Your search keyword '"electrocorticography"' showing total 6,380 results

151. Less-invasive subdural electrocorticography for investigation of spreading depolarizations in patients with subarachnoid hemorrhage.

Author

Meinert, Franziska, Lemâle, Coline L., Major, Sebastian, Helgers, Simeon O. A., Dömer, Patrick, Mencke, Rik, Bergold, Martin N., Dreier, Jens P., Hecht, Nils, and Woitzik, Johannes

Subjects

SUBARACHNOID hemorrhage, CLINICAL trials, ELECTROENCEPHALOGRAPHY, INDEPENDENT variables, BRAIN damage

Abstract

Introduction: Wyler-strip electrodes for subdural electrocorticography (ECoG) are the gold standard for continuous bed-side monitoring of pathological cortical network events, such as spreading depolarizations (SD) and electrographic seizures. Recently, SD associated parameters were shown to be (1) a marker of early brain damage after aneurysmal subarachnoid hemorrhage (aSAH), (2) the strongest real-time predictor of delayed cerebral ischemia currently known, and (3) the second strongest predictor of patient outcome at 7months. The strongest predictor of patient outcome at 7months was focal brain damage segmented on neuroimaging 2 weeks after the initial hemorrhage, whereas the initial focal brain damage was inferior to the SD variables as a predictor for patient outcome. However, the implantation of Wyler-strip electrodes typically requires either a craniotomy or an enlarged burr hole. Neuromonitoring via an enlarged burr hole has been performed in only about 10% of the total patients monitored. Methods: In the present pilot study, we investigated the feasibility of ECoG monitoring via a less invasive burrhole approach using a Spencer- type electrode array, which was implanted subdurally rather than in the depth of the parenchyma. Seven aSAH patients requiring extraventricular drainage (EVD) were included. For electrode placement, the burr hole over which the EVD was simultaneously placed, was used in all cases. After electrode implantation, continuous, direct current (DC)/alternating current (AC)-ECoG monitoring was performed at bedside in our Neurointensive Care unit. ECoGs were analyzed following the recommendations of the Co-Operative Studies on Brain Injury Depolarizations (COSBID). Results: Subdural Spencer-type electrode arrays permitted high-quality ECoG recording. During a cumulative monitoring period of 1,194.5 hours and a medianmonitoring period of 201.3 (interquartile range: 126.1-209.4) hours per patient, 84 SDs were identified. Numbers of SDs, isoelectric SDs and clustered SDs per recording day, and peak total SD-induced depression duration of a recording day were not significantly different from the previously reported results of the prospective, observational,multicenter, cohort, diagnostic phase III trial, DISCHARGE-1. No adverse events related to electrode implantation were noted. Discussion: In conclusion, our findings support the safety and feasibility of less-invasive subdural electrode implantation for reliable SD-monitoring. [ABSTRACT FROM AUTHOR]

Published

2023

152. Reliability of visual review of intracranial electroencephalogram in identifying the seizure onset zone: A systematic review and implications for the accuracy of automated methods.

Author

Flanary, James, Daly, Sam, Bakker, Caitlin, Herman, Alexander B., Park, Michael C., McGovern, Robert, Walczak, Thaddeus, Henry, Thomas, Netoff, Theoden I., and Darrow, David P.

Subjects

*EPILEPSY, *TEMPORAL lobe epilepsy, *TEMPORAL lobectomy, *SEIZURES (Medicine), *ELECTROENCEPHALOGRAPHY, *EPILEPSY surgery, *SURGICAL excision

Abstract

Visual review of intracranial electroencephalography (iEEG) is often an essential component for defining the zone of resection for epilepsy surgery. Unsupervised approaches using machine and deep learning are being employed to identify seizure onset zones (SOZs). This prompts a more comprehensive understanding of the reliability of visual review as a reference standard. We sought to summarize existing evidence on the reliability of visual review of iEEG in defining the SOZ for patients undergoing surgical workup and understand its implications for algorithm accuracy for SOZ prediction. We performed a systematic literature review on the reliability of determining the SOZ by visual inspection of iEEG in accordance with best practices. Searches included MEDLINE, Embase, Cochrane Library, and Web of Science on May 8, 2022. We included studies with a quantitative reliability assessment within or between observers. Risk of bias assessment was performed with QUADAS‐2. A model was developed to estimate the effect of Cohen kappa on the maximum possible accuracy for any algorithm detecting the SOZ. Two thousand three hundred thirty‐eight articles were identified and evaluated, of which one met inclusion criteria. This study assessed reliability between two reviewers for 10 patients with temporal lobe epilepsy and found a kappa of.80. These limited data were used to model the maximum accuracy of automated methods. For a hypothetical algorithm that is 100% accurate to the ground truth, the maximum accuracy modeled with a Cohen kappa of.8 ranged from.60 to.85 (F‐2). The reliability of reviewing iEEG to localize the SOZ has been evaluated only in a small sample of patients with methodologic limitations. The ability of any algorithm to estimate the SOZ is notably limited by the reliability of iEEG interpretation. We acknowledge practical limitations of rigorous reliability analysis, and we propose design characteristics and study questions to further investigate reliability. [ABSTRACT FROM AUTHOR]

Published

2023

153. Effects of chronic administration of thymoquinone on penicillin induced epileptiform activity in rats.

Author

Beyazcicek, Ersin, Avci, Duru Aslihan, and Beyazcicek, Ozge

Subjects

PENICILLIN, ANTIOXIDANTS, EPILEPSY, ELECTROENCEPHALOGRAPHY, AMPLITUDE estimation

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

2023

154. Decoding micro-electrocorticographic signals by using explainable 3D convolutional neural network to predict finger movements.

Author

Kuo, Chao-Hung, Liu, Guan-Tze, Lee, Chi-En, Wu, Jing, Casimo, Kaitlyn, Weaver, Kurt E., Lo, Yu-Chun, Chen, You-Yin, Huang, Wen-Cheng, and Ojemann, Jeffrey G.

Subjects

*CONVOLUTIONAL neural networks, *MACHINE learning, *DEEP learning, *BRAIN-computer interfaces, *FEATURE extraction

Abstract

Electroencephalography (EEG) and electrocorticography (ECoG) recordings have been used to decode finger movements by analyzing brain activity. Traditional methods focused on single bandpass power changes for movement decoding, utilizing machine learning models requiring manual feature extraction. This study introduces a 3D convolutional neural network (3D-CNN) model to decode finger movements using ECoG data. The model employs adaptive, explainable AI (xAI) techniques to interpret the physiological relevance of brain signals. ECoG signals from epilepsy patients during awake craniotomy were processed to extract power spectral density across multiple frequency bands. These data formed a 3D matrix used to train the 3D-CNN to predict finger trajectories. The 3D-CNN model showed significant accuracy in predicting finger movements, with root-mean-square error (RMSE) values of 0.26–0.38 for single finger movements and 0.20–0.24 for combined movements. Explainable AI techniques, Grad-CAM and SHAP, identified the high gamma (HG) band as crucial for movement prediction, showing specific cortical regions involved in different finger movements. These findings highlighted the physiological significance of the HG band in motor control. The 3D-CNN model outperformed traditional machine learning approaches by effectively capturing spatial and temporal patterns in ECoG data. The use of xAI techniques provided clearer insights into the model's decision-making process, unlike the "black box" nature of standard deep learning models. The proposed 3D-CNN model, combined with xAI methods, enhances the decoding accuracy of finger movements from ECoG data. This approach offers a more efficient and interpretable solution for brain-computer interface (BCI) applications, emphasizing the HG band's role in motor control. • Micro-ECoG signals from epilepsy patients were recorded during awake craniotomy. • Signals were processed using detrending, denoising, and frequency band analysis. • A 3D-CNN model was trained to predict finger movements from ECoG data. • Grad-CAM and SHAP values were used to explain the 3D-CNN model's predictions. • High gamma band (HG) was significant in predicting thumb and index movements. [ABSTRACT FROM AUTHOR]

Published

2024

155. A shared model-based linguistic space for transmitting our thoughts from brain to brain in natural conversations.

Author

Zada, Zaid, Goldstein, Ariel, Michelmann, Sebastian, Simony, Erez, Price, Amy, Hasenfratz, Liat, Barham, Emily, Zadbood, Asieh, Doyle, Werner, Friedman, Daniel, Dugan, Patricia, Melloni, Lucia, Devore, Sasha, Flinker, Adeen, Devinsky, Orrin, Nastase, Samuel A., and Hasson, Uri

Subjects

*LANGUAGE models, *NATURAL language processing, *LINGUISTIC models, *INTERSTELLAR communication, *SPEECH

Abstract

Effective communication hinges on a mutual understanding of word meaning in different contexts. We recorded brain activity using electrocorticography during spontaneous, face-to-face conversations in five pairs of epilepsy patients. We developed a model-based coupling framework that aligns brain activity in both speaker and listener to a shared embedding space from a large language model (LLM). The context-sensitive LLM embeddings allow us to track the exchange of linguistic information, word by word, from one brain to another in natural conversations. Linguistic content emerges in the speaker's brain before word articulation and rapidly re-emerges in the listener's brain after word articulation. The contextual embeddings better capture word-by-word neural alignment between speaker and listener than syntactic and articulatory models. Our findings indicate that the contextual embeddings learned by LLMs can serve as an explicit numerical model of the shared, context-rich meaning space humans use to communicate their thoughts to one another. • We acquired intracranial recordings in five dyads during face-to-face conversations • Large language models can serve as a shared linguistic space for communication • Context-sensitive embeddings track the exchange of information from brain to brain • Contextual embeddings outperform other models for speaker-listener coupling Zada et al. use contextual embeddings from large language models to capture linguistic information transmitted from the speaker's brain to the listener's brain in real-time, dyadic conversations. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

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

Subjects

*PSYCHIATRIC drugs, *LABORATORY rats, *ANTICONVULSANTS, *COFFEE cups, *CAFFEINE

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. [ABSTRACT FROM AUTHOR]

Published

2024

157. Passive Intraoperative Language Mapping Using Electrocorticographic Signals

Author

Sinkin, M. V., Volkova, K. V., Kondratova, M. S., Voskoboynikov, A. M., Lebedev, M. A., Ivanova, M. D., Ossadtchi, A. E., Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, Velichkovsky, Boris M., editor, Balaban, Pavel M., editor, and Ushakov, Vadim L., editor

Published

2021

158. Seizures in the Operating Room

Author

Ritaccio, Anthony, Tatum, William O., editor, Sirven, Joseph I., editor, and Cascino, Gregory D., editor

Published

2021

159. Brain Tumor-Related Epilepsy

Author

Feyissa, Anteneh M., Tatum, William O., editor, Sirven, Joseph I., editor, and Cascino, Gregory D., editor

Published

2021

160. Phase- targeted stimulation modulates phase-amplitude coupling in the motor cortex of the human brain

Author

Yousef Salimpour, Kelly A. Mills, Brian Y. Hwang, and William S. Anderson

Subjects

Phase-targeted stimulation, Cross-frequency coupling, Phase-amplitude coupling, Electrocorticography, Neuromodulation, Motor cortex, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Background: Phase-amplitude coupling (PAC) in which the amplitude of a faster field potential oscillation is coupled to the phase of a slower rhythm, is one of the most well-studied interactions between oscillations at different frequency bands. In a healthy brain, PAC accompanies cognitive functions such as learning and memory, and changes in PAC have been associated with neurological diseases including Parkinson's disease (PD), schizophrenia, obsessive-compulsive disorder, Alzheimer's disease, and epilepsy. Objective: /Hypothesis: In PD, normalization of PAC in the motor cortex has been reported in the context of effective treatments such as dopamine replacement therapy and deep brain stimulation (DBS), but the possibility of normalizing PAC through intervention at the cortex has not been shown in humans. Phase-targeted stimulation (PDS) has a strong potential to modulate PAC levels and potentially normalize it. Methods: We applied stimulation pulses triggered by specific phases of the beta oscillations, the low frequency oscillations that define phase of gamma amplitude in beta-gamma PAC, to the motor cortex of seven PD patients at rest during DBS lead placement surgery We measured the effect on PAC modulation in the motor cortex relative to stimulation-free periods. Results: We describe a system for phase-targeted stimulation locked to specific phases of a continuously updated slow local field potential oscillation (in this case, beta band oscillations) prediction. Stimulation locked to the phase of the peak of beta oscillations increased beta-gamma coupling both during and after stimulation in the motor cortex, and the opposite phase (trough) stimulation reduced the magnitude of coupling after stimulation. Conclusion: These results demonstrate the capacity of cortical phase-targeted stimulation to modulate PAC without evoking motor activation, which could allow applications in the treatment of neurological disorders associated with abnormal PAC, such as PD.

