Your search keyword '"Nathan E Crone"' showing total 117 results

1. Brain-Computer Interface: Applications to Speech Decoding and Synthesis to Augment Communication

Author

Shiyu Luo, Qinwan Rabbani, and Nathan E. Crone

Subjects

Pharmacology, Current Perspectives, Brain-Computer Interfaces, Communication, Quality of Life, Humans, Speech, Pharmacology (medical), Electrocorticography, Neurology (clinical)

Abstract

Damage or degeneration of motor pathways necessary for speech and other movements, as in brainstem strokes or amyotrophic lateral sclerosis (ALS), can interfere with efficient communication without affecting brain structures responsible for language or cognition. In the worst-case scenario, this can result in the locked in syndrome (LIS), a condition in which individuals cannot initiate communication and can only express themselves by answering yes/no questions with eye blinks or other rudimentary movements. Existing augmentative and alternative communication (AAC) devices that rely on eye tracking can improve the quality of life for people with this condition, but brain-computer interfaces (BCIs) are also increasingly being investigated as AAC devices, particularly when eye tracking is too slow or unreliable. Moreover, with recent and ongoing advances in machine learning and neural recording technologies, BCIs may offer the only means to go beyond cursor control and text generation on a computer, to allow real-time synthesis of speech, which would arguably offer the most efficient and expressive channel for communication. The potential for BCI speech synthesis has only recently been realized because of seminal studies of the neuroanatomical and neurophysiological underpinnings of speech production using intracranial electrocorticographic (ECoG) recordings in patients undergoing epilepsy surgery. These studies have shown that cortical areas responsible for vocalization and articulation are distributed over a large area of ventral sensorimotor cortex, and that it is possible to decode speech and reconstruct its acoustics from ECoG if these areas are recorded with sufficiently dense and comprehensive electrode arrays. In this article, we review these advances, including the latest neural decoding strategies that range from deep learning models to the direct concatenation of speech units. We also discuss state-of-the-art vocoders that are integral in constructing natural-sounding audio waveforms for speech BCIs. Finally, this review outlines some of the challenges ahead in directly synthesizing speech for patients with LIS. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s13311-022-01190-2.

Published

2022

2. Ethical commitments, principles, and practices guiding intracranial neuroscientific research in humans

Author

Ashley Feinsinger, Nader Pouratian, Hamasa Ebadi, Ralph Adolphs, Richard Andersen, Michael S. Beauchamp, Edward F. Chang, Nathan E. Crone, Jennifer L. Collinger, Itzhak Fried, Adam Mamelak, Mark Richardson, Ueli Rutishauser, Sameer A. Sheth, Nanthia Suthana, Nitin Tandon, and Daniel Yoshor

Subjects

General Neuroscience, Neurosciences, Uncertainty, Brain, Humans, Morals, Article, Research Personnel

Abstract

Leveraging firsthand experience, BRAIN-funded investigators conducting intracranial human neuroscience research propose two fundamental ethical commitments: (1) maintaining the integrity of clinical care and (2) ensuring voluntariness. Principles, practices, and uncertainties related to these commitments are offered for future investigation.

Published

2022

3. Intracortical Somatosensory Stimulation to Elicit Fingertip Sensations in an Individual With Spinal Cord Injury

Author

Matthew S. Fifer, David P. McMullen, Luke E. Osborn, Tessy M. Thomas, Breanne Christie, Robert W. Nickl, Daniel N. Candrea, Eric A. Pohlmeyer, Margaret C. Thompson, Manuel A. Anaya, Wouter Schellekens, Nick F. Ramsey, Sliman J. Bensmaia, William S. Anderson, Brock A. Wester, Nathan E. Crone, Pablo A. Celnik, Gabriela L. Cantarero, and Francesco V. Tenore

Subjects

Touch, Humans, Somatosensory Cortex, Neurology (clinical), Hand, Electric Stimulation, Spinal Cord Injuries

Abstract

Background and ObjectivesThe restoration of touch to fingers and fingertips is critical to achieving dexterous neuroprosthetic control for individuals with sensorimotor dysfunction. However, localized fingertip sensations have not been evoked via intracortical microstimulation (ICMS).MethodsUsing a novel intraoperative mapping approach, we implanted electrode arrays in the finger areas of left and right somatosensory cortex and delivered ICMS over a 2-year period in a human participant with spinal cord injury.ResultsStimulation evoked tactile sensations in 8 fingers, including fingertips, spanning both hands. Evoked percepts followed expected somatotopic arrangements. The subject was able to reliably identify up to 7 finger-specific sites spanning both hands in a finger discrimination task. The size of the evoked percepts was on average 33% larger than a finger pad, as assessed via manual markings of a hand image. The size of the evoked percepts increased modestly with increased stimulation intensity, growing 21% as pulse amplitude increased from 20 to 80 µA. Detection thresholds were estimated on a subset of electrodes, with estimates of 9.2 to 35 µA observed, roughly consistent with prior studies.DiscussionThese results suggest that ICMS can enable the delivery of consistent and localized fingertip sensations during object manipulation by neuroprostheses for individuals with somatosensory deficits.ClinicalTrials.gov IdentifierNCT03161067.

Published

2021

4. Graph theoretical analysis of evoked potentials shows network influence of epileptogenic mesial temporal region

Author

Christopher Coogan, Nathan E. Crone, Mark A. Hays, and Joon Y. Kang

Subjects

Adult, Male, graph theory, single‐pulse electrical stimulation, mesial temporal lobe epilepsy, Biology, 050105 experimental psychology, intracranial EEG, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Connectome, Humans, 0501 psychology and cognitive sciences, Radiology, Nuclear Medicine and imaging, In patient, Evoked potential, Evoked Potentials, Research Articles, Graph analytics, evoked potential, Radiological and Ultrasound Technology, 05 social sciences, Middle Aged, Network density, Intracranial eeg, Neurology, Epilepsy, Temporal Lobe, Female, Neurology (clinical), Electrocorticography, Anatomy, Neuroscience, 030217 neurology & neurosurgery, Mesial temporal lobe epilepsy, Research Article

Abstract

It is now widely accepted that seizures arise from the coordinated activity of epileptic networks, and as a result, traditional methods of analyzing seizures have been augmented by techniques like single‐pulse electrical stimulation (SPES) that estimate effective connectivity in brain networks. We used SPES and graph analytics in 18 patients undergoing intracranial EEG monitoring to investigate effective connectivity between recording sites within and outside mesial temporal structures. We compared evoked potential amplitude, network density, and centrality measures inside and outside the mesial temporal region (MTR) across three patient groups: focal epileptogenic MTR, multifocal epileptogenic MTR, and non‐epileptogenic MTR. Effective connectivity within the MTR had significantly greater magnitude (evoked potential amplitude) and network density, regardless of epileptogenicity. However, effective connectivity between MTR and surrounding non‐epileptogenic regions was of greater magnitude and density in patients with focal epileptogenic MTR compared to patients with multifocal epileptogenic MTR and those with non‐epileptogenic MTR. Moreover, electrodes within focal epileptogenic MTR had significantly greater outward network centrality compared to electrodes outside non‐epileptogenic regions and to multifocal and non‐epileptogenic MTR. Our results indicate that the MTR is a robustly connected subnetwork that can exert an overall elevated propagative influence over other brain regions when it is epileptogenic. Understanding the underlying effective connectivity and roles of epileptogenic regions within the larger network may provide insights that eventually lead to improved surgical outcomes., Hays et al. utilize evoked potentials from single‐pulse electrical stimulation to map effective networks in mesial temporal epilepsy patients. Graph theoretical analysis of these connections is applied to characterize the role of mesial temporal structures within broader epileptogenic networks, revealing a highly hyperexcitable and influential densely connected subnetwork. This approach provides additional groundwork to better understand epilepsy as a network disorder and identify epileptogenic hubs of connectivity for network targeted treatments.

Published

2021

5. Significance of event related causality (ERC) in eloquent neural networks

Author

Anna Korzeniewska, Takumi Mitsuhashi, Yujing Wang, Eishi Asano, Piotr J. Franaszczuk, and Nathan E. Crone

Subjects

Brain Mapping, Epilepsy, Artificial Intelligence, Cognitive Neuroscience, Brain, Humans, Electroencephalography, Neural Networks, Computer, Article

Abstract

Neural activity emerges and propagates swiftly between brain areas. Investigation of these transient large-scale flows requires sophisticated statistical models. We present a method for assessing the statistical confidence of event-related neural propagation. Furthermore, we propose a criterion for statistical model selection, based on both goodness of fit and width of confidence intervals. We show that event-related causality (ERC) with two-dimensional (2D) moving average, is an efficient estimator of task-related neural propagation and that it can be used to determine how different cognitive task demands affect the strength and directionality of neural propagation across human cortical networks. Using electrodes surgically implanted on the surface of the brain for clinical testing prior to epilepsy surgery, we recorded electrocorticographic (ECoG) signals as subjects performed three naming tasks: naming of ambiguous and unambiguous visual objects, and as a contrast, naming to auditory description. ERC revealed robust and statistically significant patterns of high gamma activity propagation, consistent with models of visually and auditorily cued word production. Interestingly, ambiguous visual stimuli elicited more robust propagation from visual to auditory cortices relative to unambiguous stimuli, whereas naming to auditory description elicited propagation in the opposite direction, consistent with recruitment of modalities other than those of the stimulus during object recognition and naming. The new method introduced here is uniquely suitable to both research and clinical applications and can be used to estimate the statistical significance of neural propagation for both cognitive neuroscientific studies and functional brain mapping prior to resective surgery for epilepsy and brain tumors.

Published

2022

6. Stimulating native seizures with neural resonance: a new approach to localize the seizure onset zone

Author

Rachel J Smith, Mark A Hays, Golnoosh Kamali, Christopher Coogan, Nathan E Crone, Joon Y Kang, and Sridevi V Sarma

Subjects

Translational Research, Biomedical, Drug Resistant Epilepsy, Engineering, Epilepsy, Seizures, Humans, Brain, Original Article, Electroencephalography, Neurology (clinical), Electrocorticography, Retrospective Studies

Abstract

Successful outcomes in epilepsy surgery rely on the accurate localization of the seizure onset zone. Localizing the seizure onset zone is often a costly and time-consuming process wherein a patient undergoes intracranial EEG monitoring, and a team of clinicians wait for seizures to occur. Clinicians then analyse the intracranial EEG before each seizure onset to identify the seizure onset zone and localization accuracy increases when more seizures are captured. In this study, we develop a new approach to guide clinicians to actively elicit seizures with electrical stimulation. We propose that a brain region belongs to the seizure onset zone if a periodic stimulation at a particular frequency produces large amplitude oscillations in the intracranial EEG network that propagate seizure activity. Such responses occur when there is ‘resonance’ in the intracranial EEG network, and the resonant frequency can be detected by observing a sharp peak in the magnitude versus frequency response curve, called a Bode plot. To test our hypothesis, we analysed single-pulse electrical stimulation response data in 32 epilepsy patients undergoing intracranial EEG monitoring. For each patient and each stimulated brain region, we constructed a Bode plot by estimating a transfer function model from the intracranial EEG ‘impulse’ or single-pulse electrical stimulation response. The Bode plots were then analysed for evidence of resonance. First, we showed that when Bode plot features were used as a marker of the seizure onset zone, it distinguished successful from failed surgical outcomes with an area under the curve of 0.83, an accuracy that surpassed current methods of analysis with cortico-cortical evoked potential amplitude and cortico-cortical spectral responses. Then, we retrospectively showed that three out of five native seizures accidentally triggered in four patients during routine periodic stimulation at a given frequency corresponded to a resonant peak in the Bode plot. Last, we prospectively stimulated peak resonant frequencies gleaned from the Bode plots to elicit seizures in six patients, and this resulted in an induction of three seizures and three auras in these patients. These findings suggest neural resonance as a new biomarker of the seizure onset zone that can guide clinicians in eliciting native seizures to more quickly and accurately localize the seizure onset zone.

