Here, we used a group reduced rank regression model to show that distributed cortical responses support a low-dimensional latent state representation of temporal context in speech. The timing cues each capture more unique variance than all other phonetic features and exhibit rotational or cyclical dynamics in latent space from activity that is widespread over the superior temporal gyrus. We propose that these spatially distributed timing signals could serve to provide temporal context for, and possibly bind across time, the concurrent processing of individual phonetic features, to compose higher-order phonological (e.g. word-level) representations.

Published

2023

15. Gamma amplitude-envelope correlations are strongly elevated within hyperexcitable networks in focal epilepsy

Author

Manoj Raghavan, Jared Pilet, Chad Carlson, Christopher T. Anderson, Wade Mueller, Sean Lew, Candida Ustine, Priyanka Shah-Basak, Vahab Youssofzadeh, and Scott A. Beardsley

Subjects

Focal epilepsy, Cortical hyperexcitability, Electrocorticography, Functional connectivity, Gamma amplitude envelope correlations, Seizure onset zones, Medicine, Science

Abstract

Abstract Methods to quantify cortical hyperexcitability are of enormous interest for mapping epileptic networks in patients with focal epilepsy. We hypothesize that, in the resting state, cortical hyperexcitability increases firing-rate correlations between neuronal populations within seizure onset zones (SOZs). This hypothesis predicts that in the gamma frequency band (40–200 Hz), amplitude envelope correlations (AECs), a relatively straightforward measure of functional connectivity, should be elevated within SOZs compared to other areas. To test this prediction, we analyzed archived samples of interictal electrocorticographic (ECoG) signals recorded from patients who became seizure-free after surgery targeting SOZs identified by multiday intracranial recordings. We show that in the gamma band, AECs between nodes within SOZs are markedly elevated relative to those elsewhere. AEC-based node strength, eigencentrality, and clustering coefficient are also robustly increased within the SOZ with maxima in the low-gamma band (permutation test Z-scores > 8) and yield moderate discriminability of the SOZ using ROC analysis (maximal mean AUC ~ 0.73). By contrast to AECs, phase locking values (PLVs), a measure of narrow-band phase coupling across sites, and PLV-based graph metrics discriminate the seizure onset nodes weakly. Our results suggest that gamma band AECs may provide a clinically useful marker of cortical hyperexcitability in focal epilepsy.

Published

2024

16. Prospects of Electrocorticography in Neuropharmacological Studies in Small Laboratory Animals.

Author

Sysoev, Yuriy I. and Okovityi, Sergey V.

Subjects

*LABORATORY animals, *PATHOLOGICAL physiology, *ELECTROENCEPHALOGRAPHY, *CEREBRAL cortex, *ANIMAL experimentation

Abstract

Electrophysiological methods of research are widely used in neurobiology. To assess the bioelectrical activity of the brain in small laboratory animals, electrocorticography (ECoG) is most often used, which allows the recording of signals directly from the cerebral cortex. To date, a number of methodological approaches to the manufacture and implantation of ECoG electrodes have been proposed, the complexity of which is determined by experimental tasks and logistical capabilities. Existing methods for analyzing bioelectrical signals are used to assess the functional state of the nervous system in test animals, as well as to identify correlates of pathological changes or pharmacological effects. The review presents current areas of applications of ECoG in neuropharmacological studies in small laboratory animals. Traditionally, this method is actively used to study the antiepileptic activity of new molecules. However, the possibility of using ECoG to assess the neuroprotective activity of drugs in models of traumatic, vascular, metabolic, or neurodegenerative CNS damage remains clearly underestimated. Despite the fact that ECoG has a number of disadvantages and methodological difficulties, the recorded data can be a useful addition to traditional molecular and behavioral research methods. An analysis of the works in recent years indicates a growing interest in the method as a tool for assessing the pharmacological activity of psychoactive drugs, especially in combination with classification and prediction algorithms. [ABSTRACT FROM AUTHOR]

Published

2024

17. Gamma amplitude-envelope correlations are strongly elevated within hyperexcitable networks in focal epilepsy.

Author

Raghavan, Manoj, Pilet, Jared, Carlson, Chad, Anderson, Christopher T., Mueller, Wade, Lew, Sean, Ustine, Candida, Shah-Basak, Priyanka, Youssofzadeh, Vahab, and Beardsley, Scott A.

Subjects

*PARTIAL epilepsy, *PEOPLE with epilepsy, *FUNCTIONAL connectivity, *ELECTROENCEPHALOGRAPHY, *SEIZURES (Medicine)

Abstract

Methods to quantify cortical hyperexcitability are of enormous interest for mapping epileptic networks in patients with focal epilepsy. We hypothesize that, in the resting state, cortical hyperexcitability increases firing-rate correlations between neuronal populations within seizure onset zones (SOZs). This hypothesis predicts that in the gamma frequency band (40–200 Hz), amplitude envelope correlations (AECs), a relatively straightforward measure of functional connectivity, should be elevated within SOZs compared to other areas. To test this prediction, we analyzed archived samples of interictal electrocorticographic (ECoG) signals recorded from patients who became seizure-free after surgery targeting SOZs identified by multiday intracranial recordings. We show that in the gamma band, AECs between nodes within SOZs are markedly elevated relative to those elsewhere. AEC-based node strength, eigencentrality, and clustering coefficient are also robustly increased within the SOZ with maxima in the low-gamma band (permutation test Z-scores > 8) and yield moderate discriminability of the SOZ using ROC analysis (maximal mean AUC ~ 0.73). By contrast to AECs, phase locking values (PLVs), a measure of narrow-band phase coupling across sites, and PLV-based graph metrics discriminate the seizure onset nodes weakly. Our results suggest that gamma band AECs may provide a clinically useful marker of cortical hyperexcitability in focal epilepsy. [ABSTRACT FROM AUTHOR]

Published

2024

18. Can hyperoxic stress cause susceptibility to acute seizure in the neonatal period?: a rat study.

Author

Dilek, Mustafa, Soytürk, Hayriye, Bozat, Gökçe, Hancı, Fatma, Taş, Sinan, and Kabakuş, Nimet

Subjects

*MEDIAN (Mathematics), *SEIZURES (Medicine), *WAVENUMBER, *HYPEROXIA, *RATS

Abstract

Objective: Preterm neonates encounter hyperoxia relatively early, and are more exposed to hyperoxic stress due to their insufficient antioxidant defense mechanisms. This study was planned around the hypothesis that this hyperoxic effect may cause a disposition to future acute seizures. Methods: This study was composed of two main groups Hyperoxy and Control (Room air with normal O2 levels) Groups. Group 1 – hyperoxia (Study): The experimental group consisted of premature newborn rats exposed to hyperoxia with their dams from birth to postnatal day 5. Group 2 – room air (Control): The group was not exposed to hyperoxia and housed the same room air and temperature as their dams. Female, Acute Epilepsy Female, Male, Acute Epilepsy Male, and a total of eight subgroups were formed in both the control and hyperoxia groups. When the rats were two months old, intracranial electrodes were attached to obtain electrocorticography (ECoG) recordings. Pre-model recordings were taken, after which an acute pentylenetetrazole (PTZ) model of absence seizure was induced by the intraperitoneal administration of PTZ at 50 mg/kg. ECoG records were examined using the PowerLab system for 180 min. Spike wave number and duration, Spike wave frequency and amplitude data were evaluated.Results: Seven female and three male rats were exposed to hyperoxia, and a control group of five female and three male rats were included in the study. The median interquartile range for spike wave latency in the hyperoxia and control groups were 1112 (644–1545) and 654 (408–1152), frequency 4476 (3120–7421) and 3934 (2264–4704), and amplitude data 0.68 (0.59–0.79) and 0.52 (0.37–0.67), respectively. Although a difference was observed in median values capable of constituting susceptibility to epilepsy, the difference was not statistically significant (p > 0.05). In terms of gender, spike-wave counts were significantly higher in female rats (p < 0.05). Females exposed to hyperoxia were more susceptible to epilepsy than both males and females in the control group (p < 0.05).Conclusion: Exposure to hyperoxia in the first days of life of premature neonates due to their susceptibility to oxidative stress and insufficient antioxidant mechanisms, can cause a disposition to acute seizures. As a result, females exposed to hyperoxia during the neonatal period may be prone to epilepsy in maturity. [ABSTRACT FROM AUTHOR]

Published

2024

19. The effect of aprepitant, a neurokinin-1 receptor antagonist, on epileptiform activity in the penicillin model of epilepsy.