Published

2022

161. Brain-Computer interface control of stepping from invasive electrocorticography upper-limb motor imagery in a patient with quadriplegia

Author

Iahn Cajigas, Kevin C. Davis, Noeline W. Prins, Sebastian Gallo, Jasim A. Naeem, Letitia Fisher, Michael E. Ivan, Abhishek Prasad, and Jonathan R. Jagid

Subjects

brain-computer interface, electrocorticography, spinal cord injury, gait, lower-extremity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Introduction: Most spinal cord injuries (SCI) result in lower extremities paralysis, thus diminishing ambulation. Using brain-computer interfaces (BCI), patients may regain leg control using neural signals that actuate assistive devices. Here, we present a case of a subject with cervical SCI with an implanted electrocorticography (ECoG) device and determined whether the system is capable of motor-imagery-initiated walking in an assistive ambulator.Methods: A 24-year-old male subject with cervical SCI (C5 ASIA A) was implanted before the study with an ECoG sensing device over the sensorimotor hand region of the brain. The subject used motor-imagery (MI) to train decoders to classify sensorimotor rhythms. Fifteen sessions of closed-loop trials followed in which the subject ambulated for one hour on a robotic-assisted weight-supported treadmill one to three times per week. We evaluated the stability of the best-performing decoder over time to initiate walking on the treadmill by decoding upper-limb (UL) MI.Results: An online bagged trees classifier performed best with an accuracy of 84.15% averaged across 9 weeks. Decoder accuracy remained stable following throughout closed-loop data collection.Discussion: These results demonstrate that decoding UL MI is a feasible control signal for use in lower-limb motor control. Invasive BCI systems designed for upper-extremity motor control can be extended for controlling systems beyond upper extremity control alone. Importantly, the decoders used were able to use the invasive signal over several weeks to accurately classify MI from the invasive signal. More work is needed to determine the long-term consequence between UL MI and the resulting lower-limb control.

Published

2023

162. Less-invasive subdural electrocorticography for investigation of spreading depolarizations in patients with subarachnoid hemorrhage

Author

Franziska Meinert, Coline L. Lemâle, Sebastian Major, Simeon O. A. Helgers, Patrick Dömer, Rik Mencke, Martin N. Bergold, Jens P. Dreier, Nils Hecht, and Johannes Woitzik

Subjects

electrocorticography, spreading depolarization, subarachnoid hemorrhage, neurocritical care, Spencer-type electrode array, Neurology. Diseases of the nervous system, RC346-429

Abstract

IntroductionWyler-strip electrodes for subdural electrocorticography (ECoG) are the gold standard for continuous bed-side monitoring of pathological cortical network events, such as spreading depolarizations (SD) and electrographic seizures. Recently, SD associated parameters were shown to be (1) a marker of early brain damage after aneurysmal subarachnoid hemorrhage (aSAH), (2) the strongest real-time predictor of delayed cerebral ischemia currently known, and (3) the second strongest predictor of patient outcome at 7 months. The strongest predictor of patient outcome at 7 months was focal brain damage segmented on neuroimaging 2 weeks after the initial hemorrhage, whereas the initial focal brain damage was inferior to the SD variables as a predictor for patient outcome. However, the implantation of Wyler-strip electrodes typically requires either a craniotomy or an enlarged burr hole. Neuromonitoring via an enlarged burr hole has been performed in only about 10% of the total patients monitored.MethodsIn the present pilot study, we investigated the feasibility of ECoG monitoring via a less invasive burrhole approach using a Spencer-type electrode array, which was implanted subdurally rather than in the depth of the parenchyma. Seven aSAH patients requiring extraventricular drainage (EVD) were included. For electrode placement, the burr hole over which the EVD was simultaneously placed, was used in all cases. After electrode implantation, continuous, direct current (DC)/alternating current (AC)-ECoG monitoring was performed at bedside in our Neurointensive Care unit. ECoGs were analyzed following the recommendations of the Co-Operative Studies on Brain Injury Depolarizations (COSBID).ResultsSubdural Spencer-type electrode arrays permitted high-quality ECoG recording. During a cumulative monitoring period of 1,194.5 hours and a median monitoring period of 201.3 (interquartile range: 126.1–209.4) hours per patient, 84 SDs were identified. Numbers of SDs, isoelectric SDs and clustered SDs per recording day, and peak total SD-induced depression duration of a recording day were not significantly different from the previously reported results of the prospective, observational, multicenter, cohort, diagnostic phase III trial, DISCHARGE-1. No adverse events related to electrode implantation were noted.DiscussionIn conclusion, our findings support the safety and feasibility of less-invasive subdural electrode implantation for reliable SD-monitoring.

Published

2023

163. Cortical Potentials Evoked by Subthalamic Stimulation Demonstrate a Short Latency Hyperdirect Pathway in Humans

Author

Miocinovic, Svjetlana, de Hemptinne, Coralie, Chen, Witney, Isbaine, Faical, Willie, Jon T, Ostrem, Jill L, and Starr, Philip A

Subjects

Aging, Brain Disorders, Neurosciences, Neurodegenerative, Clinical Research, Aetiology, 2.1 Biological and endogenous factors, Neurological, Cerebral Cortex, Deep Brain Stimulation, Electrocorticography, Evoked Potentials, Female, Humans, Magnetic Resonance Imaging, Male, Neural Pathways, Parkinson Disease, Random Allocation, Subthalamic Nucleus, cortical projections, DBS, deep-brain stimulation, electrocorticography, globus pallidus, hyperdirect pathway, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

A monosynaptic projection from the cortex to the subthalamic nucleus is thought to have an important role in basal ganglia function and in the mechanism of therapeutic subthalamic deep-brain stimulation, but in humans the evidence for its existence is limited. We sought physiological confirmation of the cortico-subthalamic hyperdirect pathway using invasive recording techniques in patients with Parkinson's disease (9 men, 1 woman). We measured sensorimotor cortical evoked potentials using a temporary subdural strip electrode in response to low-frequency deep-brain stimulation in patients undergoing awake subthalamic or pallidal lead implantations. Evoked potentials were grouped into very short latency (

Published

2018

164. Random Recurrent Networks Near Criticality Capture the Broadband Power Distribution of Human ECoG Dynamics.

Author

Chaudhuri, Rishidev, He, Biyu J, and Wang, Xiao-Jing

Subjects

Biomedical and Clinical Sciences, Neurosciences, Behavioral and Social Science, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Algorithms, Brain Mapping, Cerebral Cortex, Electrocorticography, Humans, Models, Neurological, Nerve Net, Psychomotor Performance, dynamics, electrocorticography, neural networks, power spectrum, bifurcation, Psychology, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Brain electric field potentials are dominated by an arrhythmic broadband signal, but the underlying mechanism is poorly understood. Here we propose that broadband power spectra characterize recurrent neural networks of nodes (neurons or clusters of neurons), endowed with an effective balance between excitation and inhibition tuned to keep the network on the edge of dynamical instability. These networks show a fast mode reflecting local dynamics and a slow mode emerging from distributed recurrent connections. Together, the 2 modes produce power spectra similar to those observed in human intracranial EEG (i.e., electrocorticography, ECoG) recordings. Moreover, such networks convert spatial input correlations across nodes into temporal autocorrelation of network activity. Consequently, increased independence between nodes reduces low-frequency power, which may explain changes observed during behavioral tasks. Lastly, varying network coupling causes activity changes that resemble those observed in human ECoG across different arousal states. The model links macroscopic features of empirical ECoG power to a parsimonious underlying network structure, and suggests mechanisms for changes observed across behavioral and arousal states. This work provides a computational framework to generate and test hypotheses about cellular and network mechanisms underlying whole brain electrical dynamics, their variations across states, and potential alterations in brain diseases.

Published

2018

165. Removing high-frequency oscillations

Author

Jacobs, Julia, Wu, Joyce Y, Perucca, Piero, Zelmann, Rina, Mader, Malenka, Dubeau, Francois, Mathern, Gary W, Schulze-Bonhage, Andreas, and Gotman, Jean

Subjects

Epilepsy, Clinical Research, Neurodegenerative, Brain Disorders, Neurosciences, Neurological, Adolescent, Adult, Brain Waves, Child, Child, Preschool, Electrocorticography, Electroencephalography, Female, Humans, Infant, Male, Middle Aged, Neurosurgical Procedures, Prospective Studies, Seizures, Treatment Outcome, Young Adult, Clinical Sciences, Cognitive Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo evaluate the use of interictal high-frequency oscillations (HFOs) in epilepsy surgery for prediction of postsurgical seizure outcome in a prospective multicenter trial.MethodsWe hypothesized that a seizure-free outcome could be expected in patients in whom the surgical planning included the majority of HFO-generating brain tissue while a poor seizure outcome could be expected in patients in whom only a few such areas were planned to be resected. Fifty-two patients were included from 3 tertiary epilepsy centers during a 1-year period. Ripples (80-250 Hz) and fast ripples (250-500 Hz) were automatically detected during slow-wave sleep with chronic intracranial EEG in 2 centers and acute intraoperative electrocorticography in 1 patient.ResultsThere was a correlation between the removal of HFO-generating regions and seizure-free outcome at the group level for all patients. No correlation was found, however, for the center-specific analysis, and an individual prognostication of seizure outcome was true in only 36 patients (67%). Moreover, some patients became seizure-free without removal of the majority of HFO-generating tissue. The investigation of influencing factors, including comparisons of visual and automatic analysis, using a threshold analysis for areas with high HFO activity, and excluding contacts bordering the resection, did not result in improved prognostication.ConclusionsOn an individual patient level, a prediction of outcome was not possible in all patients. This may be due to the analysis techniques used. Alternatively, HFOs may be less specific for epileptic tissue than earlier studies have indicated.