Published

2022

7. Intracortical microstimulation of somatosensory cortex enables object identification through perceived sensations

Author

Luke E. Osborn, Breanne P. Christie, David P. McMullen, Robert W. Nickl, Margaret C. Thompson, Ambarish S. Pawar, Tessy M. Thomas, Manuel Alejandro Anaya, Nathan E. Crone, Brock A. Wester, Sliman J. Bensmaia, Pablo A. Celnik, Gabriela L. Cantarero, Francesco V. Tenore, and Matthew S. Fifer

Subjects

Touch, Humans, Somatosensory Cortex, Hand, Microelectrodes, Electric Stimulation

Abstract

Advances in brain-machine interfaces have helped restore function and independence for individuals with sensorimotor deficits; however, providing efficient and effective sensory feedback remains challenging. Intracortical microstimulation (ICMS) of sensorimotor brain regions is a promising technique for providing bioinspired sensory feedback. In a human participant with chronically-implanted microelectrode arrays, we provided ICMS to the primary somatosensory cortex to generate tactile percepts in his hand. In a 3-choice object identification task, the participant identified virtual objects using tactile sensory feedback and no visual information. We evaluated three different stimulation paradigms, each with a different weighting of the grip force and its derivative, to explore the potential benefits of a more bioinspired stimulation strategy. In all paradigms, the participant's ability to identify the objects was above-chance, with object identification accuracy reaching 80% correct when using only sustained grip force feedback and 76.7% when using equal weighting of both sustained grip force and its derivative. These results demonstrate that bioinspired ICMS can provide sensory feedback that is functionally beneficial in sensorimotor tasks. Designing more efficient stimulation paradigms is important because it will allow us to 1) provide safer stimulation delivery methods that reduce overall injected charge without sacrificing function and 2) more effectively transmit sensory information to promote intuitive integration and usage by the human body.

Published

2021

8. Dynamical Analysis of Seizure in Epileptic Brain: a Dynamic Phase-Amplitude Coupling Estimation Approach

Author

Diana C Ghinda, Yousef Salimpour, Nathan E Crone, Joon Kang, and William S Anderson

Subjects

Epilepsy, Epilepsy, Temporal Lobe, Seizures, Brain, Humans, Electroencephalography

Abstract

Cross-frequency coupling in general and phase-amplitude coupling (PAC) as a particular form of it, provides an opportunity to investigate the complex interactions between neural oscillations in the human brain and neurological disorders such as epilepsy. Using PAC detection methods on temporal sliding windows, we developed a map of dynamic PAC evolution to investigate the spatiotemporal changes occurring during ictal transitions in a patient with intractable mesial temporal lobe epilepsy. The map is built by computing the modulation index between the amplitude of high frequency oscillations and the phase of lower frequency rhythms from the intracranial stereoelectroencephalography recordings during seizure. Our preliminary results show early abnormal PAC changes occurring in the preictal state prior to the occurrence of clinical or visible electrographic seizure onset, and suggest that dynamic PAC measures may serve as a potential clinical technique for analyzing seizure dynamics.Clinical Relevance-Application of a dynamic temporal PAC map as a new tool may provide novel insights into the neurophysiology of epileptic seizure activity and its spatio-temporal dynamics.

Published

2021

9. Source-sink connectivity: A novel interictal EEG marker for seizure localization

Author

Patrick Landazuri, Carol M Ulloa, Jorge Gonzalez-Martinez, Nathaniel Cameron, Iahn Cajigas, Manuel A. Melo Bicchi, Utku Uysal, Niravkumar Barot, Sridevi V. Sarma, Michael Kinsman, Varina L. Boerwinkle, Sara K. Inati, Turki Elarjani, Jonathan R. Jagid, Andres M. Kanner, Joon-Yi Kang, Kareem A. Zaghloul, Jennifer Cheng, Sarah N. Wyckoff, Rachel J. Smith, Nathan E. Crone, Anna Korzeniewska, Adam Li, Kristin M. Gunnarsdottir, and Adam G. Rouse

Subjects

Source sink, medicine.medical_specialty, Epilepsy, business.industry, Audiology, Epileptogenic zone, medicine.disease, Complete resection, Scientific Commentary, Neuroimaging, Seizures, Cortical network, Interictal eeg, Humans, Medicine, Ictal, Electrocorticography, Neurology (clinical), business, Biomarkers, Retrospective Studies

Abstract

Over 15 million epilepsy patients worldwide have drug-resistant epilepsy. Successful surgery is a standard of care treatment but can only be achieved through complete resection or disconnection of the epileptogenic zone, the brain region(s) where seizures originate. Surgical success rates vary between 20% and 80%, because no clinically validated biological markers of the epileptogenic zone exist. Localizing the epileptogenic zone is a costly and time-consuming process, which often requires days to weeks of intracranial EEG (iEEG) monitoring. Clinicians visually inspect iEEG data to identify abnormal activity on individual channels occurring immediately before seizures or spikes that occur interictally (i.e. between seizures). In the end, the clinical standard mainly relies on a small proportion of the iEEG data captured to assist in epileptogenic zone localization (minutes of seizure data versus days of recordings), missing opportunities to leverage these largely ignored interictal data to better diagnose and treat patients. IEEG offers a unique opportunity to observe epileptic cortical network dynamics but waiting for seizures increases patient risks associated with invasive monitoring. In this study, we aimed to leverage interictal iEEG data by developing a new network-based interictal iEEG marker of the epileptogenic zone. We hypothesized that when a patient is not clinically seizing, it is because the epileptogenic zone is inhibited by other regions. We developed an algorithm that identifies two groups of nodes from the interictal iEEG network: those that are continuously inhibiting a set of neighbouring nodes (‘sources’) and the inhibited nodes themselves (‘sinks’). Specifically, patient-specific dynamical network models were estimated from minutes of iEEG and their connectivity properties revealed top sources and sinks in the network, with each node being quantified by source-sink metrics. We validated the algorithm in a retrospective analysis of 65 patients. The source-sink metrics identified epileptogenic regions with 73% accuracy and clinicians agreed with the algorithm in 93% of seizure-free patients. The algorithm was further validated by using the metrics of the annotated epileptogenic zone to predict surgical outcomes. The source-sink metrics predicted outcomes with an accuracy of 79% compared to an accuracy of 43% for clinicians’ predictions (surgical success rate of this dataset). In failed outcomes, we identified brain regions with high metrics that were untreated. When compared with high frequency oscillations, the most commonly proposed interictal iEEG feature for epileptogenic zone localization, source-sink metrics outperformed in predictive power (by a factor of 1.2), suggesting they may be an interictal iEEG fingerprint of the epileptogenic zone.

Published

2021

10. Neural Fragility as an EEG Marker of the Seizure Onset Zone

Author

Angel Claudio, Emily Johnson, Iahn Cajigas, Damian Brusko, Andres M. Kanner, Zachary Fitzgerald, Juan Bulacio, Kareem A. Zaghloul, Adam Li, Stephanie Chen, Jorge Gonzalez-Martinez, Jonathan R. Jagid, Nathan E. Crone, Jennifer Haagensen, Sridevi V. Sarma, William S. Anderson, Jennifer Hopp, Chester Huynh, and Sara K. Inati

Subjects

Adult, Male, Drug Resistant Epilepsy, medicine.medical_specialty, Adolescent, Seizure onset zone, Electroencephalography, Audiology, Brain mapping, Neurosurgical Procedures, Article, Young Adult, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, Fragility, Neuroimaging, Predictive Value of Tests, Seizures, Internal medicine, medicine, Humans, Young adult, Statistic, Retrospective Studies, 030304 developmental biology, Neurons, Brain Mapping, 0303 health sciences, medicine.diagnostic_test, business.industry, General Neuroscience, Retrospective cohort study, Middle Aged, medicine.disease, Intracranial eeg, 3. Good health, Stable system, Treatment Outcome, Predictive value of tests, Cardiology, Biomarker (medicine), Female, business, Neuroscience, Algorithms, Biomarkers, 030217 neurology & neurosurgery

Abstract

Epilepsy is a global epidemic and 30% of the 60 million patients do not respond to medication treatment. The only treatment options for patients with medically refractory epilepsy are surgical removal or electrical stimulation of the epileptogenic zone (EZ) i.e. the source of their seizures. Despite extensive evaluations with neuroimaging, visual EEG analysis and clinical testing, surgical success rates vary between 30-70%. Currently, no computational methods have been translated into the clinic to assist in localizing the EZ. Here, we applied a dynamical network model that quantifies the fragility of nodes within a patient9s intracranial EEG (iEEG) brain network. Fragility is quantified as the minimal amount of perturbation that must to be applied to a node9s influence on a "balanced" network to cause imbalance. Here, a balanced network is one in which the connectivity between excitatory and inhibitory nodes render a stable system, and an imbalanced network is unstable and hence can generate seizures. Using iEEG data from 91 patients treated across 5 epilepsy centers (44 successes, 47 failures), we demonstrated that nodal fragility is greater in electrodes within the EZ. In addition, we compared fragility of iEEG nodes to 7 frequency-based and 14 graph theoretic features of the EZ in both seizure (n=91) and non-seizure data (n=54). We calculated a confidence statistic, defined as the ratio of the value of a given feature averaged across electrodes in the clinically annotated seizure onset zone to its average across all other electrodes. Fragility has a significantly greater effect size difference between surgical outcomes when compared to other features. This novel feature, outperformed the most popular iEEG features when comparing across surgical outcomes, possibly defining a superior network-based EEG fingerprint for the EZ.

Published

2021

11. Increased mirror overflow movements in ADHD are associated with altered EEG alpha/beta band desynchronization

Author

Deana Crocetti, Kathryn Hirabayashi, Yi Zhao, Jack H. Adamek, Yu Luo, Stewart H. Mostofsky, Ajay S. Pillai, Joshua B. Ewen, Danielle McAuliffe, and Nathan E. Crone

Subjects

medicine.medical_specialty, Movement, Alpha (ethology), Audiology, Electroencephalography, Article, 03 medical and health sciences, 0302 clinical medicine, mental disorders, Humans, Medicine, Child, Beta (finance), 030304 developmental biology, 0303 health sciences, medicine.diagnostic_test, business.industry, General Neuroscience, Motor Cortex, Motor control, Cognition, Sensorimotor rhythm, Attention Deficit Disorder with Hyperactivity, Disinhibition, Case-Control Studies, Finger tapping, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Children with ADHD show developmentally abnormal levels of mirror overflow-unintentional movements occurring symmetrically opposite of intentional movements. Because mirror overflow correlates with ADHD behavioral symptoms, the study of disinhibition in motor control may shed light on physiologic mechanisms underlying impaired behavioral/cognitive control. This is a case-controlled study of EEG recording from 25 children with ADHD and 25 typically developing (TD) controls performing unilateral sequential finger tapping, with overflow movements measured using electronic goniometers. Consistent with previously published findings, children with ADHD showed increased mirror overflow as compared with TD peers. EEG findings revealed less lateralized alpha modulation (event-related desynchronization; ERD) and decreased magnitude of beta ERD in ADHD; both alpha and beta ERD reflect cortical activation. Moderation analysis revealed a significant association between beta ERD and overflow, independent of diagnosis; and an equivocal (p = .08) effect of diagnosis on the relationship between alpha ERD and overflow, with a significant effect in children with ADHD but not TD children. These results suggest two mechanisms involved with mirror overflow: one reflected in beta ipsilateral to the intentional movement and relevant to both children with ADHD and controls, and the other seemingly more specific to ADHD (alpha, contralateral to movement).