Author

Cirrik, Selma, Dogan, Eli̇f, Aslan, Ali̇, and Tasci, Ni̇yazi̇

Subjects

SUBSTANCE P receptors, ANTICONVULSANTS, TREATMENT of epilepsy, PENICILLIN, ELECTROENCEPHALOGRAPHY

Abstract

Substance P (SP) is a peptide neurotransmitter that plays a role in pain transmission, stress, inflammation, and emesis through neurokinin-1 receptor (NK-1R). Previous studies of NK-1R antagonists suggest that SP can have either convulsant or anticonvulsant effects. Aprepitant, an NK-1R antagonist, is clinically used to prevent nausea and vomiting in chemotherapy and post-operative patients. However, the effects of aprepitant on epilepsy have not been studied yet. Therefore, the objective of this study was to explore the influence of aprepitant on epileptiform activity in a rat model of epilepsy induced by penicillin. Male Wistar rats, aged 2.5 to 3 months, were divided into 5 groups (n=6): Control, Vehicle, Aprepitant, Substance P, and Aprepitant+Substance P. Aprepitant was administered intragastrically (30 mg/kg) 24 hours and 3 hours before surgery. Substance P (10 pmol) was administered intraventricularly during the surgical procedure. Induction of epileptiform activity was achieved by the injection of penicillin G (500 IU) into the cortex. Electrocorticography (ECoG) recording was conducted online using the PowerLab data acquisition system for over 3 hours. The disparity in spike frequency and amplitude among groups for each 10-minute interval was assessed through One-Way ANOVA and subsequent Tukey post-hoc tests, utilizing the SPSS 15.0 software package. Epileptiform activity was observed in all rats within 3 minutes after the injection of penicillin into the cortex. No significant difference was found between groups in terms of spike frequency and amplitude. When the percentage changes in mean spike frequency and amplitude values were calculated, no significant difference was shown between the groups. Using a penicillin-induced epilepsy model, the present study showed that aprepitant does not affect epileptiform activity in the presence or absence of exogenous SP. Further studies are needed to understand possible anticonvulsant or proconvulsant properties of aprepitant. [ABSTRACT FROM AUTHOR]

Published

2024

20. Camphor alters occipital electrocorticographic patterns during sleep deprivation in Wistar rats

Author

Anthony Lucas Gurgel do Amaral, Gabriela Brito Barbosa, Murilo Farias dos Santos, Luana Vasconcelos de Souza, Rodrigo Gonçalves dos Santos, Tays Mata Câmara, Thaysa de Sousa Reis, Priscille Fidelis Pacheco Hartcopff, Luciana Eiró-Quirino, Clarissa Araújo da Paz, Daniella Bastos de Araújo, Dielly Catrina Favacho Lopes, Miki Taketomi Saito, and Moisés Hamoy

Subjects

camphor, electrocorticography, sleep deprivation, insomnia, neuropharmacology, sleep disorders, Chemistry, QD1-999, Botany, QK1-989

Abstract

IntroductionSleep disorders are common in the general population, necessitating the search for new strategies to address this public health challenge. The study aims to describe the electrocorticographic and behavioral changes in sleep deprived Wistar rats exposed to varying doses of camphor, to assess its effects on sleep and its potential as a sleep-inducing drug.Materials and MethodsFor the electrocorticographic evaluation, seventy-two rats were randomly assigned to distinct groups: a control group, a sleep-deprived group, three sleep-deprived groups receiving 10, 20, and 30 mg/kg i.p. of camphor respectively, and three groups that received these doses without sleep deprivation. For the behavioral analysis, twenty-seven rats were divided into three groups, each receiving the same doses as the previous test.Results and DiscussionOur results showed that there was a decrease in the frequency of brain oscillatory patterns when camphor was administered at 10 mg/kg i.p. whereas there was a dose-dependent increase in the spectral power and distribution following the administration of 20 and 30 mg/kg i.p., with the emergence of Delta, Theta, Alpha, and Beta waves. As for the behavioral analysis, it was demonstrated that testicular relaxation, decreased motility, and light sleep induction also occurred in a dose-dependent manner. Thus, we conclude that camphor administration intensifies occipital electrocorticographic patterns in sleep-deprived rats, and its electrocorticographic and behavioral analysis could indicate a potential as a supporting agent in the insomnia treatment.

Published

2024

21. International Delirium Pathophysiology & Electrophysiology Network for Data sharing (iDEPEND)

Author

Robert D. Sanders, Leiv Watne, Shawniqua Williams Roberson, Eyal Y. Kimchi, Arjen J.C. Slooter, Colm Cunningham, Kirill V. Nourski, Ben J.A. Palanca, Richard Lennertz, and Matthew I. Banks

Subjects

biomarker, collaboration, delirium, electrocorticography, electroencephalography, surgery, Anesthesiology, RD78.3-87.3

Abstract

Summary: In an era of ‘big data’, we propose that a collaborative network approach will drive a better understanding of the mechanisms of delirium, and more rapid development of therapies. We have formed the International Delirium Pathophysiology & Electrophysiology Network for Data sharing (iDEPEND) group with a key aim to ‘facilitate the study of delirium pathogenesis with electrophysiology, imaging, and biomarkers including data acquisition, analysis, and interpretation’. Our initial focus is on studies of electrophysiology as we anticipate this methodology has great potential to enhance our understanding of delirium. Our article describes this principle and is used to highlight the endeavour to the wider community as we establish key stakeholders and partnerships.

Published

2024

22. Recording of hippocampal activity on the effect of convulsant doses of caffeine

Author

Luciana Eiró-Quirino, Felipe Kiyoshi Yoshino, Gloria Calandrini de Amorim, Daniella Bastos de Araújo, Gabriela Brito Barbosa, Luana Vasconcelos de Souza, Murilo Farias dos Santos, Maria Klara Otake Hamoy, Rodrigo Gonçalves dos Santos, Laís Helena Baptista Amóras, Anthony Lucas Gurgel do Amaral, Priscille Fidelis Pacheco Hartcopff, Raíssa Vieira de Souza, Yris da Silva Deiga, and Moisés Hamoy

Subjects

Caffeine, Seizure, Electrocorticography, Hippocampus, Therapeutics. Pharmacology, RM1-950

Abstract

Seizures occur when there is a hyper-excitation of the outer layer of the brain, with subsequent excessive synchrony in a group of neurons. According to the World Health Organization (WHO), an estimated 50 million people are affected by this disease, a third of whom are resistant to the treatments available on the market. Caffeine (1,3,7-trimethylxanthine), which belongs to the purine alkaloid family, is the most widely consumed psychoactive drug in the world. It is ingested by people through drinks containing this substance, such as coffee, and as an adjuvant in analgesic therapy with non-steroidal antiflammatory drugs. The present study evaluated the electrocorticographic changes observed in the hippocampus of Wistar rats subjected to acute doses of caffeine (150 mg/kg i.p), which represents a toxic dose of caffeine corresponding to an estimated acute intake of more than 12 cups of coffee to record its convulsant activity. Our results showed, for the first time, that the administration of high doses of caffeine (150 mg/kg i.p.) in rats caused an increase in the spectral distribution of power in all frequency bands and suggested the appearance of periods of ictal and interictal peaks in the electrocorticogram (ECog). We have also shown that the anticonvulsants phenytoin, diazepam and phenobarbital have a satisfactory response when associated with caffeine.