Published

2018

166. Encoding of Multiple Reward-Related Computations in Transient and Sustained High-Frequency Activity in Human OFC.

Author

Saez, Ignacio, Lin, Jack, Stolk, Arjen, Chang, Edward, Parvizi, Josef, Schalk, Gerwin, Knight, Robert T, and Hsu, Ming

Subjects

Prefrontal Cortex, Neurons, Humans, Decision Making, Female, Male, Electrocorticography, ECoC, ERP, FP, HFA, OFC, RPE, electrocorticography, event-related potential, field potential, high-frequency activity, orbitofrontal cortex, reward-prediction error, Basic Behavioral and Social Science, Neurosciences, Behavioral and Social Science, Brain Disorders, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Developmental Biology

Abstract

Human orbitofrontal cortex (OFC) has long been implicated in value-based decision making. In recent years, convergent evidence from human and model organisms has further elucidated its role in representing reward-related computations underlying decision making. However, a detailed description of these processes remains elusive due in part to (1) limitations in our ability to observe human OFC neural dynamics at the timescale of decision processes and (2) methodological and interspecies differences that make it challenging to connect human and animal findings or to resolve discrepancies when they arise. Here, we sought to address these challenges by conducting multi-electrode electrocorticography (ECoG) recordings in neurosurgical patients during economic decision making to elucidate the electrophysiological signature, sub-second temporal profile, and anatomical distribution of reward-related computations within human OFC. We found that high-frequency activity (HFA) (70-200 Hz) reflected multiple valuation components grouped in two classes of valuation signals that were dissociable in temporal profile and information content: (1) fast, transient responses reflecting signals associated with choice and outcome processing, including anticipated risk and outcome regret, and (2) sustained responses explicitly encoding what happened in the immediately preceding trial. Anatomically, these responses were widely distributed in partially overlapping networks, including regions in the central OFC (Brodmann areas 11 and 13), which have been consistently implicated in reward processing in animal single-unit studies. Together, these results integrate insights drawn from human and animal studies and provide evidence for a role of human OFC in representing multiple reward computations.

Published

2018

167. A transient cortical state with sleep-like sensory responses precedes emergence from general anesthesia in humans.

Author

Lewis, Laura D, Piantoni, Giovanni, Peterfreund, Robert A, Eskandar, Emad N, Harrell, Priscilla Grace, Akeju, Oluwaseun, Aglio, Linda S, Cash, Sydney S, Brown, Emery N, Mukamel, Eran A, and Purdon, Patrick L

Subjects

Cerebral Cortex, Humans, Propofol, Hypnotics and Sedatives, Electroencephalography, Anesthesia Recovery Period, Consciousness, Sensation, Sleep, Evoked Potentials, Adult, Middle Aged, Female, Male, Young Adult, anesthesia, dynamics, electrocorticography, emergence, human, neuroscience, Neurosciences, Sleep Research, Brain Disorders, 1.1 Normal biological development and functioning, Neurological, Biochemistry and Cell Biology

Abstract

During awake consciousness, the brain intrinsically maintains a dynamical state in which it can coordinate complex responses to sensory input. How the brain reaches this state spontaneously is not known. General anesthesia provides a unique opportunity to examine how the human brain recovers its functional capabilities after profound unconsciousness. We used intracranial electrocorticography and scalp EEG in humans to track neural dynamics during emergence from propofol general anesthesia. We identify a distinct transient brain state that occurs immediately prior to recovery of behavioral responsiveness. This state is characterized by large, spatially distributed, slow sensory-evoked potentials that resemble the K-complexes that are hallmarks of stage two sleep. However, the ongoing spontaneous dynamics in this transitional state differ from sleep. These results identify an asymmetry in the neurophysiology of induction and emergence, as the emerging brain can enter a state with a sleep-like sensory blockade before regaining responsivity to arousing stimuli.

Published

2018

168. Electrocorticographic Encoding of Human Gait in the Leg Primary Motor Cortex

Author

McCrimmon, Colin M, Wang, Po T, Heydari, Payam, Nguyen, Angelica, Shaw, Susan J, Gong, Hui, Chui, Luis A, Liu, Charles Y, Nenadic, Zoran, and H, An

Subjects

Rehabilitation, Assistive Technology, Bioengineering, Physical Rehabilitation, Neurodegenerative, Neurosciences, Clinical Research, Neurological, Adult, Brain Mapping, Brain Waves, Electrocorticography, Female, Gait, Humans, Image Processing, Computer-Assisted, Leg, Magnetic Resonance Imaging, Male, Motor Cortex, Movement, Walking, ECoG, electrophysiology, motor control, neurophysiology, walking, Psychology, Cognitive Sciences, Experimental Psychology

Abstract

While prior noninvasive (e.g., electroencephalographic) studies suggest that the human primary motor cortex (M1) is active during gait processes, the limitations of noninvasive recordings make it impossible to determine whether M1 is involved in high-level motor control (e.g., obstacle avoidance, walking speed), low-level motor control (e.g., coordinated muscle activation), or only nonmotor processes (e.g., integrating/relaying sensory information). This study represents the first invasive electroneurophysiological characterization of the human leg M1 during walking. Two subjects with an electrocorticographic grid over the interhemispheric M1 area were recruited. Both exhibited generalized γ-band (40-200 Hz) synchronization across M1 during treadmill walking, as well as periodic γ-band changes within each stride (across multiple walking speeds). Additionally, these changes appeared to be of motor, rather than sensory, origin. However, M1 activity during walking shared few features with M1 activity during individual leg muscle movements, and was not highly correlated with lower limb trajectories on a single channel basis. These findings suggest that M1 primarily encodes high-level gait motor control (i.e., walking duration and speed) instead of the low-level patterns of leg muscle activation or movement trajectories. Therefore, M1 likely interacts with subcortical/spinal networks, which are responsible for low-level motor control, to produce normal human walking.

Published

2018

169. Neural Mechanisms of Sustained Attention Are Rhythmic

Author

Helfrich, Randolph F, Fiebelkorn, Ian C, Szczepanski, Sara M, Lin, Jack J, Parvizi, Josef, Knight, Robert T, and Kastner, Sabine

Subjects

Brain Disorders, Basic Behavioral and Social Science, Behavioral and Social Science, Neurosciences, Mental Health, Neurological, Adult, Attention, Brain, Electrodes, Implanted, Electroencephalography, Female, Humans, Male, Middle Aged, Periodicity, Photic Stimulation, Psychomotor Performance, Random Allocation, Reaction Time, Visual Perception, discrete perception, electrocorticography, frontoparietal attention network, functional network parcellation, high-frequency activity, intracranial EEG, perceptual cycles, phase-dependent behavior, rhythmic attention, theta oscillations, Psychology, Cognitive Sciences, Neurology & Neurosurgery

Abstract

Classic models of attention suggest that sustained neural firing constitutes a neural correlate of sustained attention. However, recent evidence indicates that behavioral performance fluctuates over time, exhibiting temporal dynamics that closely resemble the spectral features of ongoing, oscillatory brain activity. Therefore, it has been proposed that periodic neuronal excitability fluctuations might shape attentional allocation and overt behavior. However, empirical evidence to support this notion is sparse. Here, we address this issue by examining data from large-scale subdural recordings, using two different attention tasks that track perceptual ability at high temporal resolution. Our results reveal that perceptual outcome varies as a function of the theta phase even in states of sustained spatial attention. These effects were robust at the single-subject level, suggesting that rhythmic perceptual sampling is an inherent property of the frontoparietal attention network. Collectively, these findings support the notion that the functional architecture of top-down attention is intrinsically rhythmic.

Published

2018

170. Integrated analysis of anatomical and electrophysiological human intracranial data

Author

Stolk, Arjen, Griffin, Sandon, van der Meij, Roemer, Dewar, Callum, Saez, Ignacio, Lin, Jack J, Piantoni, Giovanni, Schoffelen, Jan-Mathijs, Knight, Robert T, and Oostenveld, Robert

Subjects

Biomedical Imaging, Brain, Electrocorticography, Electronic Data Processing, Humans, Neuroanatomy, Software, Chemical Sciences, Biological Sciences, Medical and Health Sciences, Bioinformatics

Abstract

Human intracranial electroencephalography (iEEG) recordings provide data with much greater spatiotemporal precision than is possible from data obtained using scalp EEG, magnetoencephalography (MEG), or functional MRI. Until recently, the fusion of anatomical data (MRI and computed tomography (CT) images) with electrophysiological data and their subsequent analysis have required the use of technologically and conceptually challenging combinations of software. Here, we describe a comprehensive protocol that enables complex raw human iEEG data to be converted into more readily comprehensible illustrative representations. The protocol uses an open-source toolbox for electrophysiological data analysis (FieldTrip). This allows iEEG researchers to build on a continuously growing body of scriptable and reproducible analysis methods that, over the past decade, have been developed and used by a large research community. In this protocol, we describe how to analyze complex iEEG datasets by providing an intuitive and rapid approach that can handle both neuroanatomical information and large electrophysiological datasets. We provide a worked example using an example dataset. We also explain how to automate the protocol and adjust the settings to enable analysis of iEEG datasets with other characteristics. The protocol can be implemented by a graduate student or postdoctoral fellow with minimal MATLAB experience and takes approximately an hour to execute, excluding the automated cortical surface extraction.

Published

2018

171. Alterations of network synchrony after epileptic seizures: An analysis of post-ictal intracranial recordings in pediatric epilepsy patients

Author

Tomlinson, Samuel B, Khambhati, Ankit N, Bermudez, Camilo, Kamens, Rebecca M, Heuer, Gregory G, Porter, Brenda E, and Marsh, Eric D

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Neurosciences, Brain Disorders, Epilepsy, Neurodegenerative, Clinical Research, Aetiology, 2.1 Biological and endogenous factors, Neurological, Adolescent, Brain, Child, Child, Preschool, Delta Rhythm, Electrocorticography, Female, Humans, Male, Prognosis, Retrospective Studies, Seizures, Time Factors, Treatment Outcome, Young Adult, Pediatric epilepsy, Intracranial electroencephalography, Post-ictal, Epilepsy surgery, Network connectivity, Neurology & Neurosurgery

Abstract

ObjectivePost-ictal EEG alterations have been identified in studies of intracranial recordings, but the clinical significance of post-ictal EEG activity is undetermined. The purpose of this study was to examine the relationship between peri-ictal EEG activity, surgical outcome, and extent of seizure propagation in a sample of pediatric epilepsy patients.MethodsIntracranial EEG recordings were obtained from 19 patients (mean age = 11.4 years, range = 3-20 years) with 57 seizures used for analysis (mean = 3.0 seizures per patient). For each seizure, 3-min segments were extracted from adjacent pre-ictal and post-ictal epochs. To compare physiology of the epileptic network between epochs, we calculated the relative delta power (Δ) using discrete Fourier transformation and constructed functional networks based on broadband connectivity (conn). We investigated differences between the pre-ictal (Δpre, connpre) and post-ictal (Δpost, connpost) segments in focal-network (i.e., confined to seizure onset zone) versus distributed-network (i.e., diffuse ictal propagation) seizures.ResultsDistributed-network (DN) seizures exhibited increased post-ictal delta power and global EEG connectivity compared to focal-network (FN) seizures. Following DN seizures, patients with seizure-free outcomes exhibited a 14.7% mean increase in delta power and an 8.3% mean increase in global connectivity compared to pre-ictal baseline, which was dramatically less than values observed among seizure-persistent patients (29.6% and 47.1%, respectively).SignificancePost-ictal differences between DN and FN seizures correlate with post-operative seizure persistence. We hypothesize that post-ictal deactivation of subcortical nuclei recruited during seizure propagation may account for this result while lending insights into mechanisms of post-operative seizure recurrence.