Published

2019

12. Neuropsychological outcomes after resection of cortical sites with visual naming associated electrocorticographic high-gamma modulation

Author

Douglas F. Rose, Francesco T. Mangano, Hansel M. Greiner, J. Adam Wilson, Ravindra Arya, Leonid Rozhkov, Jason Buroker, Nathan E. Crone, Celie Roth, Katherine D. Holland, James L. Leach, Hisako Fujiwara, Craig Scholle, Anna W. Byars, Denise Middeler, Paul S. Horn, and Jennifer Vannest

Subjects

Male, 0301 basic medicine, Drug Resistant Epilepsy, medicine.medical_specialty, Adolescent, Neuropsychological Tests, Audiology, Young Adult, 03 medical and health sciences, Epilepsy, Postoperative Complications, 0302 clinical medicine, Peabody Picture Vocabulary Test, Humans, Medicine, Epilepsy surgery, Child, Language, Cerebral Cortex, business.industry, Working memory, Neuropsychology, Wechsler Adult Intelligence Scale, Cognition, medicine.disease, Magnetic Resonance Imaging, 030104 developmental biology, Neurology, Female, Neurology (clinical), Cognition Disorders, business, Cortical stimulation mapping, 030217 neurology & neurosurgery, Follow-Up Studies

Abstract

Background Language mapping with high-gamma modulation (HGM) has compared well with electrical cortical stimulation mapping (ESM). However, there is limited prospective data about its functional validity. We compared changes in neuropsychological evaluation (NPE) performed before and 1-year after epilepsy surgery, between patients with/without resection of cortical sites showing HGM during a visual naming task. Methods Pediatric drug-resistant epilepsy (DRE) patients underwent pre-surgical language localization with ESM and HGM using a visual naming task. Surgical decisions were based solely on ESM results. NPE difference scores were compared between patients with/without resection of HGM naming sites using principal component (PC) analysis. Follow-up NPE scores were modeled with resection group as main effect and respective pre-surgical score as a covariate, using analysis of covariance. Results Seventeen native English speakers (12 females), aged 6.5–20.2 years, were included. One year after epilepsy surgery, first PC score increased by (mean ± standard deviation) 14.4 ± 16.5 points in patients without resection, whereas it decreased by 7.6 ± 24.6 points in those with resection of HGM naming sites (p = 0.040). This PC score represented verbal comprehension, working memory, perceptual reasoning (Wechsler subscales); Woodcock-Johnson Tests of Achievement; and Peabody Picture Vocabulary Test. Subsequent analysis showed significant difference in working memory score between patients with/without resection of HGM naming sites (−15.2 points, 95% confidence limits −29.7 to −0.7, p = 0.041). Conclusion We highlight the functional consequences of resecting HGM language sites, and suggest that NPE of DRE patients should include comprehensive assessment of multiple linguistic and cognitive domains besides naming ability.

Published

2019

13. Effects of stimulation intensity on intracranial cortico-cortical evoked potentials: A titration study

Author

Joon Y. Kang, Mark A. Hays, Rachel J. Smith, Christopher Coogan, Nathan E. Crone, and Babitha Haridas

Subjects

Adult, Male, Drug Resistant Epilepsy, Phase (waves), Stimulation, Article, Young Adult, Signal-to-noise ratio, Physiology (medical), Waveform, Medicine, Humans, Evoked Potentials, Cerebral Cortex, Brain Mapping, Titration Study, Pulse (signal processing), business.industry, Middle Aged, Sensory Systems, Electric Stimulation, Intensity (physics), Electrodes, Implanted, Amplitude, Neurology, Female, Neurology (clinical), Electrocorticography, business, Neuroscience

Abstract

Objective The aim of the present study was to investigate the optimal stimulation parameters for eliciting cortico-cortical evoked potentials (CCEPs) for mapping functional and epileptogenic networks. Methods We studied 13 patients with refractory epilepsy undergoing intracranial EEG monitoring. We systematically titrated the intensity of single-pulse electrical stimulation at multiple sites to assess the effect of increasing current on salient features of CCEPs such as N1 potential magnitude, signal to noise ratio, waveform similarity, and spatial distribution of responses. Responses at each incremental stimulation setting were compared to each other and to a final set of responses at the maximum intensity used in each patient (3.5–10 mA, median 6 mA). Results We found that with a biphasic 0.15 ms/phase pulse at least 2–4 mA is needed to differentiate between non-responsive and responsive sites, and that stimulation currents of 6–7 mA are needed to maximize amplitude and spatial distribution of N1 responses and stabilize waveform morphology. Conclusions We determined a minimum stimulation threshold necessary for eliciting CCEPs, as well as a point at which the current-dependent relationship of several response metrics all saturate. Significance This titration study provides practical, immediate guidance on optimal stimulation parameters to study specific features of CCEPs, which have been increasingly used to map both functional and epileptic brain networks in humans.

Published

2021

14. State-space models of evoked potentials to localize the seizure onset zone

Author

Mark A. Hays, Rachel J. Smith, Golnoosh Kamali, Nathan E. Crone, Christopher Coogan, Sridevi V. Sarma, and Joon Y. Kang

Subjects

Drug Resistant Epilepsy, Dynamical systems theory, Computer science, Brain, State vector, Dynamical system, medicine.disease, 01 natural sciences, Surgical planning, 010305 fluids & plasmas, Data set, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, Seizures, 0103 physical sciences, medicine, Animals, Humans, State space, Electrocorticography, Evoked Potentials, Neuroscience, 030217 neurology & neurosurgery

Abstract

Surgical removal of the seizure onset zone (SOZ) in epilepsy patients is a potentially curative treatment, but the process heavily relies on accurate localization of the SOZ via visual inspection. SPES (Single-pulse electrical stimulation) is a method recently used to explore inter-areal connectivity in vivo to probe functional brain networks such as language and motor networks, and to a much lesser degree, seizure networks. We hypothesized that a dynamical quantification of the connectivity networks derived from the evoked responses induced by SPES could also be used to localize the SOZ. To test our hypothesis, we used an intracranial EEG (iEEG) data set in which five epilepsy patients underwent extensive SPES evaluation. For each patient, and for each dataset that stimulated a different pair of electrodes, we constructed a state-space model from the patient's data. Specifically, we simultaneously estimated model parameters under an exogenous pulse input to a dynamical system whose state vector consisted of the response iEEG signals. Then, the size of the reachable state space, as quantified by the maximum singular value of the reachability matrix, σ max (R), was computed and denoted as the "largest" network response possible when stimulating the given pair. Our results suggest high agreement between σ max (R) and clinically annotated SOZ for patients with localizable SOZs.Clinical Relevance— Our study applies dynamical systems theory to identify epileptogenic brain regions, creating a novel tool that clinicians may use in surgical planning for medically-refractory epilepsy patients.

Published

2020

15. Localizing the seizure onset zone from single pulse electrical stimulation responses using transfer function models

Author

Sridevi V. Sarma, Golnoosh Kamali, Rachel J. Smith, Mark A. Hays, Joon Y. Kang, Christopher Coogan, and Nathan E. Crone

Subjects

Drug Resistant Epilepsy, medicine.medical_specialty, Remote patient monitoring, Stimulation, Seizure onset zone, Audiology, 01 natural sciences, 010305 fluids & plasmas, 03 medical and health sciences, Functional brain, Epilepsy, 0302 clinical medicine, Seizures, 0103 physical sciences, Humans, Medicine, Lead (electronics), business.industry, Single pulse, medicine.disease, Electric Stimulation, Electrocorticography, business, Subdural electrodes, 030217 neurology & neurosurgery

Abstract

Surgical resection of the seizure onset zone (SOZ) could potentially lead to seizure-freedom in medically refractory epilepsy patients. However, localizing the SOZ can be a time consuming and tedious process involving visual inspection of intracranial electroencephalographic (iEEG) recordings captured during passive patient monitoring. Single pulse electrical stimulation (SPES) is currently performed on patients undergoing invasive EEG monitoring for the main purposes of mapping functional brain networks such as language and motor networks. We hypothesize that evoked responses from SPES can also be used to localize the SOZ as they may express the natural frequencies and connectivity of the iEEG network. To test our hypothesis, we construct patient specific single-input multi-output transfer function models from the evoked responses recorded from five epilepsy patients that underwent SPES evaluation and iEEG monitoring. Our preliminary results suggest that the stimulation electrodes that produced the highest gain transfer functions, as measured by the ${\mathcal{H}_\infty }$ norm, correspond to those electrodes clinically defined in the SOZ in successfully treated patients.Clinical Relevance- This study creates an innovative tool that allows clinicians to identify the seizure onset zone in medically refractory epilepsy patients using quantitative metrics thereby increasing surgical success outcomes, mitigating patient risks, and decreasing costs.

Published

2020

16. 'Characteristics and stability of sensorimotor activity driven by isolated-muscle group activation in a human with tetraplegia'

Author

Robert W. Nickl, Manuel A. Anaya, Tessy M. Thomas, Matthew S. Fifer, Daniel N. Candrea, David P McMullen, Margaret C. Thompson, Luke E. Osborn, William S. Anderson, Brock A. Wester, Francesco V. Tenore, Nathan E. Crone, Gabriela L. Cantarero, and Pablo A. Celnik

Subjects

Spatial stability, Multidisciplinary, Electromyography, Movement, Sensory system, Biology, Quadriplegia, medicine.disease, Stability (probability), Forearm, Single muscle, medicine, Humans, Body region, Muscle, Skeletal, Muscle group, Neuroscience, Tetraplegia, Brain–computer interface

Abstract

The topography and temporal stability of movement representations in sensorimotor cortex underlie the quality and durability of neural decoders for brain machine interface (BMI) technology. While single- and multi-unit activity (SUA and MUA) in sensorimotor cortex has been used to characterize the layout of the sensorimotor map, quantifying its stability has not been done outside of injury or targeted interventions. Here we aimed to characterize 1) the bilateral sensorimotor body map associated to isolated muscle group contractions and 2) the stability of multiunit firing responses for a single muscle (the extensor carpi radialis, ECR) over short (minutes) and long (days) time intervals. We concurrently recorded surface electromyograms (EMG) and MUA in a participant with incomplete high-spinal-cord injury as he executed (or attempted to execute) different metronome-paced, isolated muscle group contractions. Furthermore, for 8 recording sessions over 2 months, we characterized the sensorimotor map associated to ECR motions both within and across sessions. For each measurement period, we compared the stability of somatotopy (defined by the number of the channels on which a response was consistently detected) and firing pattern stability for each responsive channel. Stability was calculated for each channel in peri-EMG or peri-cue windows using both mean MUA firing rates and the full time-varying responses (i.e., MUA “shape”). First, we found that cortical representations of isolated group muscle contractions overlapped, even for muscles from disparate body regions such as facial and distal leg muscles; this was the case for both intact and de-efferented muscles, in both motor and sensory channels. Second, the spatial stability of somatotopy significantly changed over the course of both minutes and days, with the consistency between sessions decreasing across longer bouts of time. Firing pattern stabilities showed distinct profiles; mean MUA firing rates became less stable over time whereas MUA shape remained consistent. Interestingly, sensory channels were overall more consistent than motor channels in terms of spatial stability, mean MUA firing rates, and MUA shape. Our findings suggest that the encoding of muscle-driven specific activity in sensorimotor cortex at the level of MUA is redundant and widespread with complex spatial and temporal characteristics. These findings extend our understanding of how sensorimotor cortex represents movements, which could be leveraged for the design of non-traditional BMI approaches.

Published

2020

17. Spatiotemporal dynamics of orthographic and lexical processing in the ventral visual pathway

Author

Oscar, Woolnough, Cristian, Donos, Patrick S, Rollo, Kiefer J, Forseth, Yair, Lakretz, Nathan E, Crone, Simon, Fischer-Baum, Stanislas, Dehaene, and Nitin, Tandon

Subjects

Adult, Memory, Long-Term, Psycholinguistics, Time Factors, Electric Stimulation, Temporal Lobe, Young Adult, Pattern Recognition, Visual, Reading, Humans, Visual Pathways, Electrocorticography, Occipital Lobe, Visual Cortex

Abstract

Reading is a rapid, distributed process that engages multiple components of the ventral visual stream. To understand the neural constituents and their interactions that allow us to identify written words, we performed direct intra-cranial recordings in a large cohort of humans. This allowed us to isolate the spatiotemporal dynamics of visual word recognition across the entire left ventral occipitotemporal cortex. We found that mid-fusiform cortex is the first brain region sensitive to lexicality, preceding the traditional visual word form area. The magnitude and duration of its activation are driven by the statistics of natural language. Information regarding lexicality and word frequency propagates posteriorly from this region to visual word form regions and to earlier visual cortex, which, while active earlier, show sensitivity to words later. Further, direct electrical stimulation of this region results in reading arrest, further illustrating its crucial role in reading. This unique sensitivity of mid-fusiform cortex to sub-lexical and lexical characteristics points to its central role as the orthographic lexicon-the long-term memory representations of visual word forms.