Published

2024

23. Grasp-specific high-frequency broadband mirror neuron activity during reach-and-grasp movements in humans.

Author

Dreyer, Alexander, Michalke, Leo, Perry, Anat, Knight, Robert, Rieger, Jochem, Chang, Edward, and Lin, Jack

Subjects

ECoG, decoding, mirror neurons, motor, Animals, Humans, Mirror Neurons, Psychomotor Performance, Movement, Electrocorticography, Hand Strength

Abstract

Broadly congruent mirror neurons, responding to any grasp movement, and strictly congruent mirror neurons, responding only to specific grasp movements, have been reported in single-cell studies with primates. Delineating grasp properties in humans is essential to understand the human mirror neuron system with implications for behavior and social cognition. We analyzed electrocorticography data from a natural reach-and-grasp movement observation and delayed imitation task with 3 different natural grasp types of everyday objects. We focused on the classification of grasp types from high-frequency broadband mirror activation patterns found in classic mirror system areas, including sensorimotor, supplementary motor, inferior frontal, and parietal cortices. Classification of grasp types was successful during movement observation and execution intervals but not during movement retention. Our grasp type classification from combined and single mirror electrodes provides evidence for grasp-congruent activity in the human mirror neuron system potentially arising from strictly congruent mirror neurons.

Published

2023

24. Electrochemical and electrophysiological considerations for clinical high channel count neural interfaces

Author

Vatsyayan, Ritwik, Lee, Jihwan, Bourhis, Andrew M, Tchoe, Youngbin, Cleary, Daniel R, Tonsfeldt, Karen J, Lee, Keundong, Montgomery-Walsh, Rhea, Paulk, Angelique C, U, Hoi Sang, Cash, Sydney S, and Dayeh, Shadi A

Subjects

Engineering, Biomedical Engineering, Neurosciences, Bioengineering, Neurological, Electrophysiology, Impedance, Electrocorticography, High-density electrodes, Macromolecular and Materials Chemistry, Materials Engineering, Mechanical Engineering, Applied Physics, Materials engineering, Nanotechnology

Abstract

Electrophysiological recording and stimulation are the gold standard for functional mapping during surgical and therapeutic interventions as well as capturing cellular activity in the intact human brain. A critical component probing human brain activity is the interface material at the electrode contact that electrochemically transduces brain signals to and from free charge carriers in the measurement system. Here, we summarize state-of-the-art electrode array systems in the context of translation for use in recording and stimulating human brain activity. We leverage parametric studies with multiple electrode materials to shed light on the varied levels of suitability to enable high signal-to-noise electrophysiological recordings as well as safe electrophysiological stimulation delivery. We discuss the effects of electrode scaling for recording and stimulation in pursuit of high spatial resolution, channel count electrode interfaces, delineating the electrode-tissue circuit components that dictate the electrode performance. Finally, we summarize recent efforts in the connectorization and packaging for high channel count electrode arrays and provide a brief account of efforts toward wireless neuronal monitoring systems.

Published

2023

25. A novel method for dynamically altering the surface area of intracranial EEG electrodes.

Author

Sindhu, Kavyakantha, Ngo, Duy, Ombao, Hernando, Olaya, Joffre, Shrey, Daniel, and Lopour, Beth

Subjects

electrocorticogram, electrode model, electrode properties, electrode size, interictal epileptiform discharge, intracranial electroencephalogram, power spectrum, Humans, Electrocorticography, Electroencephalography, Brain, Epilepsy, Electrodes

Abstract

Objective.Intracranial electroencephalogram (iEEG) plays a critical role in the treatment of neurological diseases, such as epilepsy and Parkinsons disease, as well as the development of neural prostheses and brain computer interfaces. While electrode geometries vary widely across these applications, the impact of electrode size on iEEG features and morphology is not well understood. Some insight has been gained from computer simulations, as well as experiments in which signals are recorded using electrodes of different sizes concurrently in different brain regions. Here, we introduce a novel method to record from electrodes of different sizes in the exact same location by changing the size of iEEG electrodes after implantation in the brain.Approach.We first present a theoretical model and anin vitrovalidation of the method. We then report the results of anin vivoimplementation in three human subjects with refractory epilepsy. We recorded iEEG data from three different electrode sizes and compared the amplitudes, power spectra, inter-channel correlations, and signal-to-noise ratio (SNR) of interictal epileptiform discharges, i.e. epileptic spikes.Main Results.We found that iEEG amplitude and power decreased as electrode size increased, while inter-channel correlation did not change significantly with electrode size. The SNR of epileptic spikes was generally highest in the smallest electrodes, but 39% of spikes had maximal SNR in larger electrodes. This likely depends on the precise location and spatial spread of each spike.Significance.Overall, this new method enables multi-scale measurements of electrical activity in the human brain that can facilitate our understanding of neurophysiology, treatment of neurological disease, and development of novel technologies.

Published

2023

26. Effect of Electrode Distance and Size on Electrocorticographic Recordings in Human Sensorimotor Cortex

Author

Geukes, Simon H., Branco, Mariana P., Aarnoutse, Erik J., Bekius, Annike, Berezutskaya, Julia, and Ramsey, Nick F.

Published

2024

27. Adaptive Deep Brain Stimulation for sleep stage targeting in Parkinsons disease.

Author

Smyth, Clay, Anjum, Md, Ravi, Shravanan, Denison, Timothy, Starr, Philip, and Little, Simon

Subjects

Adaptive Deep Brain Stimulation, Parkinson’s disease, Real-time neural control, Sleep, Humans, Parkinson Disease, Deep Brain Stimulation, Sleep Stages, Sleep, Electrocorticography

Abstract

BACKGROUND: Sleep dysfunction is disabling in people with Parkinsons disease and is linked to worse motor and non-motor outcomes. Sleep-specific adaptive Deep Brain Stimulation has the potential to target pathophysiologies of sleep. OBJECTIVE: Develop an adaptive Deep Brain Stimulation algorithm that modulates stimulation parameters in response to intracranially classified sleep stages. METHODS: We performed at-home, multi-night intracranial electrocorticography and polysomnogram recordings to train personalized linear classifiers for discriminating the N3 NREM sleep stage. Classifiers were embedded into investigational Deep Brain Stimulators for N3 specific adaptive DBS. RESULTS: We report high specificity of embedded, autonomous, intracranial electrocorticography N3 sleep stage classification across two participants and provide proof-of-principle of successful sleep stage specific adaptive Deep Brain Stimulation. CONCLUSION: Multi-night cortico-basal recordings and sleep specific adaptive Deep Brain Stimulation provide an experimental framework to investigate sleep pathophysiology and mechanistic interactions with stimulation, towards the development of therapeutic neurostimulation paradigms directly targeting sleep dysfunction.

Published

2023

28. Human upper extremity motor cortex activity shows distinct oscillatory signatures for stereotyped arm and leg movements.

Author

Starkweather, Clara, Morrison, Melanie, Yaroshinsky, Maria, Louie, Kenneth, Balakid, Jannine, Presbrey, Kara, Starr, Philip, and Wang, Doris

Subjects

arm swing, cortical oscillations, electrocorticography, stepping, stereotyped movements

Abstract

INTRODUCTION: Stepping and arm swing are stereotyped movements that require coordination across multiple muscle groups. It is not known whether the encoding of these stereotyped movements in the human primary motor cortex is confined to the limbs respective somatotopy. METHODS: We recorded subdural electrocorticography activities from the hand/arm area in the primary motor cortex of 6 subjects undergoing deep brain stimulation surgery for essential tremor and Parkinsons disease who performed stepping (all patients) and arm swing (n = 3 patients) tasks. RESULTS: We show stepping-related low frequency oscillations over the arm area. Furthermore, we show that this oscillatory activity is separable, both in frequency and spatial domains, from gamma band activity changes that occur during arm swing. DISCUSSION: Our study contributes to the growing body of evidence that lower extremity movement may be more broadly represented in the motor cortex, and suggest that it may represent a way to coordinate stereotyped movements across the upper and lower extremities.