Published

2018

172. Electrocorticographic Activity of the Brain During Micturition

Author

Tran, Tracie, Wang, Po T, Lee, Brian, Liu, Charles Y, Kreydin, Evgeniy I, Nenadic, Zoran, and H., An

Subjects

Biomedical and Clinical Sciences, Neurosciences, Neurodegenerative, Brain Disorders, Epilepsy, Urologic Diseases, Physical Injury - Accidents and Adverse Effects, 2.1 Biological and endogenous factors, Aetiology, Neurological, Brain, Electrocorticography, Humans, Retrospective Studies, Urinary Bladder, Urination, Neural technologies, neuromodulation, neurophysiology, neurogenic bladder, electrocorticogram

Abstract

Current therapies for neurogenic bladder do not allow spinal cord injury patients to regain conscious control of urine storage or voiding. Novel neural technologies may provide means to improve or restore the connection between the brain and the bladder; however, the specific brain areas and their underlying neural activities responsible for micturition must be better understood in order to design such technologies. In this retrospective study, we analyzed electrocorticographic (ECoG) data obtained from epilepsy patients who underwent ECoG grid implantation for epilepsy surgery evaluation, in the hopes of determining specific electrophysiological activity associated with micturition. Our results indicate modulation of the delta (δ, 0.1-4 Hz) and low-gamma (\gamma, 25-50 Hz) activity in the peri-Sylvian area and the inferior temporal lobe. These findings suggest involvement of the insular cortex and the uncinate fasciculus in micturition, important structures related to sensation and decision making. To date, this is the first known study utilizing ECoG data to elucidate the electrophysiological activity of the brain associated with bladder control and sensation.

Published

2018

173. Characterization of Stimulation Artifact Behavior in Simultaneous Electrocorticography Grid Stimulation and Recording

Author

Lim, Jeffrey, Wang, Po T, Bidhendi, Alireza K, Arasteh, Omid M, Shaw, Susan J, Armacost, Michelle, Gong, Hui, Liu, Charles Y, Heydari, Payam, H., An, and Nenadic, Zoran

Subjects

Engineering, Biomedical Engineering, Neurosciences, Bioengineering, Assistive Technology, Brain Disorders, Artifacts, Brain-Computer Interfaces, Cerebral Cortex, Electrocorticography, Electrodes

Abstract

Bi-directional brain-computer interfaces (BCIs) require simultaneous stimulation and recording to achieve closed-loop operation. It is therefore important that the interface be able to distinguish between neural signals of interest and stimulation artifacts. Current bi-directional BCIs address this problem by temporally multiplexing stimulation and recording. This approach, however, is suboptimal in many BCI applications. Alternative artifact mitigation methods can be devised by investigating the mechanics of artifact propagation. To characterize stimulation artifact behaviors, we collected and analyzed electrocorticography (ECoG) data from eloquent cortex mapping. Ratcheting and phase-locking of stimulation artifacts were observed, as well as dipole-like properties. Artifacts as large as ±1,100 μV appeared as far as 15-37 mm away from the stimulating channel when stimulating at 10 mA. Analysis also showed that the majority of the artifact power was concentrated at the stimulation pulse train frequency (50 Hz) and its super-harmonics (100, 150, 200 Hz). Lower frequencies (0-32 Hz) experienced minimal artifact contamination. These findings could inform the design of future bi-directional ECoG-based BCIs.

Published

2018

174. A lexical semantic hub for heteromodal naming in middle fusiform gyrus.

Author

Forseth, Kiefer James, Kadipasaoglu, Cihan Mehmet, Conner, Christopher Richard, Hickok, Gregory, Knight, Robert Thomas, and Tandon, Nitin

Subjects

Basic Behavioral and Social Science, Neurosciences, Neurodegenerative, Behavioral and Social Science, Epilepsy, Aphasia, Clinical Research, Brain Disorders, Aetiology, 2.1 Biological and endogenous factors, Neurological, Adult, Anomia, Brain, Brain Mapping, Cognition, Comprehension, Electrocorticography, Epilepsy, Temporal Lobe, Female, Humans, Language, Magnetic Resonance Imaging, Male, Memory, Memory Disorders, Middle Aged, Occipital Lobe, Prefrontal Cortex, Semantics, Speech, Temporal Lobe, intracranial EEG, aphasia, temporal lobe, gamma oscillations, language, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Semantic memory underpins our understanding of objects, people, places, and ideas. Anomia, a disruption of semantic memory access, is the most common residual language disturbance and is seen in dementia and following injury to temporal cortex. While such anomia has been well characterized by lesion symptom mapping studies, its pathophysiology is not well understood. We hypothesize that inputs to the semantic memory system engage a specific heteromodal network hub that integrates lexical retrieval with the appropriate semantic content. Such a network hub has been proposed by others, but has thus far eluded precise spatiotemporal delineation. This limitation in our understanding of semantic memory has impeded progress in the treatment of anomia. We evaluated the cortical structure and dynamics of the lexical semantic network in driving speech production in a large cohort of patients with epilepsy using electrocorticography (n = 64), functional MRI (n = 36), and direct cortical stimulation (n = 30) during two generative language processes that rely on semantic knowledge: visual picture naming and auditory naming to definition. Each task also featured a non-semantic control condition: scrambled pictures and reversed speech, respectively. These large-scale data of the left, language-dominant hemisphere uniquely enable convergent, high-resolution analyses of neural mechanisms characterized by rapid, transient dynamics with strong interactions between distributed cortical substrates. We observed three stages of activity during both visual picture naming and auditory naming to definition that were serially organized: sensory processing, lexical semantic processing, and articulation. Critically, the second stage was absent in both the visual and auditory control conditions. Group activity maps from both electrocorticography and functional MRI identified heteromodal responses in middle fusiform gyrus, intraparietal sulcus, and inferior frontal gyrus; furthermore, the spectrotemporal profiles of these three regions revealed coincident activity preceding articulation. Only in the middle fusiform gyrus did direct cortical stimulation disrupt both naming tasks while still preserving the ability to repeat sentences. These convergent data strongly support a model in which a distinct neuroanatomical substrate in middle fusiform gyrus provides access to object semantic information. This under-appreciated locus of semantic processing is at risk in resections for temporal lobe epilepsy as well as in trauma and strokes that affect the inferior temporal cortex-it may explain the range of anomic states seen in these conditions. Further characterization of brain network behaviour engaging this region in both healthy and diseased states will expand our understanding of semantic memory and further development of therapies directed at anomia.

Published

2018

175. Distinct phase-amplitude couplings distinguish cognitive processes in human attention

Author

Chacko, Ravi V, Kim, Byungchan, Jung, Suh Woo, Daitch, Amy L, Roland, Jarod L, Metcalf, Nicholas V, Corbetta, Maurizio, Shulman, Gordon L, and Leuthardt, Eric C

Subjects

Biomedical and Clinical Sciences, Health Sciences, Neurosciences, Behavioral and Social Science, Clinical Research, Adult, Attention, Brain Waves, Cerebral Cortex, Cues, Electrocorticography, Epilepsy, Humans, Psychomotor Performance, Reaction Time, Signal Processing, Computer-Assisted, Space Perception, Visual Perception, Phase-amplitude coupling, Sharp waves, Cued attention, Reaction time, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery, Biomedical and clinical sciences, Health sciences

Abstract

Spatial attention is the cognitive function that coordinates the selection of visual stimuli with appropriate behavioral responses. Recent studies have reported that phase-amplitude coupling (PAC) of low and high frequencies covaries with spatial attention, but differ on the direction of covariation and the frequency ranges involved. We hypothesized that distinct phase-amplitude frequency pairs have differentiable contributions during tasks that manipulate spatial attention. We investigated this hypothesis with electrocorticography (ECoG) recordings from participants who engaged in a cued spatial attention task. To understand the contribution of PAC to spatial attention we classified cortical sites by their relationship to spatial variables or behavioral performance. Local neural activity in spatial sites was sensitive to spatial variables in the task, while local neural activity in behavioral sites correlated with reaction time. We found two PAC frequency clusters that covaried with different aspects of the task. During a period of cued attention, delta-phase/high-gamma (DH) PAC was sensitive to cue direction in spatial sites. In contrast, theta-alpha-phase/beta-low-gamma-amplitude (TABL) PAC robustly correlated with future reaction times in behavioral sites. Finally, we investigated the origins of TABL PAC and found it corresponded to behaviorally relevant, sharp waveforms, which were also coupled to a low frequency rhythm. We conclude that TABL and DH PAC correspond to distinct mechanisms during spatial attention tasks and that sharp waveforms are elements of a coupled dynamical process.

Published

2018

176. Neurosurgical Patients as Human Research Subjects: Ethical Considerations in Intracranial Electrophysiology Research.

Author

Chiong, Winston, Leonard, Matthew K, and Chang, Edward F

Subjects

Humans, Neurosurgical Procedures, Human Experimentation, Neurosciences, Informed Consent, Intraoperative Neurophysiological Monitoring, Bioethical issues, Electrocorticography, Deep brain stimulation, Human experimentation, Informed consent, Neurosurgery, Therapeutic misconception, Brain Disorders, Patient Safety, Clinical Research, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

Intracranial electrical recordings and stimulation of neurosurgical patients have been central to the advancement of human neuroscience. The use of these methods has rapidly expanded over the last decade due to theoretical and technical advances, as well as the growing number of neurosurgical patients undergoing functional procedures for indications such as epilepsy, tumor resection, and movement disorders. These methods pose the potential for ethical conflict, as they involve basic neuroscientific research utilizing invasive procedures in human patients undergoing treatment for neurological illnesses. This review addresses technical aspects, clinical contexts, and issues of ethical concern, utilizing a framework that is informed by, but also departs from, existing bioethical literature on matters in clinical research. We conclude with proposals for improving informed consent processes to address potential problems specific to intracranial electrophysiology research, a general schema for scrutinizing research-related risk associated with different methods, and a call for the development of consensus to ensure continuing scientific progress alongside crucial patient protections in this promising area of human neuroscience.