Published

2020

18. Subthalamic Nucleus Activity Influences Sensory and Motor Cortex during Force Transduction

Author

Donald J. Crammond, Robert Turner, Efstathios D. Kondylis, Ahmad Alhourani, Witold J. Lipski, Anna Korzeniewska, Thomas A. Wozny, R. Mark Richardson, Nathan E. Crone, and Avniel Singh Ghuman

Subjects

Adult, Male, Deep brain stimulation, Cognitive Neuroscience, medicine.medical_treatment, Deep Brain Stimulation, Sensory system, Context (language use), Somatosensory system, Cellular and Molecular Neuroscience, Subthalamic Nucleus, Medicine, Humans, Electrocorticography, Aged, medicine.diagnostic_test, Hand Strength, business.industry, Motor Cortex, Somatosensory Cortex, Middle Aged, nervous system diseases, Electrodes, Implanted, Subthalamic nucleus, medicine.anatomical_structure, surgical procedures, operative, nervous system, Original Article, Female, business, Neuroscience, Transduction (physiology), therapeutics, Psychomotor Performance, Motor cortex

Abstract

The subthalamic nucleus (STN) is proposed to participate in pausing, or alternately, in dynamic scaling of behavioral responses, roles that have conflicting implications for understanding STN function in the context of deep brain stimulation (DBS) therapy. To examine the nature of event-related STN activity and subthalamic-cortical dynamics, we performed primary motor and somatosensory electrocorticography while subjects (n = 10) performed a grip force task during DBS implantation surgery. Phase-locking analyses demonstrated periods of STN-cortical coherence that bracketed force transduction, in both beta and gamma ranges. Event-related causality measures demonstrated that both STN beta and gamma activity predicted motor cortical beta and gamma activity not only during force generation but also prior to movement onset. These findings are consistent with the idea that the STN participates in motor planning, in addition to the modulation of ongoing movement. We also demonstrated bidirectional information flow between the STN and somatosensory cortex in both beta and gamma range frequencies, suggesting robust STN participation in somatosensory integration. In fact, interactions in beta activity between the STN and somatosensory cortex, and not between STN and motor cortex, predicted PD symptom severity. Thus, the STN contributes to multiple aspects of sensorimotor behavior dynamically across time.

Published

2020

19. Seizure triggers identified postictally using a smart watch reporting system

Author

Anjie, Ge, Erie G, Gutierrez, Seung, Wook Lee, Samyak, Shah, Yaretson, Carmenate, Maxwell, Collard, Nathan E, Crone, and Gregory L, Krauss

Subjects

Behavioral Neuroscience, Epilepsy, Neurology, Seizures, Surveys and Questionnaires, Humans, Female, Neurology (clinical), Sleep, Retrospective Studies

Abstract

Persons with epilepsy (PWE) often report that seizure triggers can influence the occurrence and timing of seizures. Some previous studies of seizure triggers have relied on retrospective daily seizure diaries or surveys pertaining to all past seizures, recent and/or remote, in respondents. To assess the characteristics of seizure triggers at the granularity of individual seizures, we used a seizure-tracking app, called EpiWatch, on a smart watch system (Apple Watch and iPhone) in a national study of PWE. Participants tracked seizures during a 16-month study period using the EpiWatch app. Seizure tracking was initiated during a pre-ictal state or as the seizure was occurring and included collection of biosensor data, responsiveness testing, and completion of an immediate post-seizure survey. The survey evaluated seizure types, auras or warning symptoms, loss of awareness, use of rescue medication, and seizure triggers for each tracked seizure. Two hundred and thirty four participants tracked 2493 seizures. Ninety six participants reported triggers in 650 seizures: stress (65.8%), lack of sleep (30.5%), menstrual cycle (19.7%), and overexertion (18%) were the most common. Participants often reported having multiple combined triggers, frequent stress with lack of sleep, overexertion, or menses. Participants who reported triggers were more likely to be taking 3 or more anti-seizure medications compared to participants who did not report triggers. Participants were able to interact with the app and use mobile technology in this national study to record seizures and report common seizure triggers. These findings demonstrate the promise of longitudinal, self-reported data to improve our understanding of epilepsy and its related comorbidities.

Published

2022

20. Electrocorticographic high-gamma modulation with passive listening paradigm for pediatric extraoperative language mapping

Author

Leonid Rozhkov, Douglas F. Rose, Hansel M. Greiner, Francesco T. Mangano, Hisako Fujiwara, Ravindra Arya, Jason Buroker, Nathan E. Crone, Paul S. Horn, Anna W. Byars, J. Adam Wilson, James L. Leach, Katherine D. Holland, Jennifer Vannest, and Craig Scholle

Subjects

Male, Drug Resistant Epilepsy, medicine.medical_specialty, Adolescent, Audiology, behavioral disciplines and activities, Lateralization of brain function, 030218 nuclear medicine & medical imaging, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Aphasia, Preoperative Care, medicine, Gamma Rhythm, Humans, Epilepsy surgery, Active listening, Prospective Studies, Child, Language, Brain Mapping, Cognition, Neurology, Frontal lobe, Child, Preschool, QUIET, Auditory Perception, Diagnostic odds ratio, Female, Electrocorticography, Neurology (clinical), medicine.symptom, Psychology, 030217 neurology & neurosurgery

Abstract

OBJECTIVE This prospective study compared the topography of high-gamma modulation (HGM) during a story-listening task requiring negligible patient cooperation, with the conventional electrical stimulation mapping (ESM) using a picture-naming task, for presurgical language localization in pediatric drug-resistant epilepsy. METHODS Patients undergoing extraoperative monitoring with subdural electrodes were included. Electrocorticographic signals were recorded during quiet baseline and a story-listening task. The likelihood of 70- to 150-Hz power modulation during the listening task relative to the baseline was estimated for each electrode and plotted on a cortical surface model. Sensitivity, specificity, accuracy, and diagnostic odds ratio (DOR) were estimated compared to ESM, using a meta-analytic framework. RESULTS Nineteen patients (10 with left hemisphere electrodes) aged 4-19 years were analyzed. HGM during story listening was observed in bilateral posterior superior temporal, angular, supramarginal, and inferior frontal gyri, along with anatomically defined language association areas. Compared to either cognitive or both cognitive and orofacial sensorimotor interference with naming during ESM, left hemisphere HGM showed high specificity (0.82-0.84), good accuracy (0.66-0.70), and DOR of 2.23 and 3.24, respectively. HGM was a better classifier of ESM language sites in the left temporoparietal cortex compared to the frontal lobe. Incorporating visual naming with the story-listening task substantially improved the accuracy (0.80) and DOR (13.61) of HGM mapping, while the high specificity (0.85) was retained. In the right hemisphere, no ESM sites for aphasia were seen, and the results of HGM and ESM comparisons were not significant. SIGNIFICANCE HGM associated with story listening is a specific determinant of left hemisphere ESM language sites. It can be used for presurgical language mapping in children who cannot cooperate with conventional language tasks requiring active engagement. Incorporation of additional language tasks, if feasible, can further improve the diagnostic accuracy of language localization with HGM.

Published

2018

21. Cortical Responses to Input From Distant Areas are Modulated by Local Spontaneous Alpha/Beta Oscillations

Author

Kiyohide Usami, Yujing Wang, Griffin Milsap, Anna Korzeniewska, Nathan E. Crone, William S. Anderson, Ronald P. Lesser, and Maxwell Collard

Subjects

Adult, Male, Drug Resistant Epilepsy, Adolescent, Oscillatory power, Cognitive Neuroscience, Alpha (ethology), Stimulation, 050105 experimental psychology, Cortical processing, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Cortex (anatomy), medicine, Humans, 0501 psychology and cognitive sciences, Intracranial electrodes, Beta (finance), Cerebral Cortex, Physics, Extramural, 05 social sciences, Original Articles, Electrodes, Implanted, Alpha Rhythm, medicine.anatomical_structure, Female, Electrocorticography, Beta Rhythm, Neuroscience, 030217 neurology & neurosurgery

Abstract

Any given area in human cortex may receive input from multiple, functionally heterogeneous areas, potentially representing different processing threads. Alpha (8–13 Hz) and beta oscillations (13–20 Hz) have been hypothesized by other investigators to gate local cortical processing, but their influence on cortical responses to input from other cortical areas is unknown. To study this, we measured the effect of local oscillatory power and phase on cortical responses elicited by single-pulse electrical stimulation (SPES) at distant cortical sites, in awake human subjects implanted with intracranial electrodes for epilepsy surgery. In 4 out of 5 subjects, the amplitudes of corticocortical evoked potentials (CCEPs) elicited by distant SPES were reproducibly modulated by the power, but not the phase, of local oscillations in alpha and beta frequencies. Specifically, CCEP amplitudes were higher when average oscillatory power just before distant SPES (−110 to −10 ms) was high. This effect was observed in only a subset (0–33%) of sites with CCEPs and, like the CCEPs themselves, varied with stimulation at different distant sites. Our results suggest that although alpha and beta oscillations may gate local processing, they may also enhance the responsiveness of cortex to input from distant cortical sites.

Published

2018

22. After-discharges and seizures during pediatric extra-operative electrical cortical stimulation functional brain mapping: Incidence, thresholds, and determinants

Author

Jeffrey R. Tenney, Katherine D. Holland, Hansel M. Greiner, Ravindra Arya, Paul S. Horn, Gewalin Aungaroon, Todd Arthur, Anna W. Byars, Francesco T. Mangano, Nathan E. Crone, and Alonso Zea Vera

Subjects

Adult, Male, medicine.medical_specialty, Adolescent, Stimulation, Brain mapping, 030218 nuclear medicine & medical imaging, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Seizures, Physiology (medical), Internal medicine, Preoperative Care, medicine, Humans, Epilepsy surgery, Child, Cerebral Cortex, Tomography, Emission-Computed, Single-Photon, Brain Mapping, medicine.diagnostic_test, Incidence, Incidence (epidemiology), Infant, Odds ratio, Electric Stimulation, Sensory Systems, Electrodes, Implanted, Functional imaging, Neurology, Positron emission tomography, Child, Preschool, Positron-Emission Tomography, Cardiology, Female, Electrocorticography, Neurology (clinical), Psychology, Neuroscience, Cortical stimulation mapping, 030217 neurology & neurosurgery

Abstract

Objective This study examined the incidence, thresholds, and determinants of electrical cortical stimulation (ECS)-induced after-discharges (ADs) and seizures. Methods Electrocorticograph recordings were reviewed to determine incidence of ECS-induced ADs and seizures. Multivariable analyses for predictors of AD/seizure occurrence and their thresholds were performed. Results In 122 patients, the incidence of ADs and seizures was 77% (94/122) and 35% (43/122) respectively. Males (odds ratio [OR] 2.92, 95% CI 1.21–7.38, p = 0.02) and MRI-negative patients (OR 3.69, 95% CI 1.24–13.7, p = 0.03) were found to have higher odds of ECS-induced ADs. A significant trend for decreasing AD thresholds with age was seen (regression co-efficient −0.151, 95% CI −0.267 to −0.035, p = 0.011). ECS-induced seizures were more likely in patients with lateralized functional imaging (OR 6.62, 95% CI 1.36–55.56, p = 0.036, for positron emission tomography) and presence of ADs (OR 3.50, 95% CI 1.12–13.36, p = 0.043). Conclusions ECS is associated with a high incidence of ADs and seizures. With age, current thresholds decrease and the probability for AD/seizure occurrence increases. Significance ADs and seizures during ECS brain mapping are potentially hazardous and affect its functional validity. Thus, safer method(s) for brain mapping with improved neurophysiologic validity are desirable.