Published

2023

29. Intraoperative Neurophysiological Monitoring in Neurosurgery.

Author

Guzzi, Giusy, Ricciuti, Riccardo Antonio, Della Torre, Attilio, Lo Turco, Erica, Lavano, Angelo, Longhini, Federico, and La Torre, Domenico

Subjects

*INTRAOPERATIVE monitoring, *NEUROPHYSIOLOGIC monitoring, *NEUROVASCULAR surgery, *NEUROSURGERY, *MEDICAL personnel, *SPINAL surgery

Abstract

Intraoperative neurophysiological monitoring (IONM) is a crucial advancement in neurosurgery, enhancing procedural safety and precision. This technique involves continuous real-time assessment of neurophysiological signals, aiding surgeons in timely interventions to protect neural structures. In addition to inherent limitations, IONM necessitates a detailed anesthetic plan for accurate signal recording. Given the growing importance of IONM in neurosurgery, we conducted a narrative review including the most relevant studies about the modalities and their application in different fields of neurosurgery. In particular, this review provides insights for all physicians and healthcare professionals unfamiliar with IONM, elucidating commonly used techniques in neurosurgery. In particular, it discusses the roles of IONM in various neurosurgical settings such as tumoral brain resection, neurovascular surgery, epilepsy surgery, spinal surgery, and peripheral nerve surgery. Furthermore, it offers an overview of the anesthesiologic strategies and limitations of techniques essential for the effective implementation of IONM. [ABSTRACT FROM AUTHOR]

Published

2024

30. The effect of propofol on effective brain networks.

Author

van Blooijs, D., Blok, S., Huiskamp, G.J.M., van Eijsden, P., Meijer, H.G.E., and Leijten, F.S.S.

Subjects

*LARGE-scale brain networks, *PROPOFOL, *EVOKED potentials (Electrophysiology), *ELECTRIC stimulation, *EPILEPSY surgery, *PEDIATRIC surgery, *TEMPORAL lobectomy

Abstract

• The number of corticocortical evoked potentials decreases under anesthesia compared to the awake state. • The N1-peak latency is increased under propofol-anesthesia. • The topology of effective networks in awake patients is preserved under anesthesia. We compared the effective networks derived from Single Pulse Electrical Stimulation (SPES) in intracranial electrocorticography (ECoG) of awake epilepsy patients and while under general propofol-anesthesia to investigate the effect of propofol on these brain networks. We included nine patients who underwent ECoG for epilepsy surgery evaluation. We performed SPES when the patient was awake (SPES-clinical) and repeated this under propofol-anesthesia during the surgery in which the ECoG grids were removed (SPES-propofol). We detected the cortico-cortical evoked potentials (CCEPs) with an automatic detector. We constructed two effective networks derived from SPES-clinical and SPES-propofol. We compared three network measures (indegree, outdegree and betweenness centrality), the N1-peak-latency and amplitude of CCEPs between the two effective networks. Fewer CCEPs were observed during SPES-propofol (median: 6.0, range: 0–29) compared to SPES-clinical (median: 10.0, range: 0–36). We found a significant correlation for the indegree, outdegree and betweenness centrality between SPES-clinical and SPES-propofol (respectively r s = 0.77, r s = 0.70, r s = 0.55, p < 0.001). The median N1-peak-latency increased from 22.0 ms during SPES-clinical to 26.4 ms during SPES-propofol. Our findings suggest that the number of effective network connections decreases, but network measures are only marginally affected. The primary network topology is preserved under propofol. [ABSTRACT FROM AUTHOR]

Published

2024

31. Spatiotemporal Dynamics of Successive Activations across the Human Brain during Simple Arithmetic Processing.

Author

Pinheiro-Chagas, Pedro, Sava-Segal, Clara, Akkol, Serdar, Daitch, Amy, and Parvizi, Josef

Subjects

*ARITHMETIC, *DIAGNOSTIC imaging, *FUNCTIONAL connectivity, *INFORMATION resources, *ELECTROENCEPHALOGRAPHY

Abstract

Previous neuroimaging studies have offered unique insights about the spatial organization of activations and deactivations across the brain; however, these were not powered to explore the exact timing of events at the subsecond scale combined with a precise anatomical source of information at the level of individual brains. As a result, we know little about the order of engagement across different brain regions during a given cognitive task. Using experimental arithmetic tasks as a prototype for human-unique symbolic processing, we recorded directly across 10,076 brain sites in 85 human subjects (52% female) using the intracranial electroencephalography. Our data revealed a remarkably distributed change of activity in almost half of the sampled sites. In each activated brain region, we found juxtaposed neuronal populations preferentially responsive to either the target or control conditions, arranged in an anatomically orderly manner. Notably, an orderly successive activation of a set of brain regions--anatomically consistent across subjects--was observed in individual brains. The temporal order of activations across these sites was replicable across subjects and trials. Moreover, the degree of functional connectivity between the sites decreased as a function of temporal distance between regions, suggesting that the information is partially leaked or transformed along the processing chain. Our study complements prior imaging studies by providing hitherto unknown information about the timing of events in the brain during arithmetic processing. Such findings can be a basis for developing mechanistic computational models of human-specific cognitive symbolic systems. [ABSTRACT FROM AUTHOR]

Published

2024

32. Light and the Brain: A Clinical Case Depicting the Effects of Light on Brainwaves and Possible Presence of Plasma-like Brain Energy.

Author

Idris, Zamzuri, Zakaria, Zaitun, Yee, Ang Song, Fitzrol, Diana Noma, Ismail, Muhammad Ihfaz, Ghani, Abdul Rahman Izaini, Abdullah, Jafri Malin, Hassan, Mohd Hasyizan, and Suardi, Nursakinah

Subjects

*THERMAL equilibrium, *BRAIN surgery, *ELECTROMAGNETIC radiation, *PHOTOTHERAPY, *ENERGY function

Abstract

Light is an electromagnetic radiation that has visible and invisible wavelength spectrums. Visible light can only be detected by the eyes through the optic pathways. With the presence of the scalp, cranium, and meninges, the brain is seen as being protected from direct exposure to light. For that reason, the brain can be viewed as a black body lying inside a black box. In physics, a black body tends to be in thermal equilibrium with its environment and can tightly regulate its temperature via thermodynamic principles. Therefore, a healthy brain inside a black box should not be exposed to light. On the contrary, photobiomodulation, a form of light therapy for the brain, has been shown to have beneficial effects on some neurological conditions. The proposed underlying mechanisms are multiple. Herein, we present our intraoperative findings of rapid electrocorticographic brainwave changes when the brain was shone directly with different wavelengths of light during awake brain surgery. Our findings provide literature evidence for light's ability to influence human brain energy and function. Our proposed mechanism for these rapid changes is the presence of plasma-like energy inside the brain, which causes fast brain activities that are akin to lightning strikes. [ABSTRACT FROM AUTHOR]

Published

2024

33. Multiplexed Surface Electrode Arrays Based on Metal Oxide Thin‐Film Electronics for High‐Resolution Cortical Mapping.