Published

2018

177. Encoding of Articulatory Kinematic Trajectories in Human Speech Sensorimotor Cortex.

Author

Chartier, Josh, Anumanchipalli, Gopala K, Johnson, Keith, and Chang, Edward F

Subjects

Lip, Jaw, Tongue, Larynx, Humans, Epilepsy, Speech, Models, Neurological, Phonetics, Adult, Middle Aged, Female, Biomechanical Phenomena, Sensorimotor Cortex, Electrocorticography, Neural Networks, Computer, articulation, coordination, decoding, electrocorticography, encoding, movement, sensorimotor cortex, speech production, trajectory, Rehabilitation, Behavioral and Social Science, Neurosciences, Psychology, Cognitive Sciences, Neurology & Neurosurgery

Abstract

When speaking, we dynamically coordinate movements of our jaw, tongue, lips, and larynx. To investigate the neural mechanisms underlying articulation, we used direct cortical recordings from human sensorimotor cortex while participants spoke natural sentences that included sounds spanning the entire English phonetic inventory. We used deep neural networks to infer speakers' articulator movements from produced speech acoustics. Individual electrodes encoded a diversity of articulatory kinematic trajectories (AKTs), each revealing coordinated articulator movements toward specific vocal tract shapes. AKTs captured a wide range of movement types, yet they could be differentiated by the place of vocal tract constriction. Additionally, AKTs manifested out-and-back trajectories with harmonic oscillator dynamics. While AKTs were functionally stereotyped across different sentences, context-dependent encoding of preceding and following movements during production of the same phoneme demonstrated the cortical representation of coarticulation. Articulatory movements encoded in sensorimotor cortex give rise to the complex kinematics underlying continuous speech production. VIDEO ABSTRACT.

Published

2018

178. The Control of Vocal Pitch in Human Laryngeal Motor Cortex

Author

Dichter, Benjamin K, Breshears, Jonathan D, Leonard, Matthew K, and Chang, Edward F

Subjects

Basic Behavioral and Social Science, Neurosciences, Clinical Research, Behavioral and Social Science, Underpinning research, 1.1 Normal biological development and functioning, 1.2 Psychological and socioeconomic processes, Neurological, Adolescent, Adult, Brain Mapping, Electrocorticography, Female, Humans, Larynx, Male, Middle Aged, Models, Biological, Motor Cortex, Speech, Young Adult, cortical stimulation, human cortex, larynx, motor cortex, pitch, singing, speech, vocalization, voicing, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

In speech, the highly flexible modulation of vocal pitch creates intonation patterns that speakers use to convey linguistic meaning. This human ability is unique among primates. Here, we used high-density cortical recordings directly from the human brain to determine the encoding of vocal pitch during natural speech. We found neural populations in bilateral dorsal laryngeal motor cortex (dLMC) that selectively encoded produced pitch but not non-laryngeal articulatory movements. This neural population controlled short pitch accents to express prosodic emphasis on a word in a sentence. Other larynx cortical representations controlling voicing and longer pitch phrase contours were found at separate sites. dLMC sites also encoded vocal pitch during a non-speech singing task. Finally, direct focal stimulation of dLMC evoked laryngeal movements and involuntary vocalization, confirming its causal role in feedforward control. Together, these results reveal the neural basis for the voluntary control of vocal pitch in human speech. VIDEO ABSTRACT.

Published

2018

179. Pallidal Deep-Brain Stimulation Disrupts Pallidal Beta Oscillations and Coherence with Primary Motor Cortex in Parkinson's Disease

Author

Wang, Doris D, de Hemptinne, Coralie, Miocinovic, Svjetlana, Ostrem, Jill L, Galifianakis, Nicholas B, San Luciano, Marta, and Starr, Philip A

Subjects

Neurodegenerative, Parkinson's Disease, Assistive Technology, Rare Diseases, Aging, Brain Disorders, Clinical Research, Neurosciences, Bioengineering, Rehabilitation, Dystonia, Neurological, Adult, Aged, Basal Ganglia, Beta Rhythm, Deep Brain Stimulation, Electrocorticography, Electrodes, Implanted, Electroencephalography Phase Synchronization, Female, Globus Pallidus, Humans, Male, Middle Aged, Motor Cortex, Parkinson Disease, Theta Rhythm, Young Adult, basal ganglia thalamocortical network, beta oscillations, dystonia, electrocorticography, local field potential, synchronization, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

In Parkinson's disease (PD), subthalamic nucleus beta band oscillations are decreased by therapeutic deep-brain stimulation (DBS) and this has been proposed as important to the mechanism of therapy. The globus pallidus is a common alternative target for PD with similar motor benefits as subthalamic DBS, but effects of pallidal stimulation in PD are not well studied, and effects of pallidal DBS on cortical function in PD are unknown. Here, in 20 PD and 14 isolated dystonia human patients of both genders undergoing pallidal DBS lead implantation, we recorded local field potentials from the globus pallidus and in a subset of these, recorded simultaneous sensorimotor cortex ECoG potentials. PD patients had elevated resting pallidal low beta band (13-20 Hz) power compared with dystonia patients, whereas dystonia patients had elevated resting pallidal theta band (4-8 Hz) power compared with PD. We show that this results in disease-specific patterns of interaction between the pallidum and motor cortex: PD patients demonstrated relatively elevated phase coherence with the motor cortex in the beta band and this was reduced by therapeutic pallidal DBS. Dystonia patients had greater theta band phase coherence. Our results support the hypothesis that specific motor phenomenology observed in movement disorders are associated with elevated network oscillations in specific frequency bands, and that DBS in movement disorders acts in general by disrupting elevated synchronization between basal ganglia output and motor cortex.SIGNIFICANCE STATEMENT Perturbations in synchronized oscillatory activity in brain networks are increasingly recognized as important features in movement disorders. The globus pallidus is a commonly used target for deep-brain stimulation (DBS) in Parkinson's disease (PD), however, the effects of pallidal DBS on basal ganglia and cortical oscillations are unknown. Using invasive intraoperative recordings in patients with PD and isolated dystonia, we found disease-specific patterns of elevated oscillatory synchronization within the pallidum and in coherence between pallidum and motor cortex. Therapeutic pallidal DBS in PD suppresses these elevated synchronizations, reducing the influence of diseased basal ganglia on cortical physiology. We propose a general mechanism for DBS therapy in movement disorders: functional disconnection of basal ganglia output and motor cortex by coherence suppression.

Published

2018

180. Direct electrical stimulation of human cortex evokes high gamma activity that predicts conscious somatosensory perception.

Author

Muller, Leah, Rolston, John D, Fox, Neal P, Knowlton, Robert, Rao, Vikram R, and Chang, Edward F

Subjects

Somatosensory Cortex, Humans, Deep Brain Stimulation, Brain Mapping, Consciousness, Evoked Potentials, Somatosensory, Forecasting, Adult, Middle Aged, Female, Male, Touch Perception, Young Adult, Gamma Rhythm, DES, electrocorticography, functional mapping, neural prosthesis, direct electrical stimulation, Biomedical Engineering, Clinical Sciences, Neurosciences

Abstract

OBJECTIVE:Direct electrical stimulation (DES) is a clinical gold standard for human brain mapping and readily evokes conscious percepts, yet the neurophysiological changes underlying these percepts are not well understood. APPROACH:To determine the neural correlates of DES, we stimulated the somatosensory cortex of ten human participants at frequency-amplitude combinations that both elicited and failed to elicit conscious percepts, meanwhile recording neural activity directly surrounding the stimulation site. We then compared the neural activity of perceived trials to that of non-perceived trials. MAIN RESULTS:We found that stimulation evokes distributed high gamma activity, which correlates with conscious perception better than stimulation parameters themselves. SIGNIFICANCE:Our findings suggest that high gamma activity is a reliable biomarker for perception evoked by both natural and electrical stimuli.

Published

2018

181. Human Sensorimotor Cortex Control of Directly Measured Vocal Tract Movements during Vowel Production

Author

Conant, David F, Bouchard, Kristofer E, Leonard, Matthew K, and Chang, Edward F

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Research, Bioengineering, Basic Behavioral and Social Science, Rehabilitation, Behavioral and Social Science, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Adult, Biomechanical Phenomena, Female, Humans, Jaw, Lip, Male, Movement, Sensorimotor Cortex, Speech, Tongue, electrocorticography, sensorimotor cortex, speech motor control, speech production, vowels, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

During speech production, we make vocal tract movements with remarkable precision and speed. Our understanding of how the human brain achieves such proficient control is limited, in part due to the challenge of simultaneously acquiring high-resolution neural recordings and detailed vocal tract measurements. To overcome this challenge, we combined ultrasound and video monitoring of the supralaryngeal articulators (lips, jaw, and tongue) with electrocorticographic recordings from the cortical surface of 4 subjects (3 female, 1 male) to investigate how neural activity in the ventral sensory-motor cortex (vSMC) relates to measured articulator movement kinematics (position, speed, velocity, acceleration) during the production of English vowels. We found that high-gamma activity at many individual vSMC electrodes strongly encoded the kinematics of one or more articulators, but less so for vowel formants and vowel identity. Neural population decoding methods further revealed the structure of kinematic features that distinguish vowels. Encoding of articulator kinematics was sparsely distributed across time and primarily occurred during the time of vowel onset and offset. In contrast, encoding was low during the steady-state portion of the vowel, despite sustained neural activity at some electrodes. Significant representations were found for all kinematic parameters, but speed was the most robust. These findings enabled by direct vocal tract monitoring demonstrate novel insights into the representation of articulatory kinematic parameters encoded in the vSMC during speech production.SIGNIFICANCE STATEMENT Speaking requires precise control and coordination of the vocal tract articulators (lips, jaw, and tongue). Despite the impressive proficiency with which humans move these articulators during speech production, our understanding of how the brain achieves such control is rudimentary, in part because the movements themselves are difficult to observe. By simultaneously measuring speech movements and the neural activity that gives rise to them, we demonstrate how neural activity in sensorimotor cortex produces complex, coordinated movements of the vocal tract.

Published

2018

182. Chronic multisite brain recordings from a totally implantable bidirectional neural interface: experience in 5 patients with Parkinson's disease.