Published

2017

23. Brain network dynamics in the human articulatory loop

Author

Goichiro Toyoda, Erik C. Brown, Noa Ofen, Yasuo Nakai, Eishi Asano, Anna Korzeniewska, Masaaki Nishida, and Nathan E. Crone

Subjects

Male, 0301 basic medicine, medicine.medical_specialty, Adolescent, Stimulation, Audiology, behavioral disciplines and activities, Article, 03 medical and health sciences, Tone (musical instrument), 0302 clinical medicine, Gyrus, Physiology (medical), Reaction Time, medicine, Humans, Epilepsy surgery, Child, Prosody, Communication, business.industry, Brain, Neurophysiology, Temporal Lobe, Sensory Systems, Frontal Lobe, Loop (topology), 030104 developmental biology, medicine.anatomical_structure, Acoustic Stimulation, Neurology, Auditory Perception, Female, Electrocorticography, Neurology (clinical), Nerve Net, Articulation (phonetics), Psychology, business, 030217 neurology & neurosurgery

Abstract

Objective The articulatory loop is a fundamental component of language function, involved in the short-term buffer of auditory information followed by its vocal reproduction. We characterized the network dynamics of the human articulatory loop, using invasive recording and stimulation. Methods We measured high-gamma activity 70–110 Hz recorded intracranially when patients with epilepsy either only listened to, or listened to and then reproduced two successive tones by humming. We also conducted network analyses, and analyzed behavioral responses to cortical stimulation. Results Presentation of the initial tone elicited high-gamma augmentation bilaterally in the superior-temporal gyrus (STG) within 40ms, and in the precentral and inferior-frontal gyri (PCG and IFG) within 160ms after sound onset. During presentation of the second tone, high-gamma augmentation was reduced in STG but enhanced in IFG. The task requiring tone reproduction further enhanced high-gamma augmentation in PCG during and after sound presentation. Event-related causality (ERC) analysis revealed dominant flows within STG immediately after sound onset, followed by reciprocal interactions involving PCG and IFG. Measurement of cortico-cortical evoked-potentials (CCEPs) confirmed connectivity between distant high-gamma sites in the articulatory loop. High-frequency stimulation of precentral high-gamma sites in either hemisphere induced speech arrest, inability to control vocalization, or forced vocalization. Vocalization of tones was accompanied by high-gamma augmentation over larger extents of PCG. Conclusions Bilateral PCG rapidly and directly receives feed-forward signals from STG, and may promptly initiate motor planning including sub-vocal rehearsal for short-term buffering of auditory stimuli. Enhanced high-gamma augmentation in IFG during presentation of the second tone may reflect high-order processing of the tone sequence. Significance The articulatory loop employs sustained reciprocal propagation of neural activity across a network of cortical sites with strong neurophysiological connectivity.

Published

2017

24. Semantic attributes are encoded in human electrocorticographic signals during visual object recognition

Author

Mark A. Chevillet, Nathan E. Crone, Matthew J. Roos, Michael Wolmetz, Kyle M. Rupp, Griffin Milsap, Christopher R. Ratto, and Carlos A. Caceres

Subjects

Adult, Male, Drug Resistant Epilepsy, Computer science, Cognitive Neuroscience, Models, Neurological, Semantics, computer.software_genre, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Neuroimaging, medicine, Semantic memory, Encoding (semiotics), Gamma Rhythm, Humans, 0501 psychology and cognitive sciences, Visual Pathways, Electrodes, Brain Mapping, medicine.diagnostic_test, business.industry, 05 social sciences, Cognitive neuroscience of visual object recognition, Pattern recognition, Recognition, Psychology, Magnetic Resonance Imaging, Temporal Lobe, Neurology, Visual Perception, Female, Artificial intelligence, Electrocorticography, Occipital Lobe, business, Functional magnetic resonance imaging, computer, 030217 neurology & neurosurgery, Natural language processing, Algorithms

Abstract

Non-invasive neuroimaging studies have shown that semantic category and attribute information are encoded in neural population activity. Electrocorticography (ECoG) offers several advantages over non-invasive approaches, but the degree to which semantic attribute information is encoded in ECoG responses is not known. We recorded ECoG while patients named objects from 12 semantic categories and then trained high-dimensional encoding models to map semantic attributes to spectral-temporal features of the task-related neural responses. Using these semantic attribute encoding models, untrained objects were decoded with accuracies comparable to whole-brain functional Magnetic Resonance Imaging (fMRI), and we observed that high-gamma activity (70-110Hz) at basal occipitotemporal electrodes was associated with specific semantic dimensions (manmade-animate, canonically large-small, and places-tools). Individual patient results were in close agreement with reports from other imaging modalities on the time course and functional organization of semantic processing along the ventral visual pathway during object recognition. The semantic attribute encoding model approach is critical for decoding objects absent from a training set, as well as for studying complex semantic encodings without artificially restricting stimuli to a small number of semantic categories.

Published

2017

25. The Dynamics of Language Network Interactions in Lexical Selection: An Intracranial EEG Study

Author

Kiyohide Usami, Yujing Wang, Nathan E. Crone, Anna Korzeniewska, and Alyssandra Valenzuela

Subjects

Adult, Male, Speech production, Cognitive Neuroscience, Population, Sentence completion tests, Task (project management), Cellular and Molecular Neuroscience, Selection (linguistics), Reaction Time, Gamma Rhythm, Humans, Speech, Broca's area, education, Language, Temporal cortex, education.field_of_study, Middle Aged, Network dynamics, Broca Area, Temporal Lobe, Female, Original Article, Electrocorticography, Psychology, Photic Stimulation, Cognitive psychology

Abstract

Speaking in sentences requires selection from contextually determined lexical representations. Although posterior temporal cortex (PTC) and Broca’s areas play important roles in storage and selection, respectively, of lexical representations, there has been no direct evidence for physiological interactions between these areas on time scales typical of lexical selection. Using intracranial recordings of cortical population activity indexed by high-gamma power (70–150 Hz) modulations, we studied the causal dynamics of cortical language networks while epilepsy surgery patients performed a sentence completion task in which the number of potential lexical responses was systematically varied. Prior to completion of sentences with more response possibilities, Broca’s area was not only more active, but also exhibited more local network interactions with and greater top-down influences on PTC, consistent with activation of, and competition between, more lexical representations. These findings provide the most direct experimental support yet for network dynamics playing a role in lexical selection among competing alternatives during speech production.

Published

2019

26. Virtual Cortical Stimulation Mapping of Epilepsy Networks to Localize the Epileptogenic Zone

Author

Zachary Fitzgerald, Sridevi V. Sarma, Juan Bulacio, Kareem A. Zaghloul, Jorge Martinez-Gonzalez, Adam Li, Jennifer Hopp, Emily Johnson, Sara K. Inati, and Nathan E. Crone

Subjects

Brain Mapping, Epilepsy, medicine.diagnostic_test, business.industry, 05 social sciences, Electroencephalography, Epileptogenic zone, medicine.disease, Electrode Contact, Brain mapping, 050105 experimental psychology, Stereoelectroencephalography, 03 medical and health sciences, 0302 clinical medicine, Seizures, medicine, Humans, 0501 psychology and cognitive sciences, Electrocorticography, business, Neuroscience, Cortical stimulation mapping, 030217 neurology & neurosurgery

Abstract

Cortical stimulation mapping (CSM) is a common clinical procedure for mapping eloquent cortex in epilepsy patients. Electrical responses to the stimulation, or after-discharges (ADs), that occur in response to stimulation can point to unstable regions of cortex that are more prone to spontaneous seizures. Clinicians are interested in identifying regions that start seizures, i.e., the epileptogenic zone (EZ), so that they can target treatment. However, during CSM, not all regions are stimulated, as it would be time-consuming and potentially harmful to the patient. This limits the clinician's ability to fully explore ADs to reliably localize the EZ. In this paper, we develop a virtual CSM procedure that processes pre-seizure intracranial EEG recordings obtained from epilepsy patients being treated at three different epilepsy centers. First, we identify a linear time varying network (LTVN) model from electrocorticography (ECoG) and stereo-EEG (SEEG) data using sparse least squares estimation for each patient. We then construct an virtual CSM by applying impulse perturbations to each electrode contact in the LTVN model and then measuring the ADs of the network. We summarize the l2-norm of the responses in the form of a heatmap that shows the spatio-temporal evolution of the ADs before, during, and after seizures. Finally we compute an impulse response ratio (IRR) metric from each heatmap, that measures the ratio between the mean norm of ADs of clinically annotated EZ contacts and the mean norm of ADs of the remaining contacts. We find that the IRR is higher in maps derived from patients with successful surgical outcomes and lower in failed surgical outcomes. This suggests that virtual CSM may provide valuable information to clinicians regarding EZ location.

Published

2019

27. The neural tides of sleep and consciousness revealed by single-pulse electrical brain stimulation

Author

Katsuya Kobayashi, Kiyohide Usami, Masao Matsuhashi, Anna Korzeniewska, Takayuki Kikuchi, Takefumi Hitomi, Susumu Miyamoto, Akio Ikeda, Nobuhiro Mikuni, Nathan E. Crone, Ryosuke Takahashi, Kazumichi Yoshida, Takeharu Kunieda, and Riki Matsumoto

Subjects

Adult, Male, Consciousness, brain waves, effective connectivity, Basic Science of Sleep and Circadian Rhythms, Sleep, REM, Sleep, Slow-Wave, 03 medical and health sciences, 0302 clinical medicine, Heart Rate, Physiology (medical), Parietal Lobe, Medicine, Humans, Epilepsy surgery, Wakefulness, Neurons, Sleep Stages, Epilepsy, business.industry, high-gamma activity, causal interactions, Parietal lobe, Electroencephalography, Sleep in non-human animals, Electric Stimulation, Frontal Lobe, 030228 respiratory system, Frontal lobe, Brain stimulation, Neurology (clinical), Electrocorticography, business, human electrocorticography, Neuroscience, 030217 neurology & neurosurgery, Electrical brain stimulation

Abstract

Wakefulness and sleep arise from global changes in brain physiology that may also govern the flow of neural activity between cortical regions responsible for perceptual processing versus planning and action. To test whether and how the sleep/wake cycle affects the overall propagation of neural activity in large-scale brain networks, we applied single-pulse electrical stimulation (SPES) in patients implanted with intracranial EEG electrodes for epilepsy surgery. SPES elicited cortico-cortical spectral responses at high-gamma frequencies (CCSR(HG), 80–150 Hz), which indexes changes in neuronal population firing rates. Using event-related causality (ERC) analysis, we found that the overall patterns of neural propagation among sites with CCSR(HG) were different during wakefulness and different sleep stages. For example, stimulation of frontal lobe elicited greater propagation toward parietal lobe during slow-wave sleep than during wakefulness. During REM sleep, we observed a decrease in propagation within frontal lobe, and an increase in propagation within parietal lobe, elicited by frontal and parietal stimulation, respectively. These biases in the directionality of large-scale cortical network dynamics during REM sleep could potentially account for some of the unique experiential aspects of this sleep stage. Together these findings suggest that the regulation of conscious awareness and sleep is associated with differences in the balance of neural propagation across large-scale frontal-parietal networks.