Author

Londoño‐Ramírez, Horacio, Huang, Xiaohua, Cools, Jordi, Chrzanowska, Anna, Brunner, Clément, Ballini, Marco, Hoffman, Luis, Steudel, Soeren, Rolin, Cédric, Mora Lopez, Carolina, Genoe, Jan, and Haesler, Sebastian

Subjects

*BRAIN mapping, *EVOKED potentials (Electrophysiology), *SOMATOSENSORY evoked potentials, *ELECTRODES, *BRAIN-computer interfaces, *METALLIC oxides, *INDIUM gallium zinc oxide

Abstract

Electrode grids are used in neuroscience research and clinical practice to record electrical activity from the surface of the brain. However, existing passive electrocorticography (ECoG) technologies are unable to offer both high spatial resolution and wide cortical coverage, while ensuring a compact acquisition system. The electrode count and density are restricted by the fact that each electrode must be individually wired. This work presents an active micro‐electrocorticography (µECoG) implant that tackles this limitation by incorporating metal oxide thin‐film transistors (TFTs) into a flexible electrode array, allowing to address multiple electrodes through a single shared readout line. By combining the array with an incremental‐ΔΣ readout integrated circuit (ROIC), the system is capable of recording from up to 256 electrodes virtually simultaneously, thanks to the implemented 16:1 time‐division multiplexing scheme, offering lower noise levels than existing active µECoG arrays. In vivo validation is demonstrated acutely in mice by recording spontaneous activity and somatosensory evoked potentials over a cortical surface of ≈8×8 mm2. The proposed neural interface overcomes the wiring bottleneck limiting ECoG arrays, holding promise as a powerful tool for improved mapping of the cerebral cortex and as an enabling technology for future brain‐machine interfaces. [ABSTRACT FROM AUTHOR]

Published

2024

34. Clinical utility and safety of a trapezoid-shaped electrode placement for evaluating the mesio-basal temporal lobe during epilepsy surgery.

Author

Kaneko, Satoshi, Inaji, Motoki, Shimizu, Kazuhide, Orihara, Asumi, Hashimoto Fujimoto, Satoka, and Maehara, Taketoshi

Abstract

[Display omitted] • Usefulness of trapezoid-shaped electrode in temporal lobe epilepsy was evaluated. • Seizure freedom in 73% & 50% patients with mTLE & extra-mTLE, respectively. • Significant risk factors are > 64 electrode contacts and male sex, not TSE placement. • TSE is useful for evaluating mTLE in patients undergoing ICE placement. • TSE placement has low complication rate and can be safely used in patients with TLE. A trapezoid-shaped electrode (TSE) is used for detecting epileptogenicity in patients with temporal lobe epilepsy (TLE). However, the utility and safety associated with TSE placement have not been reported. In this study, we evaluated the safety and usefulness of TSE by analyzing the seizure detection, surgical outcomes and complications in patients with TLE who underwent intracranial electrodes (ICE) placement. Between April 2000 and August 2019, 50 patients with TLE who underwent 51 ICE placement procedures were examined. A TSE with eight contacts covering the parahippocampal gyrus and basal temporal lobe was used. Among the 37 patients who underwent TSE placement, 26 and 11 patients were diagnosed with mesial TLE (mTLE) and extra-mTLE, respectively. The 14 remaining patients without TSE placement were diagnosed with extra-mTLE. Seizure freedom was achieved in 73% (19/26) of mTLE patients detected by TSE and 50% (14/24) of extra-mTLE patients.Good seizure outcomes (Engel class I and II) were observed in 81% (21/26) patients with mTLE and 67% (16/24) patients with extra-mTLE. Radiographic complications were observed in 20% (10/50) patients who underwent ICE placement. Although 6% (3/50) patients showed transient neurological deficits, none were permanent. The electrodes responsible for the occurrence of complications included nine grid electrodes and one TSE. The complication rate after TSE placement was 3% (1/37). More than 64 electrode contacts and male sex, not TSE placement, were identified as significant risk factors for developing complications. This study demonstrated the usefulness and safety of TSE for evaluating mTLE in patients undergoing ICE placement. [ABSTRACT FROM AUTHOR]

Published

2024

35. The Effect of Ceftriaxone on Penicillin-Induced Epileptiform Activity in Rats: An Electrophysiological Study.

Author

Acungil, Zeynep Kasap and Özsoy, Şeyma

Subjects

EPILEPSY, CEFTRIAXONE, GLUTAMATE transporters, PENICILLIN, ANTICONVULSANTS

Abstract

Purpose: Epilepsy is a set of chronic neurological disorders characterized by seizures associated with abnormal and uncontrolled neuronal activity of the brain. Glutamate is the main excitatory neurotransmitter in the central nervous system. Excitatory amino acid transporter-2 (EAAT2), one of the major glutamate transporters, is responsible for total glutamate intake. Ceftriaxone is a β-lactam antibiotic that increases EAAT-2 expression and functional activity. This study aims to investigate the effects of ceftriaxone on penicillin-induced epileptiform activity by using electrocorticography (ECoG) in anesthetized rats. Method: In this study, 35 Wistar male rats were used. The rats were divided into five groups of 7. In group 1, 2.5 μL 500 IU of penicillin intracranially (i.c.) and 1 ml saline solution and intraperitoneally (i.p.) were given, respectively. In group 2, 200 mg/kg, i.p. of ceftriaxone was administered 30 minutes after penicillin. In group 3, 400 mg/kg of ceftriaxone was administered i.p. 30 minutes after penicillin. 500 mg/kg of sodium valproate was administered i.p. following 30 minutes of penicillin in group 4. In group 5, 400 mg/kg, i.p. of ceftriaxone and 500 mg/kg, i.p. of sodium valproate were administered 30 minutes after penicillin. After the surgical procedure the rats were placed in a stereotaxic device and electrocorticogram recordings were captured for 210 minutes. Results: The acute treatment of ceftriaxone reduced spike-wave frequency and spike-wave amplitude of penicillin-induced epileptiform activity in the rats. Conclusion: These findings suggest that acute ceftriaxone had an anticonvulsant effect on penicillin-induced focal onset epileptic activity. Ceftriaxone may have an anti-epileptogenic potential. [ABSTRACT FROM AUTHOR]

Published

2024

36. Electrocorticographic Activation Patterns of Electroencephalographic Microstates.

Author

Mikutta, Christian A., Knight, Robert T., Sammler, Daniela, Müller, Thomas J., and Koenig, Thomas

Abstract

Electroencephalography (EEG) microstates are short successive periods of stable scalp field potentials representing spontaneous activation of brain resting-state networks. EEG microstates are assumed to mediate local activity patterns. To test this hypothesis, we correlated momentary global EEG microstate dynamics with the local temporo-spectral evolution of electrocorticography (ECoG) and stereotactic EEG (SEEG) depth electrode recordings. We hypothesized that these correlations involve the gamma band. We also hypothesized that the anatomical locations of these correlations would converge with those of previous studies using either combined functional magnetic resonance imaging (fMRI)-EEG or EEG source localization. We analyzed resting-state data (5 min) of simultaneous noninvasive scalp EEG and invasive ECoG and SEEG recordings of two participants. Data were recorded during the presurgical evaluation of pharmacoresistant epilepsy using subdural and intracranial electrodes. After standard preprocessing, we fitted a set of normative microstate template maps to the scalp EEG data. Using covariance mapping with EEG microstate timelines and ECoG/SEEG temporo-spectral evolutions as inputs, we identified systematic changes in the activation of ECoG/SEEG local field potentials in different frequency bands (theta, alpha, beta, and high-gamma) based on the presence of particular microstate classes. We found significant covariation of ECoG/SEEG spectral amplitudes with microstate timelines in all four frequency bands (p = 0.001, permutation test). The covariance patterns of the ECoG/SEEG electrodes during the different microstates of both participants were similar. To our knowledge, this is the first study to demonstrate distinct activation/deactivation patterns of frequency-domain ECoG local field potentials associated with simultaneous EEG microstates. [ABSTRACT FROM AUTHOR]

Published

2024

37. Widespread ripples synchronize human cortical activity during sleep, waking, and memory recall

Author

Dickey, Charles W, Verzhbinsky, Ilya A, Jiang, Xi, Rosen, Burke Q, Kajfez, Sophie, Stedelin, Brittany, Shih, Jerry J, Ben-Haim, Sharona, Raslan, Ahmed M, Eskandar, Emad N, Gonzalez-Martinez, Jorge, Cash, Sydney S, and Halgren, Eric