Author

Swann, Nicole C, de Hemptinne, Coralie, Miocinovic, Svjetlana, Qasim, Salman, Ostrem, Jill L, Galifianakis, Nicholas B, Luciano, Marta San, Wang, Sarah S, Ziman, Nathan, Taylor, Robin, and Starr, Philip A

Subjects

Subthalamic Nucleus, Motor Cortex, Nerve Net, Humans, Parkinson Disease, Treatment Outcome, Electric Stimulation Therapy, Deep Brain Stimulation, Neurosurgical Procedures, Artifacts, Electrodes, Implanted, Psychomotor Performance, Evoked Potentials, Middle Aged, Female, Male, Brain-Computer Interfaces, Electrocorticography, DBS, DBS = deep brain stimulation, ECoG = electrocorticography, EKG = electrocardiogram, FDA = Food and Drug Administration, IPG = implanted pulse generator, LFP = local field potential, PD, PD = Parkinson's disease, PSD = power spectral density, Parkinson's disease, RMS = root mean square, STN = subthalamic nucleus, UPDRS = Unified Parkinson's Disease Rating Scale, basal ganglia, brain-machine interface, deep brain stimulation, electrophysiology, functional neurosurgery, motor cortex, Clinical Research, Brain Disorders, Rehabilitation, Bioengineering, Parkinson's Disease, Neurodegenerative, Assistive Technology, Neurosciences, Neurological, Clinical Sciences, Neurology & Neurosurgery

Abstract

OBJECTIVE Dysfunction of distributed neural networks underlies many brain disorders. The development of neuromodulation therapies depends on a better understanding of these networks. Invasive human brain recordings have a favorable temporal and spatial resolution for the analysis of network phenomena but have generally been limited to acute intraoperative recording or short-term recording through temporarily externalized leads. Here, the authors describe their initial experience with an investigational, first-generation, totally implantable, bidirectional neural interface that allows both continuous therapeutic stimulation and recording of field potentials at multiple sites in a neural network. METHODS Under a physician-sponsored US Food and Drug Administration investigational device exemption, 5 patients with Parkinson's disease were implanted with the Activa PC+S system (Medtronic Inc.). The device was attached to a quadripolar lead placed in the subdural space over motor cortex, for electrocorticography potential recordings, and to a quadripolar lead in the subthalamic nucleus (STN), for both therapeutic stimulation and recording of local field potentials. Recordings from the brain of each patient were performed at multiple time points over a 1-year period. RESULTS There were no serious surgical complications or interruptions in deep brain stimulation therapy. Signals in both the cortex and the STN were relatively stable over time, despite a gradual increase in electrode impedance. Canonical movement-related changes in specific frequency bands in the motor cortex were identified in most but not all recordings. CONCLUSIONS The acquisition of chronic multisite field potentials in humans is feasible. The device performance characteristics described here may inform the design of the next generation of totally implantable neural interfaces. This research tool provides a platform for translating discoveries in brain network dynamics to improved neurostimulation paradigms. Clinical trial registration no.: NCT01934296 (clinicaltrials.gov).

Published

2018

183. Activation of the GABAergic Parafacial Zone Maintains Sleep and Counteracts the Wake-Promoting Action of the Psychostimulants Armodafinil and Caffeine.

Author

Anaclet, Christelle, Griffith, Kobi, and Fuller, Patrick M

Subjects

Medulla Oblongata, Animals, Mice, Benzhydryl Compounds, Caffeine, Central Nervous System Stimulants, Electromyography, Behavior, Animal, Sleep Stages, Male, GABAergic Neurons, Electrocorticography, Modafinil, Sleep Research, Nutrition, Behavioral and Social Science, Neurosciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry

Abstract

We previously reported that acute and selective activation of GABA-releasing parafacial zone (PZVgat) neurons in behaving mice produces slow-wave-sleep (SWS), even in the absence of sleep deficit, suggesting that these neurons may represent, at least in part, a key cellular substrate underlying sleep drive. It remains, however, to be determined if PZVgat neurons actively maintain, as oppose to simply gate, SWS. To begin to experimentally address this knowledge gap, we asked whether activation of PZVgat neurons could attenuate or block the wake-promoting effects of two widely used wake-promoting psychostimulants, armodafinil or caffeine. We found that activation of PZVgat neurons completely blocked the behavioral and electrocortical wake-promoting action of armodafinil. In some contrast, activation of PZVgat neurons inhibited the behavioral, but not electrocortical, arousal response to caffeine. These results suggest that: (1) PZVgat neurons actively maintain, as oppose to simply gate, SWS and cortical slow-wave-activity; (2) armodafinil cannot exert its wake-promoting effects when PZVgat neurons are activated, intimating a possible shared circuit/molecular basis for mechanism of action; (3) caffeine can continue to exert potent cortical desynchronizing, but not behavioral, effects when PZVgat neurons are activated, inferring a shared and divergent circuit/molecular basis for mechanism of action; and 4) PZVgat neurons represent a key cell population for SWS induction and maintenance.

Published

2018

184. Totally Implantable Bidirectional Neural Prostheses: A Flexible Platform for Innovation in Neuromodulation

Author

Starr, Philip A

Subjects

Biological Psychology, Biomedical and Clinical Sciences, Neurosciences, Psychology, Mental Health, Rehabilitation, Bioengineering, Brain Disorders, Assistive Technology, 5.3 Medical devices, Development of treatments and therapeutic interventions, Neurological, neural prostheses, brain-computer interface, deep brain stimulation, bidirectional interface, oscillatory brain activity, electrocorticography, local field potential, brain sensing, Cognitive Sciences, Biological psychology

Abstract

Implantable neural prostheses are in widespread use for treating a variety of brain disorders. Until recently, most implantable brain devices have been unidirectional, either delivering neurostimulation without brain sensing, or sensing brain activity to drive external effectors without a stimulation component. Further, many neural interfaces that incorporate a sensing function have relied on hardwired connections, such that subjects are tethered to external computers and cannot move freely. A new generation of neural prostheses has become available, that are both bidirectional (stimulate as well as record brain activity) and totally implantable (no externalized connections). These devices provide an opportunity for discovering the circuit basis for neuropsychiatric disorders, and to prototype personalized neuromodulation therapies that selectively interrupt neural activity underlying specific signs and symptoms.

Published

2018

185. Spontaneous Neural Activity in the Superior Temporal Gyrus Recapitulates Tuning for Speech Features

Author

Breshears, Jonathan D, Hamilton, Liberty S, and Chang, Edward F

Subjects

Biomedical and Clinical Sciences, Neurosciences, Clinical Research, Brain Disorders, Neurological, electrocorticography, speech perception, high gamma activity, resting state networks, spatiotemporal dynamics, Psychology, Cognitive Sciences, Experimental Psychology, Biological psychology, Cognitive and computational psychology

Abstract

Background: Numerous studies have demonstrated that individuals exhibit structured neural activity in many brain regions during rest that is also observed during different tasks, however it is still not clear whether and how resting state activity patterns may relate to underlying tuning for specific stimuli. In the posterior superior temporal gyrus (STG), distinct neural activity patterns are observed during the perception of specific linguistic speech features. We hypothesized that spontaneous resting-state neural dynamics of the STG would be structured to reflect its role in speech perception, exhibiting an organization along speech features as seen during speech perception. Methods: Human cortical local field potentials were recorded from the superior temporal gyrus (STG) in 8 patients undergoing surgical treatment of epilepsy. Signals were recorded during speech perception and rest. Patterns of neural activity (high gamma power: 70-150 Hz) during rest, extracted with spatiotemporal principal component analysis, were compared to spatiotemporal neural responses to speech features during perception. Hierarchical clustering was applied to look for patterns in rest that corresponded to speech feature tuning. Results: Significant correlations were found between neural responses to speech features (sentence onsets, consonants, and vowels) and the spontaneous neural activity in the STG. Across subjects, these correlations clustered into five groups, demonstrating tuning for speech features-most robustly for acoustic onsets. These correlations were not seen in other brain areas, or during motor and spectrally-rotated speech control tasks. Conclusions: In this study, we present evidence that the RS structure of STG activity robustly recapitulates its stimulus-evoked response to acoustic onsets. Further, secondary patterns in RS activity appear to correlate with stimulus-evoked responses to speech features. The role of these spontaneous spatiotemporal activity patterns remains to be elucidated.

Published

2018

186. A method for the topographical identification and quantification of high frequency oscillations in intracranial electroencephalography recordings.

Author

Waldman, Zachary J, Shimamoto, Shoichi, Song, Inkyung, Orosz, Iren, Bragin, Anatol, Fried, Itzhak, Engel, Jerome, Staba, Richard, Sperling, Michael R, and Weiss, Shennan A

Subjects

Humans, Sensitivity and Specificity, Software, Adult, Aged, Middle Aged, Female, Male, Gamma Rhythm, Electrocorticography, Filter ringing, High-frequency oscillation, Ripple, Topography, Wavelet, Clinical Research, Clinical Trials and Supportive Activities, Engineering, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo develop a reliable software method using a topographic analysis of time-frequency plots to distinguish ripple (80-200 Hz) oscillations that are often associated with EEG sharp waves or spikes (RonS) from sinusoid-like waveforms that appear as ripples but correspond with digital filtering of sharp transients contained in the wide bandwidth EEG.MethodsA custom algorithm distinguished true from false ripples in one second intracranial EEG (iEEG) recordings using wavelet convolution, identifying contours of isopower, and categorizing these contours into sets of open or closed loop groups. The spectral and temporal features of candidate groups were used to classify the ripple, and determine its duration, frequency, and power. Verification of detector accuracy was performed on the basis of simulations, and visual inspection of the original and band-pass filtered signals.ResultsThe detector could distinguish simulated true from false ripple on spikes (RonS). Among 2934 visually verified trials of iEEG recordings and spectrograms exhibiting RonS the accuracy of the detector was 88.5% with a sensitivity of 81.8% and a specificity of 95.2%. The precision was 94.5% and the negative predictive value was 84.0% (N = 12). Among, 1,370 trials of iEEG recording exhibiting RonS that were reviewed blindly without spectrograms the accuracy of the detector was 68.0%, with kappa equal to 0.01 ± 0.03. The detector successfully distinguished ripple from high spectral frequency 'fast ripple' oscillations (200-600 Hz), and characterize ripple duration and spectral frequency and power. The detector was confounded by brief bursts of gamma (30-80 Hz) activity in 7.31 ± 6.09% of trials, and in 30.2 ± 14.4% of the true RonS detections ripple duration was underestimated.ConclusionsCharacterizing the topographic features of a time-frequency plot generated by wavelet convolution is useful for distinguishing true oscillations from false oscillations generated by filter ringing.SignificanceCategorizing ripple oscillations and characterizing their properties can improve the clinical utility of the biomarker.

Published

2018

187. Utilization of independent component analysis for accurate pathological ripple detection in intracranial EEG recordings recorded extra- and intra-operatively.