Published

2019

28. Decoding Native Cortical Representations for Flexion and Extension at Upper Limb Joints Using Electrocorticography

Author

William S. Anderson, Tessy M. Thomas, David P. McMullen, Nathan E. Crone, Nitish V. Thakor, Daniel N. Candrea, and Matthew S. Fifer

Subjects

Adult, Male, Wrist Joint, medicine.medical_specialty, Adolescent, Computer science, Elbow, Biomedical Engineering, Wrist, Article, Fingers, Machine Learning, Upper Extremity, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Physical medicine and rehabilitation, Elbow Joint, Internal Medicine, medicine, Humans, Electrocorticography, 030304 developmental biology, Brain–computer interface, Cued speech, 0303 health sciences, medicine.diagnostic_test, General Neuroscience, Rehabilitation, Extension (predicate logic), medicine.anatomical_structure, Brain-Computer Interfaces, Linear Models, Upper limb, Feasibility Studies, Female, Joints, Sensorimotor Cortex, 030217 neurology & neurosurgery, Decoding methods, Photic Stimulation

Abstract

Brain–machine interface (BMI) researchers have traditionally focused on modeling endpoint reaching tasks to provide the control of neurally driven prosthetic arms. Most previous research has focused on achieving an endpoint control through a Cartesian-coordinate-centered approach. However, a joint-centered approach could potentially be used to intuitively control a wide range of limb movements. We systematically investigated the feasibility of discriminating between flexion and extension of different upper limb joints using electrocorticography(ECoG) recordings from sensorimotor cortex. Four subjects implanted with macro-ECoG (10-mm spacing), high-density ECoG (5-mm spacing), and/or micro-ECoG arrays (0.9-mm spacing and 4 mm $\times $ 4 mm coverage), performed randomly cued flexions or extensions of the fingers, wrist, or elbow contralateral to the implanted hemisphere. We trained a linear model to classify six movements using averaged high-gamma power (70–110 Hz) modulations at different latencies with respect to movement onset, and within a time interval restricted to flexion or extension at each joint. Offline decoding models for each subject classified these movements with accuracies of 62%–83%. Our results suggest that the widespread ECoG coverage of sensorimotor cortex could allow a whole limb BMI to sample native cortical representations in order to control flexion and extension at multiple joints.

Published

2019

29. The Potential for a Speech Brain-Computer Interface Using Chronic Electrocorticography

Author

Nathan E. Crone, Qinwan Rabbani, and Griffin Milsap

Subjects

0301 basic medicine, Computer science, Imagined speech, Interface (computing), Speech recognition, Population, Feature extraction, Review, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, Speech, Pharmacology (medical), education, Electrocorticography, Brain–computer interface, Pharmacology, Neural correlates of consciousness, education.field_of_study, Modalities, medicine.diagnostic_test, 030104 developmental biology, Brain-Computer Interfaces, Neurology (clinical), 030217 neurology & neurosurgery

Abstract

A brain–computer interface (BCI) is a technology that uses neural features to restore or augment the capabilities of its user. A BCI for speech would enable communication in real time via neural correlates of attempted or imagined speech. Such a technology would potentially restore communication and improve quality of life for locked-in patients and other patients with severe communication disorders. There have been many recent developments in neural decoders, neural feature extraction, and brain recording modalities facilitating BCI for the control of prosthetics and in automatic speech recognition (ASR). Indeed, ASR and related fields have developed significantly over the past years, and many lend many insights into the requirements, goals, and strategies for speech BCI. Neural speech decoding is a comparatively new field but has shown much promise with recent studies demonstrating semantic, auditory, and articulatory decoding using electrocorticography (ECoG) and other neural recording modalities. Because the neural representations for speech and language are widely distributed over cortical regions spanning the frontal, parietal, and temporal lobes, the mesoscopic scale of population activity captured by ECoG surface electrode arrays may have distinct advantages for speech BCI, in contrast to the advantages of microelectrode arrays for upper-limb BCI. Nevertheless, there remain many challenges for the translation of speech BCIs to clinical populations. This review discusses and outlines the current state-of-the-art for speech BCI and explores what a speech BCI using chronic ECoG might entail. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (10.1007/s13311-018-00692-2) contains supplementary material, which is available to authorized users.

Published

2019

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

Author

Nathan E. Crone, Julia W. Y. Kam, Josef Parvizi, Robert T. Knight, Jack J. Lin, Kurtis I. Auguste, Rachel Kuperman, Sara M. Szczepanski, Adeen Flinker, Ryan T. Canolty, and Heidi E. Kirsch

Subjects

Adult, Male, 0301 basic medicine, Signal Detection, Psychological, Adolescent, Cognitive Neuroscience, Posterior parietal cortex, Neuropsychological Tests, Electroencephalography, Biology, Young Adult, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Neuroimaging, Cortex (anatomy), P3b, medicine, Humans, Attention, Evoked Potentials, Electrocorticography, Epilepsy, medicine.diagnostic_test, Brain, Original Articles, Middle Aged, Electrophysiology, 030104 developmental biology, medicine.anatomical_structure, Scalp, Auditory Perception, Visual Perception, Female, Neuroscience, 030217 neurology & neurosurgery

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

2016

31. Cortical subnetwork dynamics during human language tasks

Author

Yujing Wang, Matthew S. Fifer, Griffin Milsap, Nathan E. Crone, Maxwell Collard, Heather L. Benz, Anna Korzeniewska, and David P. McMullen

Subjects

Male, Elementary cognitive task, Nerve net, Computer science, Cognitive Neuroscience, Speech recognition, Models, Neurological, Population, Article, 050105 experimental psychology, Visual processing, Young Adult, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, Speech, Computer Simulation, 0501 psychology and cognitive sciences, education, Subnetwork, Electrocorticography, Dynamic Bayesian network, Language, Cerebral Cortex, Brain Mapping, education.field_of_study, medicine.diagnostic_test, Functional connectivity, 05 social sciences, Speech processing, Task (computing), medicine.anatomical_structure, Reading, Neurology, Cerebral cortex, Female, Nerve Net, 030217 neurology & neurosurgery

Abstract

Language tasks require the coordinated activation of multiple subnetworks—groups of related cortical interactions involved in specific components of task processing. Although electrocorticography (ECoG) has sufficient temporal and spatial resolution to capture the dynamics of event-related interactions between cortical sites, it is difficult to decompose these complex spatiotemporal patterns into functionally discrete subnetworks without explicit knowledge of each subnetwork’s timing. We hypothesized that subnetworks corresponding to distinct components of task-related processing could be identified as groups of interactions with co-varying strengths. In this study, five subjects implanted with ECoG grids over language areas performed word repetition and picture naming. We estimated the interaction strength between each pair of electrodes during each task using a time-varying dynamic Bayesian network (tvDBN) model constructed from the power of high gamma (70–110 Hz) activity, a surrogate for population firing rates. We then reduced the dimensionality of this model using principal component analysis (PCA) to identify groups of interactions with co-varying strengths, which we term functional network components (FNCs). This data-driven technique estimates both the weight of each interaction’s contribution to a particular subnetwork, and the temporal profile of each subnetwork’s activation during the task. We found FNCs with temporal and anatomical features consistent with articulatory preparation in both tasks, and with auditory and visual processing in the word repetition and picture naming tasks, respectively. These FNCs were highly consistent between subjects with similar electrode placement, and were robust enough to be characterized in single trials. Furthermore, the interaction patterns uncovered by FNC analysis correlated well with recent literature suggesting important functional-anatomical distinctions between processing external and self-produced speech. Our results demonstrate that subnetwork decomposition of event-related cortical interactions is a powerful paradigm for interpreting the rich dynamics of large-scale, distributed cortical networks during human cognitive tasks.

Published

2016

32. Antiepileptic drug withdrawal and seizure severity in the epilepsy monitoring unit

Author

Nathan E. Crone, Phan Q. Duy, Gregory L. Krauss, Molly Ma, and Emily Johnson

Subjects

Adult, Male, Adolescent, Dose, Electroencephalography, Severity of Illness Index, Young Adult, 03 medical and health sciences, Behavioral Neuroscience, Epilepsy, 0302 clinical medicine, Seizures, medicine, Humans, Epilepsy surgery, 030212 general & internal medicine, Child, Aged, Monitoring, Physiologic, Retrospective Studies, medicine.diagnostic_test, Seizure types, business.industry, Lorazepam, Middle Aged, medicine.disease, Effective dose (pharmacology), Substance Withdrawal Syndrome, Hospitalization, Neurology, Anesthesia, Epilepsy monitoring, Anticonvulsants, Female, Neurology (clinical), business, Hospital Units, 030217 neurology & neurosurgery, medicine.drug

Abstract

The goal of this study was to identify a strategy for antiepileptic drug (AED) reduction to allow efficient recording of focal seizures (FS) in patients undergoing video-electroencephalography (EEG) in an epilepsy monitoring unit (EMU) while avoiding the risk of complications associated with more severe seizure types.We retrospectively reviewed consecutive patients admitted to our institution's EMU from July 1, 2016 to December 31, 2017. We included 114 presurgical patients who had AEDs reduced and at least one seizure during the admission. We compared AED dosages at which FS versus focal to bilateral tonic-clonic seizures (f-BTCS), seizure clusters, and lorazepam administration occurred. We also examined rate of AED reduction and seizure types. We used a receiver-operating characteristic (ROC) curve to identify a dose maximizing FS and minimizing other seizure types.Antiepileptic drug withdrawal rates ranged from 0 to 100% in the first 24 h (mean: 20%, standard deviation: 20%). Focal to bilateral tonic-clonic seizures and lorazepam administration occurred at a lower median AED dose than did FS (0%, 7.2%, and 43.8%, respectively, expressed as a percentage of the patient's outpatient daily AED dose; p 0.001). A daily EMU-administered dose of one-third of the patient's outpatient AED dose allowed 55.0% of FS to occur while avoiding 82.0% of more severe seizure types. The seizure types had no difference in rate of AED withdrawal in the first 24 h of EMU stay.Focal seizures occurred at a higher AED dose than did f-BTCS. This may imply that a low minimally effective dose of AED could allow FS to be recorded while providing protection against f-BTCS. This strategy could improve efficacy and safety in the EMU.

Published

2020

33. Changes in human brain dynamics during behavioral priming and repetition suppression

Author

Stephen J. Gotts, Alex Martin, Griffin Milsap, Anna Korzeniewska, Nathan E. Crone, Mackenzie C. Cervenka, Heather L. Benz, Max Collard, Yujing Wang, and Matthew S. Fifer

Subjects

Adult, 0301 basic medicine, media_common.quotation_subject, Stimulus (physiology), Article, Perceptual stimulus, 03 medical and health sciences, 0302 clinical medicine, Perception, Repetition Priming, Reaction Time, medicine, Humans, Speech, Evoked Potentials, Electrocorticography, media_common, Cerebral Cortex, Predictive coding, Epilepsy, medicine.diagnostic_test, Functional Neuroimaging, General Neuroscience, Human brain, Neurophysiology, Brain Waves, Implicit learning, 030104 developmental biology, medicine.anatomical_structure, Pattern Recognition, Visual, Nerve Net, Psychology, Neuroscience, Psychomotor Performance, 030217 neurology & neurosurgery

Abstract

Behavioral responses to a perceptual stimulus are typically faster with repeated exposure to the stimulus (behavioral priming). This implicit learning mechanism is critical for survival but impaired in a variety of neurological disorders, including Alzheimer's disease. Many studies of the neural bases for behavioral priming have encountered an interesting paradox: in spite of faster behavioral responses, repeated stimuli usually elicit weaker neural responses (repetition suppression). Several neurophysiological models have been proposed to resolve this paradox, but noninvasive techniques for human studies have had insufficient spatial-temporal precision for testing their predictions. Here, we used the unparalleled precision of electrocorticography (ECoG) to analyze the timing and magnitude of task-related changes in neural activation and propagation while patients named novel vs repeated visual objects. Stimulus repetition was associated with faster verbal responses and decreased neural activation (repetition suppression) in ventral occipito-temporal cortex (VOTC) and left prefrontal cortex (LPFC). Interestingly, we also observed increased neural activation (repetition enhancement) in LPFC and other recording sites. Moreover, with analysis of high gamma propagation we observed increased top-down propagation from LPFC into VOTC, preceding repetition suppression. The latter results indicate that repetition suppression and behavioral priming are associated with strengthening of top-down network influences on perceptual processing, consistent with predictive coding models of repetition suppression, and they support a central role for changes in large-scale cortical dynamics in achieving more efficient and rapid behavioral responses.