Subjects

Clinical Research, Behavioral and Social Science, Basic Behavioral and Social Science, Sleep Research, Mental Health, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Cerebral Cortex, Electrocorticography, Hippocampus, Humans, Memory Consolidation, Mental Recall, Sleep, Wakefulness, ripples, cortex, hippocampus, non-rapid eye movement sleep, waking

Abstract

Declarative memory encoding, consolidation, and retrieval require the integration of elements encoded in widespread cortical locations. The mechanism whereby such "binding" of different components of mental events into unified representations occurs is unknown. The "binding-by-synchrony" theory proposes that distributed encoding areas are bound by synchronous oscillations enabling enhanced communication. However, evidence for such oscillations is sparse. Brief high-frequency oscillations ("ripples") occur in the hippocampus and cortex and help organize memory recall and consolidation. Here, using intracranial recordings in humans, we report that these ∼70-ms-duration, 90-Hz ripples often couple (within ±500 ms), co-occur (≥ 25-ms overlap), and, crucially, phase-lock (have consistent phase lags) between widely distributed focal cortical locations during both sleep and waking, even between hemispheres. Cortical ripple co-occurrence is facilitated through activation across multiple sites, and phase locking increases with more cortical sites corippling. Ripples in all cortical areas co-occur with hippocampal ripples but do not phase-lock with them, further suggesting that cortico-cortical synchrony is mediated by cortico-cortical connections. Ripple phase lags vary across sleep nights, consistent with participation in different networks. During waking, we show that hippocampo-cortical and cortico-cortical coripples increase preceding successful delayed memory recall, when binding between the cue and response is essential. Ripples increase and phase-modulate unit firing, and coripples increase high-frequency correlations between areas, suggesting synchronized unit spiking facilitating information exchange. co-occurrence, phase synchrony, and high-frequency correlation are maintained with little decrement over very long distances (25 cm). Hippocampo-cortico-cortical coripples appear to possess the essential properties necessary to support binding by synchrony during memory retrieval and perhaps generally in cognition.

Published

2022

38. Neural Processing of Speech Using Intracranial Electroencephalography: Sound Representations in the Auditory Cortex

Author

Hamilton, Liberty S.

Published

2024

39. Intraoperative language mapping guided by real-time visualization of gamma band modulation electrocorticograms: Case report and proof of concept.

Author

Noll, Kyle R, Asman, Priscella, Tasnim, Israt, Hall, Matthew, Connelly, Katherine, Swamy, Chandra, Ene, Chibawanye, Tummala, Sudhakar, Grasu, Roxana M, Liu, Ho-Ling, Kumar, Vinodh A, Muir, Matthew, Prinsloo, Sarah, Michener, Hayley, Wefel, Jeffrey S, Ince, Nuri F, and Prabhu, Sujit S

Subjects

*TEMPORAL lobe, *PROOF of concept, *DATA visualization, *FUNCTIONAL magnetic resonance imaging

Abstract

Background Electrocorticography (ECoG) language mapping is often performed extraoperatively, frequently involves offline processing, and relationships with direct cortical stimulation (DCS) remain variable. We sought to determine the feasibility and preliminary utility of an intraoperative language mapping approach guided by real-time visualization of electrocorticograms. Methods A patient with astrocytoma underwent awake craniotomy with intraoperative language mapping, utilizing a dual iPad stimulus presentation system coupled to a real-time neural signal processing platform capable of both ECoG recording and delivery of DCS. Gamma band modulations in response to 4 language tasks at each electrode were visualized in real-time. Next, DCS was conducted for each neighboring electrode pair during language tasks. Results All language tasks resulted in strongest heat map activation at an electrode pair in the anterior to mid superior temporal gyrus. Consistent speech arrest during DCS was observed for Object and Action naming tasks at these same electrodes, indicating good correspondence with ECoG heat map recordings. This region corresponded well with posterior language representation via preoperative functional MRI. Conclusions Intraoperative real-time visualization of language task-based ECoG gamma band modulation is feasible and may help identify targets for DCS. If validated, this may improve the efficiency and accuracy of intraoperative language mapping. [ABSTRACT FROM AUTHOR]

Published

2024

40. Unraveling tactile categorization and decision-making in the subregions of supramarginal gyrus via direct cortical stimulation.

Author

Lee, Dong Hyeok, Chung, Chun Kee, Kim, June Sic, and Ryun, Seokyun

Subjects

*PARIETAL lobe, *DECISION making, *COGNITIVE maps (Psychology), *COGNITIVE ability, *BRAIN mapping

Abstract

• Direct stimulation affected the subregions responsible for cognitive processes. • Cognitive processes were linked to changes in gamma power. • Direct cortical stimulation has the potential to enhance cognitive processes. This study aims to investigate the potential of direct cortical stimulation (DCS) to modulate tactile categorization and decision-making, as well as to identify the specific locations where these cognitive functions occur. We analyzed behavioral changes in three epilepsy patients with implanted electrodes using electrocorticography (ECoG) and a vibrotactile discrimination task. DCS was applied to investigate its impact on tactile categorization and decision-making processes. We determined the precise location of the electrodes where each cognitive function was modulated. This functional discrimination was related with gamma band activity from ECoG. DCS selectively affected either tactile categorization or decision-making processes. Tactile categorization was modulated by stimulating the rostral part of the supramarginal gyrus, while decision-making was modulated by stimulating the caudal part. DCS can enhance cognitive processes and map brain regions responsible for tactile categorization and decision-making within the supramarginal gyrus. This study also demonstrates that DCS and the gamma activity of ECoG can concordantly identify the detailed brain mapping in a tactile process compared to other functional neuroimaging. The combination of DCS and ECoG gamma activity provides a more nuanced and detailed understanding of brain function than traditional neuroimaging techniques alone. [ABSTRACT FROM AUTHOR]

Published

2024

41. Discrete tactile feature comparison subprocess in human brain during a decision-making process.

Author

Lee, Dong Hyeok, Kim, June Sic, Ryun, Seokyun, and Chung, Chun Kee

Subjects

SOMATOSENSORY disorders, DECISION making, ELECTROENCEPHALOGRAPHY, TACTILE adaptation, CEREBRAL cortex

Published

2024

42. Early Postoperative Seizures Following Awake Craniotomy and Functional Brain Mapping for Lesionectomy.

Author

Freund, Brin E., Feyissa, Anteneh M., Khan, Aafreen, Middlebrooks, Erik H., Grewal, Sanjeet S., Sabsevitz, David, Sherman, Wendy J., Quiñones-Hinojosa, Alfredo, and Tatum, William O.

Subjects

*CRANIOTOMY, *BRAIN mapping, *SEIZURES (Medicine), *SUBARACHNOID hemorrhage, *ELECTRIC stimulation, *MEDICAL personnel

Abstract

Awake craniotomy with electrocorticography (ECoG) and direct electrical stimulation (DES) facilitates lesionectomy while avoiding adverse effects. Early postoperative seizures (EPS), occurring within 7 days following surgery, can lead to morbidity. However, risk factors for EPS after awake craniotomy including clinical and ECoG data are not well defined. We retrospectively studied the incidence and risk factors of EPS following awake craniotomy for lesionectomy, and report short-term outcomes between January 1, 2020, and December 31, 2022. We included 138 patients (56 female) who underwent 142 awake craniotomies, average age was 50.78 ± 15.97 years. Eighty-eight (63.7%) patients had a preoperative history of tumor-related epilepsy treated with antiseizure medication (ASM), 12 (13.6%) with drug-resistance. All others (36.3%) received ASM prophylaxis with levetiracetam perioperatively and continued for 14 days. An equal number of cases (71) each utilized a novel circle grid or strip electrodes for ECoG. There were 31 (21.8%) cases of intraoperative seizures, 16 with EPS (11.3%). Acute abnormality on early postoperative neuroimaging (P = 0.01), subarachnoid hemorrhage (P = 0.01), young age (P = 0.01), and persistent postoperative neurologic deficits (P = 0.013) were associated with EPS. Acute abnormality on neuroimaging remained significant in multivariate analysis. Outcomes during hospitalization and early outpatient follow up were worse with EPS. We report novel findings using ECoG and clinical features to predict EPS, including acute perioperative brain injury, persistent postoperative deficits and young age. Given worse outcomes with EPS, clinical indicators for EPS should alert clinicians of potential need for early postoperative EEG monitoring and perioperative ASM adjustment. [ABSTRACT FROM AUTHOR]

Published

2024

43. Rapid Passive Gamma Mapping as an Adjunct to Electrical Stimulation Mapping for Functional Localization in Resection of Primary Brain Neoplasms.