Author

Shimamoto, Shoichi, Waldman, Zachary J, Orosz, Iren, Song, Inkyung, Bragin, Anatol, Fried, Itzhak, Engel, Jerome, Staba, Richard, Sharan, Ashwini, Wu, Chengyuan, Sperling, Michael R, and Weiss, Shennan A

Subjects

Humans, Principal Component Analysis, Adolescent, Adult, Child, Female, Male, Signal-To-Noise Ratio, Intraoperative Neurophysiological Monitoring, Electrocorticography, Detector, High-frequency oscillation, Independent component analysis, Ripple, Brain Disorders, Clinical Research, Neurosciences, Engineering, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

ObjectiveTo develop and validate a detector that identifies ripple (80-200 Hz) events in intracranial EEG (iEEG) recordings in a referential montage and utilizes independent component analysis (ICA) to eliminate or reduce high-frequency artifact contamination. Also, investigate the correspondence of detected ripples and the seizure onset zone (SOZ).MethodsiEEG recordings from 16 patients were first band-pass filtered (80-600 Hz) and Infomax ICA was next applied to derive the first independent component (IC1). IC1 was subsequently pruned, and an artifact index was derived to reduce the identification of high-frequency events introduced by the reference electrode signal. A Hilbert detector identified ripple events in the processed iEEG recordings using amplitude and duration criteria. The identified ripple events were further classified and characterized as true or false ripple on spikes, or ripples on oscillations by utilizing a topographical analysis to their time-frequency plot, and confirmed by visual inspection.ResultsThe signal to noise ratio was improved by pruning IC1. The precision of the detector for ripple events was 91.27 ± 4.3%, and the sensitivity of the detector was 79.4 ± 3.0% (N = 16 patients, 5842 ripple events). The sensitivity and precision of the detector was equivalent in iEEG recordings obtained during sleep or intra-operatively. Across all the patients, true ripple on spike rates and also the rates of false ripple on spikes, that were generated due to filter ringing, classified the seizure onset zone (SOZ) with an area under the receiver operating curve (AUROC) of >76%. The magnitude and spectral content of true ripple on spikes generated in the SOZ was distinct as compared with the ripples generated in the NSOZ (p

Published

2018

188. Differential Sources for 2 Neural Signatures of Target Detection: An Electrocorticography Study.

Author

Kam, JWY, Szczepanski, SM, Canolty, RT, Flinker, A, Auguste, KI, Crone, NE, Kirsch, HE, Kuperman, RA, Lin, JJ, Parvizi, J, and Knight, RT

Subjects

Neurodegenerative, Epilepsy, Neurosciences, Clinical Research, Brain Disorders, Detection, screening and diagnosis, 4.1 Discovery and preclinical testing of markers and technologies, Neurological, Adolescent, Adult, Attention, Auditory Perception, Brain, Electrocorticography, Evoked Potentials, Female, Humans, Male, Middle Aged, Neuropsychological Tests, Signal Detection, Psychological, Visual Perception, Young Adult, electrocorticography, high frequency band, neural generators, P3b, target detection, Psychology, Cognitive Sciences, Experimental Psychology

Abstract

Electrophysiology and neuroimaging provide conflicting evidence for the neural contributions to target detection. Scalp electroencephalography (EEG) studies localize the P3b event-related potential component mainly to parietal cortex, whereas neuroimaging studies report activations in both frontal and parietal cortices. We addressed this discrepancy by examining the sources that generate the target-detection process using electrocorticography (ECoG). We recorded ECoG activity from cortex in 14 patients undergoing epilepsy monitoring, as they performed an auditory or visual target-detection task. We examined target-related responses in 2 domains: high frequency band (HFB) activity and the P3b. Across tasks, we observed a greater proportion of electrodes that showed target-specific HFB power relative to P3b over frontal cortex, but their proportions over parietal cortex were comparable. Notably, there was minimal overlap in the electrodes that showed target-specific HFB and P3b activity. These results revealed that the target-detection process is characterized by at least 2 different neural markers with distinct cortical distributions. Our findings suggest that separate neural mechanisms are driving the differential patterns of activity observed in scalp EEG and neuroimaging studies, with the P3b reflecting EEG findings and HFB activity reflecting neuroimaging findings, highlighting the notion that target detection is not a unitary phenomenon.

Published

2018

189. Language recovery after epilepsy surgery of the Broca's area.

Author

Mnatsakanyan, Lilit, Vadera, Sumeet, Ingalls, Christopher W, Zheng, Jie, Sazgar, Mona, Hsu, Frank P, and Lin, Jack J

Subjects

Electrocorticography, Eloquent cortex, Epilepsy surgery, Language and epilepsy, Refractory epilepsy, Epilepsy, Brain Disorders, Neurosciences, Neurodegenerative, 2.1 Biological and endogenous factors, Aetiology, Neurological

Abstract

Epilepsy surgery is indicated in select patients with drug-resistant focal epilepsy. Seizure freedom or significant reduction of seizure burden without risking new neurological deficits is the expected goal of epilepsy surgery. Typically, when the seizure onset zone overlaps with eloquent cortex, patients are excluded from surgery. We present a patient with drug-resistant frontal lobe epilepsy who underwent successful surgery with resection of Broca's area, primarily involving the pars triangularis (BA 45). We report transient expressive aphasia followed by recovery of speech. This case provides new insights into adult neuroplasticity of the language network.

Published

2018

190. Theta Oscillations in the Human Medial Temporal Lobe during Real-World Ambulatory Movement

Author

Aghajan, Zahra M, Schuette, Peter, Fields, Tony A, Tran, Michelle E, Siddiqui, Sameed M, Hasulak, Nicholas R, Tcheng, Thomas K, Eliashiv, Dawn, Mankin, Emily A, Stern, John, Fried, Itzhak, and Suthana, Nanthia

Subjects

Neurosciences, Behavioral and Social Science, Basic Behavioral and Social Science, Clinical Research, Neurological, Adult, Electrocorticography, Female, Humans, Implantable Neurostimulators, Male, Middle Aged, Temporal Lobe, Theta Rhythm, Walking, MTL, NeuroPace responsive neurostimulator, human, medial temporal lobe, navigation, theta oscillations, wireless intracranial recordings, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Developmental Biology

Abstract

The theta rhythm-a slow (6-12 Hz) oscillatory component of the local field potential-plays a critical role in spatial navigation and memory by coordinating the activity of neuronal ensembles within the medial temporal lobe (MTL). Although theta has been extensively studied in freely moving rodents, its presence in humans has been elusive and primarily investigated in stationary subjects. Here we used a unique clinical opportunity to examine theta within the human MTL during untethered, real-world ambulatory movement. We recorded intracranial electroencephalographic activity from participants chronically implanted with the wireless NeuroPace responsive neurostimulator (RNS) and tracked their motion with sub-millimeter precision. Our data revealed that movement-related theta oscillations indeed exist in humans, such that theta power is significantly higher during movement than immobility. Unlike in rodents, however, theta occurs in short bouts, with average durations of ∼400 ms, which are more prevalent during fast versus slow movements. In a rare opportunity to study a congenitally blind participant, we found that both the prevalence and duration of theta bouts were increased relative to the sighted participants. These results provide critical support for conserved neurobiological characteristics of theta oscillations during ambulatory spatial navigation, while highlighting some fundamental differences across species in these oscillations between humans and rodents.

Published

2017

191. Evaluation of a new cortical strip electrode for intraoperative somatosensory monitoring during perirolandic brain surgery.

Author

Sarnthein, Johannes, Seidel, Kathleen, Neidert, Marian Christoph, Raabe, Andreas, Sala, Francesco, Tonn, Joerg Christian, Thon, Niklas, and Szelenyi, Andrea

Subjects

*BRAIN surgery, *SOMATOSENSORY evoked potentials, *PLATINUM nanoparticles, *INTRAOPERATIVE monitoring, *ELECTRODES, *MOTOR cortex

Abstract

• We performed a prospective multicenter medical device study. • Polymer strips with embedded metal nanoparticles had lower impedance than the comparator device. • The electrodes achieved good signal-to-noise-ratio. During neurosurgical procedures, strip electrodes should have low impedance and sufficient adherence on the brain surface. We evaluated the signal quality, safety, and performance of a novel strip electrode (WISE Cortical Strip, WCS®), with conductive electrode contacts created with platinum nanoparticles embedded in a polymer base. In a multicenter interventional, non-inferiority study, we compared WCS to a conventional strip electrode (Ad-Tech). We recorded impedance and somatosensory evoked potentials (SEP) and determined the signal-to-noise ratio (SNR). We performed direct stimulation of the motor cortex. An external clinical event committee rated safety and adverse events and users rated usability. During 32 brain surgeries in the paracentral region, WCS was rated safe and effective in signal transmission. Two seizure events were classified as probably related to the stimulation with WCS. The users rated WCS adhesion to the brain as satisfactory but reported difficulties sliding the WCS under the dura. The median (IQR) impedance of WCS was lower than for Ad-Tech: 2.7 (2.3–3.7) vs 5.30 (4.3–6.6) kΩ (p < 0.005). The SNR of SEP was non-inferior for WCS compared to Ad-Tech. The impedance of WCS was lower than Ad-Tech without safety limitations. In small craniotomies not exposing the motor cortex its use may be limited. Low impedance electrodes facilitate recordings with high SNR. [ABSTRACT FROM AUTHOR]

Published

2022

192. Effect of irisin on the epilepsy induced by penicillin G: An electrophysiological study.

Author

ŞAHİN YILDIZ, Yasemin, DEMİR, Şerif, BEYAZÇİÇEK, Ersin, GÖK, Ali, and BEYAZÇİÇEK, Özge

Subjects

*PENICILLIN G, *IRISIN, *EPILEPSY, *ELECTROPHYSIOLOGY, *LABORATORY rats

Abstract

Epilepsy is a neurological disease characterized by sudden and synchronized seizures caused by abnormal and excessive electrical discharges in brain neurons. The purpose of this study was to electrophysiologically examine the effects of acute administration of irisin, which is thought to be neuroprotective and increase cell proliferation, at different doses (10 and 100 nM) on the penicillin-induced experimental epilepsy in rats. Fortynine adult male Wistar rats were used in the study. The rats were divided into 7 groups: sham, control group (penicillin), irisin group, the pre- and during-seizure groups of 10 nM and 100 nM irisin. All the substances except penicillin were administered intraperitoneally. The rats were anesthetized using urethane. The bone tissue on the left cerebral cortex was removed and the electrodes were placed in the somatomotor cortex. Thirty minutes before penicillin administration, irisin was administered to the pre-seizure penicillin group at doses of 10 nM and 100 nM. Then, penicillin (500 IU/2 µl) was injected intracortically, and ECoG recording was continued for 120 minutes. On the other hand, 10 nM and 100 nM of irisin were administered to the during-seizure penicillin group after penicillin was injected intracortically and the seizure occurred, and ECoG recording was continued for 120 minutes. The ECoG recordings were analyzed using the PowerLab Chart v.8 software. In conclusion, it was found that irisin prolonged the latency of initial epileptic activity and decreased the number and amplitude of spike-waves in the penicillin-induced experimental epilepsy model. These results suggest that irisin might have an antiepileptic potential. [ABSTRACT FROM AUTHOR]

Published

2022

193. Changes in Brain Electrical Activity after Transient Middle Cerebral Artery Occlusion in Rats.

Author

Sysoev, Yuriy I., Prikhodko, Veronika A., Kan, Aleksandra V., Titovich, Irina A., Karev, Vadim E., and Okovityi, Sergey V.

Subjects

*ARTERIAL occlusions, *CEREBRAL arteries, *CEREBRAL ischemia, *ISCHEMIC stroke, *RATS, *ELECTRICAL injuries

Abstract

Objectives. Ischemic stroke is a leading cause of death and disability worldwide. To search for new therapeutic and pharmacotherapeutic strategies, numerous models of this disease have been proposed, the most popular being transient middle cerebral artery occlusion. Behavioral and sensorimotor testing, biochemical, and histological methods are traditionally used in conjunction with this model to assess the effectiveness of potential treatment options. Despite its wide overall popularity, electroencephalography/electrocorticography is quite rarely used in such studies. Materials and methods. In the present work, we explored the changes in brain electrical activity at days 3 and 7 after 30- and 45-min of transient middle cerebral artery occlusion in rats. Results. Cerebral ischemia altered the amplitude and spectral electrocorticogram characteristics, and led to a reorganization of inter- and intrahemispheric functional connections. Ischemia duration affected the severity as well as the nature of the observed changes. Conclusions. The dynamics of changes in brain electrical activity may indicate a spontaneous partial recovery of impaired cerebral functions at post-surgery day 7. Our results suggest that electrocorticography can be used successfully to assess the functional status of the brain following ischemic stroke in rats as well as to investigate the dynamics of functional recovery. [ABSTRACT FROM AUTHOR]

Published

2022

194. Investigating Unilateral and Bilateral Motor Imagery Control Using Electrocorticography and fMRI in Awake Craniotomy.