Published

2020

34. Oscillatory dynamics coordinating human frontal networks in support of goal maintenance

Author

David Fegen, Josef Parvizi, Andrew S. Kayser, Bradley Voytek, Mark D'Esposito, Robert T. Knight, Nathan E. Crone, David Badre, and Edward F. Chang

Subjects

Adult, Male, Electroencephalography, Article, Neuroimaging, Gamma Rhythm, Reaction Time, medicine, Humans, Theta Rhythm, Prefrontal cortex, Electrocorticography, medicine.diagnostic_test, General Neuroscience, Neuropsychology, Cognition, Electrodes, Implanted, Frontal Lobe, Frontal lobe, Female, Psychology, Goals, Neuroscience, Photic Stimulation

Abstract

Humans have a capacity for hierarchical cognitive control—the ability to simultaneously control immediate actions while holding more abstract goals in mind. Neuropsychological and neuroimaging evidence suggests that hierarchical cognitive control emerges from a frontal architecture whereby prefrontal cortex coordinates neural activity in the motor cortices when abstract rules are needed to govern motor outcomes. Here we utilize the improved temporal resolution of human intracranial electrocorticography to investigate the mechanisms by which frontal cortical oscillatory networks communicate in support of hierarchical cognitive control. Responding according to progressively more abstract rules results in greater frontal network theta phase encoding (4-8 Hz) and increased prefrontal local neuronal population activity (high gamma amplitude, 80-150 Hz), which predicts trial-by-trial response times. Theta phase encoding couples with high gamma amplitude during interregional information encoding, suggesting that interregional phase encoding is a mechanism for the dynamic instantiation of complex cognitive functions by frontal cortical subnetworks.

Published

2015

35. Dynamics of functional and effective connectivity within human cortical motor control networks

Author

Stewart H. Mostofsky, Mark Hallett, Joshua B. Ewen, Nathan E. Crone, Balaji M. Lakshmanan, and Anna Korzeniewska

Subjects

Adult, Male, genetic structures, Electroencephalography, Article, Parietal Lobe, Physiology (medical), Connectome, medicine, Humans, Motor skill, Gestures, medicine.diagnostic_test, Motor Cortex, Parietal lobe, Efference copy, Motor control, Sensory Systems, medicine.anatomical_structure, Neurology, Motor Skills, Female, Neurology (clinical), Psychology, Neuroscience, Motor cortex, Cognitive psychology, Gesture

Abstract

Praxis, the performance of complex motor gestures, is crucial to the development of motor and social/communicative capacities. Praxis relies on a network consisting of inferior parietal and premotor regions, particularly on the left, and is thought to require transformation of spatio-temporal representations (parietal) into movement sequences (premotor).We examined praxis network dynamics by measuring EEG effective connectivity while healthy subjects performed a praxis task.Propagation from parietal to frontal regions was not statistically greater on the left than the right. However, propagation from left parietal regions to all other regions was significantly greater during gesture preparation than execution. Moreover, during gesture preparation only, propagation from the left parietal region to bilateral frontal regions was greater than reciprocal propagations to the left parietal region. This directional specificity was not observed for the right parietal region.These findings represent direct electrophysiological evidence for directionally predominant propagation in left frontal-parietal networks during praxis behavior, which may reflect neural mechanisms by which representations in the human brain select appropriate motor sequences for subsequent execution.In addition to bolstering the classic view of praxis network function, these results also demonstrate the relevance of additional information provided by directed connectivity measures.

Published

2015

36. Electrocorticographic language mapping in children by high-gamma synchronization during spontaneous conversation: Comparison with conventional electrical cortical stimulation

Author

Francesco T. Mangano, Hansel M. Greiner, Hisako Fujiwara, Douglas F. Rose, Anna W. Byars, Nathan E. Crone, Ravindra Arya, Jennifer Vannest, J. Adam Wilson, Katherine D. Holland, Paul S. Horn, and Jason Buroker

Subjects

Male, medicine.medical_specialty, Speech perception, Adolescent, Ecological validity, media_common.quotation_subject, Models, Neurological, Audiology, Electroencephalography, Sensitivity and Specificity, Brain mapping, Lateralization of brain function, Positive predicative value, Preoperative Care, medicine, Gamma Rhythm, Humans, Speech, Interpersonal Relations, Conversation, Child, Language, media_common, Cerebral Cortex, Cued speech, Brain Mapping, Epilepsy, medicine.diagnostic_test, Electric Stimulation, Neurology, Child, Preschool, Speech Perception, Feasibility Studies, Female, Neurology (clinical), Psychology, Neuroscience

Abstract

Summary Introduction This study describes development of a novel language mapping approach using high-γ modulation in electrocorticograph (ECoG) during spontaneous conversation, and its comparison with electrical cortical stimulation (ECS) in childhood-onset drug-resistant epilepsy. Methods Patients undergoing invasive pre-surgical monitoring and able to converse with the investigator were eligible. ECoG signals and synchronized audio were acquired during quiet baseline and during natural conversation between investigator and the patient. Using Signal Modeling for Real-time Identification and Event Detection (SIGFRIED) procedure, a statistical model for baseline high-γ (70–116 Hz) power, and a single score for each channel representing the probability that the power features in the experimental signal window belonged to the baseline model, were calculated. Electrodes with significant high-γ responses (HGS) were plotted on the 3D cortical model. Sensitivity, specificity, positive and negative predictive values (PPV, NPV), and classification accuracy were calculated compared to ECS. Results Seven patients were included (4 males, mean age 10.28 ± 4.07 years). Significant high-γ responses were observed in classic language areas in the left hemisphere plus in some homologous right hemispheric areas. Compared with clinical standard ECS mapping, the sensitivity and specificity of HGS mapping was 88.89% and 63.64%, respectively, and PPV and NPV were 35.29% and 96.25%, with an overall accuracy of 68.24%. HGS mapping was able to correctly determine all ECS+ sites in 6 of 7 patients and all false—sites (ECS+, HGS− for visual naming, n = 3) were attributable to only 1 patient. Conclusions This study supports the feasibility of language mapping with ECoG HGS during spontaneous conversation, and its accuracy compared to traditional ECS. Given long-standing concerns about ecological validity of ECS mapping of cued language tasks, and difficulties encountered with its use in children, ECoG mapping of spontaneous language may provide a valid alternative for clinical use.

Published

2015

37. Bottom-of-sulcus focal cortical dysplasia presenting as epilepsia partialis continua multimodality characterization including 7T MRI

Author

Sarah A. Kelley, Nathan E. Crone, Bruno P. Soares, and Shenandoah Robinson

Subjects

Male, medicine.medical_specialty, Adolescent, Epilepsia partialis continua, Epilepsia Partialis Continua, Neuroimaging, Multimodal Imaging, 030218 nuclear medicine & medical imaging, Lesion, 03 medical and health sciences, Epilepsy, 0302 clinical medicine, medicine, Humans, business.industry, General Medicine, Cortical dysplasia, Sulcus, medicine.disease, Magnetic Resonance Imaging, Malformations of Cortical Development, medicine.anatomical_structure, Epilepsy in children, Positron-Emission Tomography, Pediatrics, Perinatology and Child Health, Refractory epilepsy, Neurology (clinical), Neurosurgery, Radiology, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Bottom-of-sulcus focal cortical dysplasias are an under recognized, surgically treatable cause of focal epilepsy. Resection can dramatically reduce the seizure burden for children with refractory epilepsy, or eliminate seizures altogether. We report the case and present the results of multimodality evaluation of a 15-year-old young man who presented with long-standing partial epilepsy affecting his right leg, which over the years became refractory to therapy. High-resolution 3T MRI images acquired as a dedicated epilepsyprotocol were initially interpreted as unremarkable. On further review by an experienced specialist aware of clinical and electroencephalographic findings, a subtle focal cortical dysplasia was identified at the bottom of a sulcus near the medial aspect of the left precentral gyrus. After confirmation of the extent of the lesion with PET and ultra-high field 7T MRI, the patient underwent cortical mapping and focal resection and remains free of seizures. This case emphasizes the need for a multidisciplinary approach to the evaluation of refractory focal epilepsy in children and highlights the potential role of ultra-high field 7T MRI in identifying the often subtle causative anatomic abnormalities.

Published

2017

38. Strategies for non-EEG seizure detection and timing for alerting and interventions with tonic-clonic seizures

Author

Nathan E. Crone, Gregory L. Krauss, Yaretson I. Carmenate, Erie G. Gutierrez, and Joon Y. Kang

Subjects

0301 basic medicine, medicine.medical_specialty, Time Factors, Psychological intervention, Electroencephalography, Unexpected death, 03 medical and health sciences, Epilepsy, Death, Sudden, 0302 clinical medicine, Physical medicine and rehabilitation, Heart Rate, Seizures, Heart rate, Accelerometry, medicine, Humans, medicine.diagnostic_test, business.industry, Respiratory dysfunction, Galvanic Skin Response, medicine.disease, Respiration Disorders, Circadian Rhythm, 030104 developmental biology, Neurology, Seizure detection, Tonic-clonic seizures, Neurology (clinical), business, 030217 neurology & neurosurgery

Abstract

Sudden unexpected death in epilepsy (SUDEP) is a common cause of death in epilepsy and frequently occurs following generalized tonic-clonic seizures (GTCS). Non-electroencephalography (EEG) seizure detection systems using mobile sensor devices permit caregivers to assist patients during seizures and may reduce risks for complications of seizures such as injuries and SUDEP. We review changes in accelerometry, electrodermal activity, and heart rate associated with tonic-clonic seizures and their use in detection systems, including multimodal detectors. We reviewed current and past publications reporting data on linkage between GTCS, post-ictal generalized EEG suppression (PGES), and ventilatory dysfunction. The timing and duration of postictal immobility and respiratory dysfunction associated with convulsions help identify which patients might benefit the most from seizure monitoring and from benchmarks for the timing of seizure detection, caregiver alerting, and interventions.

Published

2017

39. Spatiotemporal dynamics of word retrieval in speech production revealed by cortical high-frequency band activity

Author

Gerwin Schalk, Peter Brunner, Peter B. Weber, Josef Parvizi, Rummit K Dhillon, Nina F. Dronkers, David King-Stephens, Kenneth D. Laxer, Robert T. Knight, Jack J. Lin, Nathan E. Crone, Alex Clarke, Kurtis I. Auguste, Rachel Kuperman, and Stephanie K. Riès

Subjects

Adult, Male, Speech production, Computer science, Speech recognition, Semantics, computer.software_genre, 050105 experimental psychology, Temporal lobe, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Speech Production Measurement, Inferior temporal gyrus, Humans, Speech, 0501 psychology and cognitive sciences, Language, Multidisciplinary, Language production, business.industry, 05 social sciences, Temporal Lobe, Electrophysiological Phenomena, Frontal Lobe, Frontal lobe, PNAS Plus, Female, Artificial intelligence, Electrocorticography, business, computer, 030217 neurology & neurosurgery, Word (computer architecture), Natural language processing, Photic Stimulation

Abstract

Word retrieval is core to language production and relies on complementary processes: the rapid activation of lexical and conceptual representations and word selection, which chooses the correct word among semantically related competitors. Lexical and conceptual activation is measured by semantic priming. In contrast, word selection is indexed by semantic interference and is hampered in semantically homogeneous (HOM) contexts. We examined the spatiotemporal dynamics of these complementary processes in a picture naming task with blocks of semantically heterogeneous (HET) or HOM stimuli. We used electrocorticography data obtained from frontal and temporal cortices, permitting detailed spatiotemporal analysis of word retrieval processes. A semantic interference effect was observed with naming latencies longer in HOM versus HET blocks. Cortical response strength as indexed by high-frequency band (HFB) activity (70–150 Hz) amplitude revealed effects linked to lexical-semantic activation and word selection observed in widespread regions of the cortical mantle. Depending on the subsecond timing and cortical region, HFB indexed semantic interference (i.e., more activity in HOM than HET blocks) or semantic priming effects (i.e., more activity in HET than HOM blocks). These effects overlapped in time and space in the left posterior inferior temporal gyrus and the left prefrontal cortex. The data do not support a modular view of word retrieval in speech production but rather support substantial overlap of lexical-semantic activation and word selection mechanisms in the brain.