Author

Tan, Hao, Nugent, Joseph G., Fecker, Adeline, Richie, Emma A., Maanum, Kayla A., Nerison, Caleb, Bowden, Stephen G., Yaylali, Ilker, Han, Seunggu J., Colgan, Dana D., Oken, Barry, and Raslan, Ahmed M.

Subjects

*CRANIOTOMY, *ELECTRIC stimulation, *BRAIN tumors, *KARNOFSKY Performance Status, *BRAIN mapping, *SURVIVAL rate

Abstract

We examined the utility of passive high gamma mapping (HGM) as an adjunct to conventional awake brain mapping during glioma resection. We compared functional and survival outcomes before and after implementing intraoperative HGM. This was a retrospective cohort study of 75 patients who underwent a first-time, awake craniotomy for glioma resection. Patients were stratified by whether their operation occurred before or after the implementation of a U.S. Food and Drug Administration−approved high-gamma mapping tool in July 2017. The preimplementation and postimplementation cohorts included 28 and 47 patients, respectively. Median intraoperative time (261 vs. 261 minutes, P = 0.250) and extent of resection (97.14% vs. 98.19%, P = 0.481) were comparable between cohorts. Median Karnofsky performance status at initial follow-up was similar between cohorts (P = 0.650). Multivariable Cox regression models demonstrated an adjusted hazard ratio for overall survival of 0.10 (95% confidence interval: 0.02–0.43, P = 0.002) for the postimplementation cohort relative to the preimplementation cohort. Progression-free survival adjusted for insular involvement showed an adjusted hazard ratio of 1.00 (95% confidence interval: 0.49–2.06, P = 0.999) following HGM implementation. Falling short of statistical significance, prevalence of intraoperative seizures and/or afterdischarges decreased after HGM implementation as well (12.7% vs. 25%, P = 0.150). Our results tentatively indicate that passive HGM is a safe and potentially useful adjunct to electrical stimulation mapping for awake cortical mapping, conferring at least comparable functional and survival outcomes with a nonsignificant lower rate of intraoperative epileptiform events. Considering the limitations of our study design and patient cohort, further investigation is needed to better identify optimal use cases for HGM. [ABSTRACT FROM AUTHOR]

Published

2024

44. Thermosensitive/thermochromic silicone and infrared thermography mapping in 60 consecutive cases of epilepsy surgery.

Author

de Font-Réaulx, Enrique, Solis-Santamaria, Andrea, Arch-Tirado, Emilio, and González-Astiazarán, Adalberto

Subjects

EPILEPSY surgery, INFRARED cameras, SURGICAL indications, THERMOGRAPHY, OPERATIVE surgery, MEDICAL thermography

Abstract

Background: Epilepsy surgery represents a therapeutic opportunity for those patients who do not respond to drug therapy. However, an important challenge is the precise identification of the epileptogenic area during surgery. Since it can be hard to delineate, it makes it necessary to use auxiliary tools as a guide during the surgical procedure. Electrocorticography (ECoG), despite having shown favorable results in terms of reducing post-surgical seizures, have certain limitations. Brain mapping using infrared thermography mapping and a new thermosensitive/thermochromic silicone (TTS) in epilepsy surgery has introduced a new resource of noninvasive and real-time devices that allow the localization of irritative zones. Methods: Sixty consecutive patients with drug-resistant epilepsy with surgical indications who decided to participate voluntarily in the study were included in the study. We measured brain temperature using two quantitative methods and a qualitative method: the TTS sheet. In all cases, we used ECoG as the gold standard to identify irritative areas, and all brain tissue samples obtained were sent to pathology for diagnosis. Results: In the subgroup in which the ECoG detected irritative areas (n = 51), adding the results in which there was a correlation with the different methods, the efficiency obtained to detect irritative areas is 94.11% (n = 48/51, P = 0.0001) while the infrared thermography mapping method independently has an efficiency of 91.66% (P = 0.0001). The TTS has a sensitivity of 95.71% and a specificity of 97.9% (P = 0.0001) to detect hypothermic areas that correlate with the irritative zones detected by ECoG. No postoperative infections or wound dehiscence were documented, so the different methodologies used do not represent an additional risk for the surgical proceedings. Conclusion: We consider that the infrared thermography mapping using high-resolution infrared thermography cameras and the TTS are both accurate and safe methods to identify irritative areas in epilepsy surgeries. [ABSTRACT FROM AUTHOR]

Published

2024

45. Multiplexed Surface Electrode Arrays Based on Metal Oxide Thin‐Film Electronics for High‐Resolution Cortical Mapping

Author

Horacio Londoño‐Ramírez, Xiaohua Huang, Jordi Cools, Anna Chrzanowska, Clément Brunner, Marco Ballini, Luis Hoffman, Soeren Steudel, Cédric Rolin, Carolina Mora Lopez, Jan Genoe, and Sebastian Haesler

Subjects

µECoGs, a‐IGZO, electrocorticography, electrode arrays, flexible electronics, thin‐film transistors, Science

Abstract

Abstract Electrode grids are used in neuroscience research and clinical practice to record electrical activity from the surface of the brain. However, existing passive electrocorticography (ECoG) technologies are unable to offer both high spatial resolution and wide cortical coverage, while ensuring a compact acquisition system. The electrode count and density are restricted by the fact that each electrode must be individually wired. This work presents an active micro‐electrocorticography (µECoG) implant that tackles this limitation by incorporating metal oxide thin‐film transistors (TFTs) into a flexible electrode array, allowing to address multiple electrodes through a single shared readout line. By combining the array with an incremental‐ΔΣ readout integrated circuit (ROIC), the system is capable of recording from up to 256 electrodes virtually simultaneously, thanks to the implemented 16:1 time‐division multiplexing scheme, offering lower noise levels than existing active µECoG arrays. In vivo validation is demonstrated acutely in mice by recording spontaneous activity and somatosensory evoked potentials over a cortical surface of ≈8×8 mm2. The proposed neural interface overcomes the wiring bottleneck limiting ECoG arrays, holding promise as a powerful tool for improved mapping of the cerebral cortex and as an enabling technology for future brain‐machine interfaces.

Published

2024

46. Columnar Localization and Laminar Origin of Cortical Surface Electrical Potentials.

Author

Baratham, Vyassa L, Dougherty, Maximilian E, Hermiz, John, Ledochowitsch, Peter, Maharbiz, Michel M, and Bouchard, Kristofer E

Subjects

Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Animals, Auditory Cortex, Brain, Brain Mapping, Electrocorticography, Neurons, Rats, auditory cortex, biophysical simulation, cortical column, neurophysiology, origins of ECoG, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Electrocorticography (ECoG) methodologically bridges basic neuroscience and understanding of human brains in health and disease. However, the localization of ECoG signals across the surface of the brain and the spatial distribution of their generating neuronal sources are poorly understood. To address this gap, we recorded from rat auditory cortex using customized μECoG, and simulated cortical surface electrical potentials with a full-scale, biophysically detailed cortical column model. Experimentally, μECoG-derived auditory representations were tonotopically organized and signals were anisotropically localized to less than or equal to ±200 μm, that is, a single cortical column. Biophysical simulations reproduce experimental findings and indicate that neurons in cortical layers V and VI contribute ∼85% of evoked high-gamma signal recorded at the surface. Cell number and synchrony were the primary biophysical properties determining laminar contributions to evoked μECoG signals, whereas distance was only a minimal factor. Thus, evoked μECoG signals primarily originate from neurons in the infragranular layers of a single cortical column.SIGNIFICANCE STATEMENT ECoG methodologically bridges basic neuroscience and understanding of human brains in health and disease. However, the localization of ECoG signals across the surface of the brain and the spatial distribution of their generating neuronal sources are poorly understood. We investigated the localization and origins of sensory-evoked ECoG responses. We experimentally found that ECoG responses were anisotropically localized to a cortical column. Biophysically detailed simulations revealed that neurons in layers V and VI were the primary sources of evoked ECoG responses. These results indicate that evoked ECoG high-gamma responses are primarily generated by the population spike rate of pyramidal neurons in layers V and VI of single cortical columns and highlight the possibility of understanding how microscopic sources produce mesoscale signals.