Author

Ma J, Li Z, Zheng Q, Li S, Zong R, Qin Z, Wan L, Zhao Z, Mao Z, Zhang Y, Yu X, Bai H, and Zhang J

Abstract

Background: The rapid development of neurosurgical techniques, such as awake craniotomy, has increased opportunities to explore the mysteries of the brain. This is crucial for deepening our understanding of motor control and imagination processes, especially in developing brain-computer interface (BCI) technologies and improving neurorehabilitation strategies for neurological disorders., Objective: This study aimed to analyze brain activity patterns in patients undergoing awake craniotomy during actual movements and motor imagery, mainly focusing on the motor control processes of the bilateral limbs., Methods: We conducted detailed observations of patients undergoing awake craniotomies. The experimenter requested participants to perform and imagine a series of motor tasks involving their hands and tongues. Brain activity during these tasks was recorded using functional magnetic resonance imaging (fMRI) and intraoperative electrocorticography (ECoG). The study included left and right finger tapping, tongue protrusion, hand clenching, and imagined movements corresponding to these actions., Results: fMRI revealed significant activation in the brain's motor areas during task performance, mainly involving bilateral brain regions during imagined movement. ECoG data demonstrated a marked desynchronization pattern in the ipsilateral motor cortex during bilateral motor imagination, especially in bilateral coordination tasks. This finding suggests a potential controlling role of the unilateral cerebral cortex in bilateral motor imagination., Conclusion: Our study highlights the unilateral cerebral cortex's significance in controlling bilateral limb motor imagination, offering new insights into future brain network remodeling in patients with hemiplegia. Additionally, these findings provide important insights into understanding motor imagination and its impact on BCI and neurorehabilitation., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

195. Electrophysiological dynamics of salience, default mode, and frontoparietal networks during episodic memory formation and recall revealed through multi-experiment iEEG replication.

Author

Das A and Menon V

Subjects

Humans, Male, Adult, Female, Young Adult, Parietal Lobe physiology, Electroencephalography, Frontal Lobe physiology, Electrocorticography, Memory, Episodic, Mental Recall physiology, Default Mode Network physiology, Nerve Net physiology

Abstract

Dynamic interactions between large-scale brain networks underpin human cognitive processes, but their electrophysiological mechanisms remain elusive. The triple network model, encompassing the salience network (SN), default mode network (DMN), and frontoparietal network (FPN), provides a framework for understanding these interactions. We analyzed intracranial electroencephalography (EEG) recordings from 177 participants across four diverse episodic memory experiments, each involving encoding as well as recall phases. Phase transfer entropy analysis revealed consistently higher directed information flow from the anterior insula (AI), a key SN node, to both DMN and FPN nodes. This directed influence was significantly stronger during memory tasks compared to resting state, highlighting the AI's task-specific role in coordinating large-scale network interactions. This pattern persisted across externally driven memory encoding and internally governed free recall. Control analyses using the inferior frontal gyrus (IFG) showed an inverse pattern, with DMN and FPN exerting higher influence on IFG, underscoring the AI's unique role. We observed task-specific suppression of high-gamma power in the posterior cingulate cortex/precuneus node of the DMN during memory encoding, but not recall. Crucially, these results were replicated across all four experiments spanning verbal and spatial memory domains with high Bayes replication factors. Our findings advance understanding of how coordinated neural network interactions support memory processes, highlighting the AI's critical role in orchestrating large-scale brain network dynamics during both memory encoding and retrieval. By elucidating the electrophysiological basis of triple network interactions in episodic memory, our study provides insights into neural circuit dynamics underlying memory function and offer a framework for investigating network disruptions in memory-related disorders., Competing Interests: AD, VM No competing interests declared, (© 2024, Das and Menon.)

Published

2024

196. Shapes of direct cortical responses vs. short-range axono-cortical evoked potentials: The effects of direct electrical stimulation applied to the human brain.

Author

Turpin C, Rossel O, Schlosser-Perrin F, Ng S, Matsumoto R, Mandonnet E, Duffau H, and Bonnetblanc F

Abstract

Objective: Direct cortical responses (DCR) and axono-cortical evoked potentials (ACEP) are generated by electrically stimulating the cortex either directly or indirectly through white matter pathways, potentially leading to different electrogenic processes. For ACEP, the slow conduction velocity of axons (median ≈ 4 m.s -1 ) is anticipated to induce a delay. For DCR, direct electrical stimulation (DES) of the cortex is expected to elicit additional cortical activity involving smaller and slower non-myelinated axons. We tried to validate these hypotheses., Methods: DES was administered either directly on the cortex or to white matter fascicles within the resection cavity, while recording DCR or ACEP at the cortical level in nine patients., Results: Short but significant delays (≈ 2 ms) were measurable for ACEP immediately following the initial component (≈ 7 ms). Subsequent activities (≈ 40 ms) exhibited notable differences between DCR and ACEP, suggesting the presence of additional cortical activities for DCR., Conclusion: Distinctions between ACEPs and DCRs can be made based on a delay at the onset of early components and the dissimilarity in the shape of the later components (>40 ms after the DES artifact)., Significance: The comparison of different types of evoked potentials allows to better understand the effects of DES., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 International Federation of Clinical Neurophysiology. Published by Elsevier B.V. All rights reserved.)

Published

2024

197. Spatiotemporal Neural Network for Sublexical Information Processing: An Intracranial SEEG Study.

Author

Zhao C, Liu Y, Zeng J, Luo X, Sun W, Luan G, Liu Y, Zhang Y, Shi G, Guan Y, and Han Z

Subjects

Humans, Male, Female, Adult, Young Adult, Brain Mapping, Middle Aged, Semantics, Electrocorticography, Brain physiology, Brain diagnostic imaging, Adolescent, Electroencephalography, Epilepsy physiopathology, Epilepsy diagnostic imaging, Reading, Nerve Net diagnostic imaging, Nerve Net physiology

Abstract

Words offer a unique opportunity to separate the processing mechanisms of object subcomponents from those of the whole object, because the phonological or semantic information provided by the word subcomponents (i.e., sublexical information) can conflict with that provided by the whole word (i.e., lexical information). Previous studies have revealed some of the specific brain regions and temporal information involved in sublexical information processing. However, a comprehensive spatiotemporal neural network for sublexical processing remains to be fully elucidated due to the low temporal or spatial resolutions of previous neuroimaging studies. In this study, we recorded stereoelectroencephalography signals with high spatial and temporal resolutions from a large sample of 39 epilepsy patients (both sexes) during a Chinese character oral reading task. We explored the activated brain regions and their connectivity related to three sublexical effects: phonological regularity (whether the whole character's pronunciation aligns with its phonetic radical), phonological consistency (whether characters with the same phonetic radical share the same pronunciation), and semantic transparency (whether the whole character's meaning aligns with its semantic radical). The results revealed that sublexical effects existed in the inferior frontal gyrus, precentral and postcentral gyri, temporal lobe, and middle occipital gyrus. Additionally, connectivity from the middle occipital gyrus to the postcentral gyrus and from postcentral gyrus to the fusiform gyrus was associated with the sublexical effects. These findings provide valuable insights into the spatiotemporal dynamics of sublexical processing and object recognition in the brain., Competing Interests: The authors declare no competing financial interests., (Copyright © 2024 Zhao et al.)

Published

2024

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

Author

Yang X, Fiebelkorn IC, Jensen O, Knight RT, and Kastner S

Subjects

Humans, Male, Female, Adult, Young Adult, Electrocorticography, Electroencephalography, Space Perception physiology, Photic Stimulation, Attention physiology, Alpha Rhythm physiology, Visual Perception physiology

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., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

199. Reward recalibrates rule representations in human amygdala and hippocampus intracranial recordings.

Author

Manssuer L, Ding Q, Feng Y, Yang R, Liu W, Sun B, Zhan S, and Voon V

Subjects

Humans, Male, Adult, Female, Decision Making physiology, Magnetic Resonance Imaging, Young Adult, Middle Aged, Electrocorticography, Gamma Rhythm physiology, Amygdala physiology, Amygdala diagnostic imaging, Amygdala physiopathology, Hippocampus physiology, Hippocampus diagnostic imaging, Hippocampus physiopathology, Reward, Epilepsy physiopathology, Epilepsy diagnostic imaging

Abstract

Adaptive behavior requires the ability to shift responding within (intra-dimensional) or between (extra-dimensional) stimulus dimensions when reward contingencies change. Studies of shifting in humans have focused mainly on the prefrontal cortex and/ or have been restricted to indirect measures of neural activity such as fMRI and lesions. Here, we demonstrate the importance of the amygdala and hippocampus by recording local field potentials directly from these regions intracranially in human epilepsy patients. Reward signals were coded in the high frequency gamma activity (HFG; 60-250 Hz) of both regions and synchronised via low frequency (3-5 Hz) phase-locking only after a shift when patients did not already know the rule and it signalled to stop shifting ("Win-Stay"). In contrast, HFG punishment signals were only seen in the amygdala when the rule then changed and it signalled to start shifting ("Lose-Shift"). During decision-making, hippocampal HFG was more inhibited on non-shift relative to shift trials, suggesting a role in preventing interference in rule representation and amygdala HFG was sensitive to stimulus novelty. The findings expand our understanding of human amygdala-hippocampal function and shifting processes, the disruption of which could contribute to shifting deficits in neuropsychiatric disorders., (© 2024. The Author(s).)

Published

2024

200. Spatiotemporal hierarchies of face representation in the human ventral temporal cortex.

Author

Salehi S, Dehaqani MRA, Schrouff J, Sava-Segal C, Raccah O, and Baek S

Subjects

Humans, Female, Adult, Male, Electroencephalography, Photic Stimulation, Brain Mapping, Young Adult, Face physiology, Middle Aged, Electrocorticography, Temporal Lobe physiology, Facial Recognition physiology

Abstract

In this study, we examined the relatively unexplored realm of face perception, investigating the activities within human brain face-selective regions during the observation of faces at both subordinate and superordinate levels. We recorded intracranial EEG signals from the ventral temporal cortex in neurosurgical patients implanted with subdural electrodes during viewing of face subcategories (human, mammal, bird, and marine faces) as well as various non-face control stimuli. The results revealed a noteworthy correlation in response patterns across all face-selective areas in the ventral temporal cortex, not only within the same face category but also extending to different face categories. Intriguingly, we observed a systematic decrease in response correlation coupled with an increased response onset time from human face to mammalian face, bird face and marine faces. Our result aligns with the notion that distinctions at the basic level category (e.g., human face versus non-human face) emerges earlier than those at the superordinate level (e.g., animate versus inanimate). This indicates response gradient in the representation of facial images within human face-sensitive regions, transitioning progressively from human faces to non-face stimuli. Our findings provide insights into spatiotemporal dynamic of face representations which varies spatially and at different timescales depending on the face subcategory represented., (© 2024. The Author(s).)

Published

2024