Published

2022

47. Intracranial electroencephalographic biomarker predicts effective responsive neurostimulation for epilepsy prior to treatment

Author

Scheid, Brittany H, Bernabei, John M, Khambhati, Ankit N, Mouchtaris, Sofia, Jeschke, Jay, Bassett, Dani S, Becker, Danielle, Davis, Kathryn A, Lucas, Timothy, Doyle, Werner, Chang, Edward F, Friedman, Daniel, Rao, Vikram R, and Litt, Brian

Subjects

Brain Disorders, Neurosciences, Clinical Research, Epilepsy, Neurodegenerative, Detection, screening and diagnosis, 4.2 Evaluation of markers and technologies, 4.1 Discovery and preclinical testing of markers and technologies, Neurological, Biomarkers, Drug Resistant Epilepsy, Electrocorticography, Humans, Retrospective Studies, functional connectivity, multicenter, network neuroscience, neuromodulation, synchronizability, Clinical Sciences, Neurology & Neurosurgery

Abstract

ObjectiveDespite the overall success of responsive neurostimulation (RNS) therapy for drug-resistant focal epilepsy, clinical outcomes in individuals vary significantly and are hard to predict. Biomarkers that indicate the clinical efficacy of RNS-ideally before device implantation-are critically needed, but challenges include the intrinsic heterogeneity of the RNS patient population and variability in clinical management across epilepsy centers. The aim of this study is to use a multicenter dataset to evaluate a candidate biomarker from intracranial electroencephalographic (iEEG) recordings that predicts clinical outcome with subsequent RNS therapy.MethodsWe assembled a federated dataset of iEEG recordings, collected prior to RNS implantation, from a retrospective cohort of 30 patients across three major epilepsy centers. Using ictal iEEG recordings, each center independently calculated network synchronizability, a candidate biomarker indicating the susceptibility of epileptic brain networks to RNS therapy.ResultsIctal measures of synchronizability in the high-γ band (95-105 Hz) significantly distinguish between good and poor RNS responders after at least 3 years of therapy under the current RNS therapy guidelines (area under the curve = .83). Additionally, ictal high-γ synchronizability is inversely associated with the degree of therapeutic response.SignificanceThis study provides a proof-of-concept roadmap for collaborative biomarker evaluation in federated data, where practical considerations impede full data sharing across centers. Our results suggest that network synchronizability can help predict therapeutic response to RNS therapy. With further validation, this biomarker could facilitate patient selection and help avert a costly, invasive intervention in patients who are unlikely to benefit.

Published

2022

48. A Digitally Assisted Multiplexed Neural Recording System With Dynamic Electrode Offset Cancellation via an LMS Interference-Canceling Filter

Author

Fathy, Nader Sherif Kassem, Huang, Jiannan, and Mercier, Patrick P

Subjects

Affordable and Clean Energy, Time division multiple access, Electrodes, Frequency division multiaccess, Codes, Capacitors, System-on-chip, Demodulation, Digitally assisted least mean square (LMS) filter, electrocorticography, microelectronic implants brain-machine interface, neural recording, time-division multiple access, Condensed Matter Physics, Electrical and Electronic Engineering, Other Technology, Electrical & Electronic Engineering

Published

2022

49. Left hemisphere dominance for bilateral kinematic encoding in the human brain.

Author

Merrick, Christina M, Dixon, Tanner C, Breska, Assaf, Lin, Jack, Chang, Edward F, King-Stephens, David, Laxer, Kenneth D, Weber, Peter B, Carmena, Jose, Thomas Knight, Robert, and Ivry, Richard B

Subjects

Brain, Humans, Psychomotor Performance, Movement, Functional Laterality, Biomechanical Phenomena, Electrocorticography, electrocorticography, human, ipsilateral, lateralization, left hemisphere, motor control, neuroscience, praxis, Clinical Research, Neurosciences, Neurological, Human, Biochemistry and Cell Biology

Abstract

Neurophysiological studies in humans and nonhuman primates have revealed movement representations in both the contralateral and ipsilateral hemispheres. Inspired by clinical observations, we ask if this bilateral representation differs for the left and right hemispheres. Electrocorticography was recorded in human participants during an instructed-delay reaching task, with movements produced with either the contralateral or ipsilateral arm. Using a cross-validated kinematic encoding model, we found stronger bilateral encoding in the left hemisphere, an effect that was present during preparation and was amplified during execution. Consistent with this asymmetry, we also observed better across-arm generalization in the left hemisphere, indicating similar neural representations for right and left arm movements. Notably, these left hemisphere electrodes were centered over premotor and parietal regions. The more extensive bilateral encoding in the left hemisphere adds a new perspective to the pervasive neuropsychological finding that the left hemisphere plays a dominant role in praxis.

Published

2022

50. Beyond rates: time-varying dynamics of high frequency oscillations as a biomarker of the seizure onset zone

Author

Nunez, Michael D, Charupanit, Krit, Sen-Gupta, Indranil, Lopour, Beth A, and Lin, Jack J

Subjects

Epilepsy, Neurosciences, Neurodegenerative, Brain Disorders, Clinical Research, Sleep Research, Neurological, Biomarkers, Electrocorticography, Electroencephalography, Humans, Seizures, epilepsy, surgery, hierarchical Bayesian methods, epileptogenic zone, high-frequency oscillations, ripple, intracranial EEG, Biomedical Engineering, Clinical Sciences

Abstract

Objective. High frequency oscillations (HFOs) recorded by intracranial electrodes have generated excitement for their potential to help localize epileptic tissue for surgical resection. However, the number of HFOs per minute (i.e. the HFO 'rate') is not stable over the duration of intracranial recordings; for example, the rate of HFOs increases during periods of slow-wave sleep. Moreover, HFOs that are predictive of epileptic tissue may occur in oscillatory patterns due to phase coupling with lower frequencies. Therefore, we sought to further characterize between-seizure (i.e. 'interictal') HFO dynamics both within and outside the seizure onset zone (SOZ).Approach. Using long-term intracranial EEG (mean duration 10.3 h) from 16 patients, we automatically detected HFOs using a new algorithm. We then fit a hierarchical negative binomial model to the HFO counts. To account for differences in HFO dynamics and rates between sleep and wakefulness, we also fit a mixture model to the same data that included the ability to switch between two discrete brain states that were automatically determined during the fitting process. The ability to predict the SOZ by model parameters describing HFO dynamics (i.e. clumping coefficients and coefficients of variation) was assessed using receiver operating characteristic curves.Main results. Parameters that described HFO dynamics were predictive of SOZ. In fact, these parameters were found to be more consistently predictive than HFO rate. Using concurrent scalp EEG in two patients, we show that the model-found brain states corresponded to (1) non-REM sleep and (2) awake and rapid eye movement sleep. However the brain state most likely corresponding to slow-wave sleep in the second model improved SOZ prediction compared to the first model for only some patients.Significance. This work suggests that delineation of SOZ with interictal data can be improved by the inclusion of time-varying HFO dynamics.

Published

2022