Published

2017

40. Language and motor function thresholds during pediatric extra-operative electrical cortical stimulation brain mapping

Author

Anna W. Byars, Alonso Zea Vera, Hansel M. Greiner, Jeffrey R. Tenney, Paul S. Horn, Gewalin Aungaroon, Nathan E. Crone, Francesco T. Mangano, Todd Arthur, Katherine D. Holland, and Ravindra Arya

Subjects

Adult, Male, medicine.medical_specialty, Clinical variables, Adolescent, Stimulation, Audiology, Brain mapping, Motor function, 050105 experimental psychology, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Physiology (medical), Preoperative Care, medicine, Humans, Speech, 0501 psychology and cognitive sciences, Epilepsy surgery, Child, Language, Motor threshold, Cerebral Cortex, Brain Mapping, 05 social sciences, Infant, Sensory Systems, Electric Stimulation, Neurology, Motor Skills, Anesthesia, Child, Preschool, Sensory Thresholds, Female, Neurology (clinical), Electrocorticography, Motor mapping, Psychology, 030217 neurology & neurosurgery

Abstract

Objective To examine current thresholds and their determinants for language and motor mapping with extra-operative electrical cortical stimulation (ECS). Methods ECS electrocorticograph recordings were reviewed to determine functional thresholds. Predictors of functional thresholds were found with multivariable analyses. Results In 122 patients (age 11.9 ± 5.4 years), average minimum, frontal, and temporal language thresholds were 7.4 (± 3.0), 7.8 (± 3.0), and 7.4 (± 3.1) mA respectively. Average minimum, face, upper and lower extremity motor thresholds were 5.4 (± 2.8), 6.1 (± 2.8), 4.9 (± 2.3), and 5.3 (± 3.3) mA respectively. Functional and after-discharge (AD)/seizure thresholds were significantly related. Minimum, frontal, and temporal language thresholds were higher than AD thresholds at all ages. Minimum motor threshold was higher than minimum AD threshold up to 8.0 years of age, face motor threshold was higher than frontal AD threshold up to 11.8 years age, and lower subsequently. UE motor thresholds remained below frontal AD thresholds throughout the age range. Conclusions Functional thresholds are frequently above AD thresholds in younger children. Significance These findings raise concerns about safety and neurophysiologic validity of ECS mapping. Functional and AD/seizure thresholds relationships suggest individual differences in cortical excitability which cannot be explained by clinical variables.

Published

2017

41. Pre-surgical Language Localization with Visual Naming associated ECoG High-gamma Modulation in Pediatric Drug-resistant Epilepsy

Author

Brian Ervin, Douglas F. Rose, Paul S. Horn, Jason Buroker, Hisako Fujiwara, J. Adam Wilson, Ravindra Arya, Francesco T. Mangano, Anna W. Byars, Hansel M. Greiner, Ali A. Minai, Nathan E. Crone, James L. Leach, Jennifer Vannest, Leonid Rozhkov, Katherine D. Holland, and Griffin Milsap

Subjects

Male, medicine.medical_specialty, Drug Resistant Epilepsy, Tomography Scanners, X-Ray Computed, Adolescent, Audiology, Electroencephalography, Brain mapping, 050105 experimental psychology, Lateralization of brain function, Article, Functional Laterality, 03 medical and health sciences, Epilepsy, Young Adult, 0302 clinical medicine, Imaging, Three-Dimensional, Gyrus, medicine, Gamma Rhythm, Humans, Names, 0501 psychology and cognitive sciences, Epilepsy surgery, Child, Electrocorticography, Language, Brain Mapping, medicine.diagnostic_test, business.industry, 05 social sciences, Brain, medicine.disease, Magnetic Resonance Imaging, Electric Stimulation, Electrodes, Implanted, medicine.anatomical_structure, Neurology, Child, Preschool, Female, Neurology (clinical), business, Neuroscience, 030217 neurology & neurosurgery, Photic Stimulation, Motor cortex

Abstract

SummaryObjective This prospective study compared presurgical language localization with visual naming–associated high-γ modulation (HGM) and conventional electrical cortical stimulation (ECS) in children with intracranial electrodes. Methods Patients with drug-resistant epilepsy who were undergoing intracranial monitoring were included if able to name pictures. Electrocorticography (ECoG) signals were recorded during picture naming (overt and covert) and quiet baseline. For each electrode the likelihood of high-γ (70–116 Hz) power modulation during naming task relative to the baseline was estimated. Electrodes with significant HGM were plotted on a three-dimensional (3D) cortical surface model. Sensitivity, specificity, and accuracy were calculated compared to clinical ECS. Results Seventeen patients with mean age of 11.3 years (range 4–19) were included. In patients with left hemisphere electrodes (n = 10), HGM during overt naming showed high specificity (0.81, 95% confidence interval [CI] 0.78–0.85), and accuracy (0.71, 95% CI 0.66–0.75, p

Published

2017

42. Demonstration of a Semi-Autonomous Hybrid Brain–Machine Interface Using Human Intracranial EEG, Eye Tracking, and Computer Vision to Control a Robotic Upper Limb Prosthetic

Author

Guy Hotson, Brock A. Wester, William S. Anderson, Matthew S. Fifer, Nitish V. Thakor, Matthew S. Johannes, Nathan E. Crone, Alan Ravitz, Timothy G. McGee, Kapil D. Katyal, Andrew L. Harris, David P. McMullen, and R. Jacob Vogelstein

Subjects

Adult, Male, Eye Movements, Computer science, Biomedical Engineering, Artificial Limbs, Pilot Projects, Prosthesis Design, Article, Task (project management), Supervisory control, Artificial Intelligence, Internal Medicine, Humans, Computer vision, Man-Machine Systems, Simulation, Brain–computer interface, business.industry, General Neuroscience, Rehabilitation, Eye movement, Electroencephalography, Robotics, Object (computer science), Equipment Failure Analysis, Brain-Computer Interfaces, Therapy, Computer-Assisted, Eye tracking, Female, Augmented reality, Artificial intelligence, business

Abstract

To increase the ability of brain-machine interfaces (BMIs) to control advanced prostheses such as the modular prosthetic limb (MPL), we are developing a novel system: the Hybrid Augmented Reality Multimodal Operation Neural Integration Environment (HARMONIE). This system utilizes hybrid input, supervisory control, and intelligent robotics to allow users to identify an object (via eye tracking and computer vision) and initiate (via brain-control) a semi-autonomous reach-grasp-and-drop of the object by the MPL. Sequential iterations of HARMONIE were tested in two pilot subjects implanted with electrocorticographic (ECoG) and depth electrodes within motor areas. The subjects performed the complex task in 71.4% (20/28) and 67.7% (21/31) of trials after minimal training. Balanced accuracy for detecting movements was 91.1% and 92.9%, significantly greater than chance accuracies (p < 0.05). After BMI-based initiation, the MPL completed the entire task 100% (one object) and 70% (three objects) of the time. The MPL took approximately 12.2 seconds for task completion after system improvements implemented for the second subject. Our hybrid-BMI design prevented all but one baseline false positive from initiating the system. The novel approach demonstrated in this proof-of-principle study, using hybrid input, supervisory control, and intelligent robotics, addresses limitations of current BMIs.

Published

2014

43. EEG analysis reveals widespread directed functional interactions related to a painful cutaneous laser stimulus

Author

Frederick A. Lenz, Jui-Hong Chien, C.C. Liu, Nathan E. Crone, Jicong Zhang, and Timothy M. Markman

Subjects

Adult, Male, Physiology, Nerve net, Pain, Stimulus (physiology), Electroencephalography, behavioral disciplines and activities, Brain mapping, Young Adult, Epilepsy, Salience (neuroscience), Physical Stimulation, Distraction, Psychophysics, medicine, Humans, Attention, Brain Mapping, medicine.diagnostic_test, Lasers, General Neuroscience, Brain, Articles, Middle Aged, medicine.disease, Electric Stimulation, medicine.anatomical_structure, Female, Nerve Net, Skin Temperature, Psychology, Neuroscience

Abstract

During attention to a painful cutaneous laser stimulus, event-related causality (ERC) has been detected in recordings from subdural electrodes implanted directly over cortical modules for the treatment of epilepsy. However, these studies afforded limited sampling of modules and did not examine interactions with a nonpainful stimulus as a control. We now sample scalp EEG to test the hypothesis that attention to the laser stimulus is associated with poststimulus ERC interactions that are different from those with attention to a nonpainful stimulus. Subjects attended to (counted) either a painful laser stimulus (laser attention task) or a nonpainful electrical cutaneous stimulus that produced distraction from the laser (laser distraction task). Both of these stimuli were presented in random order in a single train. The intensities of both stimuli were adjusted to produce similar baseline salience and sensations in the same cutaneous territory. The results demonstrated that EEG channels with poststimulus ERC interactions were consistently different during the laser stimulus versus the electric stimulus. Poststimulus ERC interactions for the laser attention task were different from the laser distraction task. Furthermore, scalp EEG frontal channels play a driver role while parietal temporal channels play a receiver role during both tasks, although this does not prove that these channels are connected. Sites at which large numbers of ERC interactions were found for both laser attention and distraction tasks (critical sites) were located at Cz, Pz, and C3. Stimulation leading to disruption of sites of these pain-related interactions may produce analgesia for acute pain.

Published

2013

44. A method for event-related phase/amplitude coupling

Author

Mark D'Esposito, Robert T. Knight, Nathan E. Crone, and Bradley Voytek

Subjects

Computer science, Cognitive Neuroscience, Models, Neurological, Statistics as Topic, Concatenation, Phase (waves), Measure (mathematics), Article, Epilepsy, Biological Clocks, medicine, Humans, Computer Simulation, Evoked Potentials, Electrocorticography, Event (probability theory), Brain Mapping, medicine.diagnostic_test, Brain, medicine.disease, Electrophysiology, Amplitude, Neurology, Coupling (computer programming), Temporal resolution, Algorithm, Neuroscience, Algorithms

Abstract

Phase/amplitude coupling (PAC) is emerging as an important electrophysiological measure of local and long-distance neuronal communication. Current techniques for calculating PAC provide a numerical index that represents an average value across an arbitrarily long time period. This requires researchers to rely on block design experiments and temporal concatenation at the cost of the sub-second temporal resolution afforded by electrophysiological recordings. Here we present a method for calculating event-related phase/amplitude coupling (ERPAC) designed to capture the temporal evolution of task-related changes in PAC across events or between distant brain regions that is applicable to human or animal electromagnetic recording.

Published

2013

45. Reliability of early cortical auditory gamma-band responses

Author

Piotr J. Franaszczuk, Brian Caffo, Dana Boatman-Reich, Mackenzie C. Cervenka, Frederick A. Lenz, Paras Bhatt, Bo Hong, and Nathan E. Crone

Subjects

Adult, Male, medicine.medical_specialty, Adolescent, Concordance, Stimulus (physiology), Audiology, Electroencephalography, Auditory cortex, Spearman's rank correlation coefficient, Article, Functional Laterality, Young Adult, McNemar's test, Seizures, Physiology (medical), medicine, Humans, Age of Onset, Auditory Cortex, Reproducibility, medicine.diagnostic_test, Reproducibility of Results, Middle Aged, Magnetic Resonance Imaging, Sensory Systems, Electrodes, Implanted, Acoustic Stimulation, Neurology, Evoked Potentials, Auditory, Speech Perception, Female, Neurology (clinical), Psychology, Auditory Physiology, Craniotomy

Abstract

Objective To evaluate the test–retest reliability of event-related power changes in the 30–150 Hz gamma frequency range occurring in the first 150 ms after presentation of an auditory stimulus. Methods Repeat intracranial electrocorticographic (ECoG) recordings were performed with 12 epilepsy patients, at ⩾1-day intervals, using a passive odd-ball paradigm with steady-state tones. Time–frequency matching pursuit analysis was used to quantify changes in gamma-band power relative to pre-stimulus baseline. Test–retest reliability was estimated based on within-subject comparisons (paired t -test, McNemar’s test) and correlations (Spearman rank correlations, intra-class correlations) across sessions, adjusting for within-session variability. Reliability estimates of gamma-band response robustness, spatial concordance, and reproducibility were compared with corresponding measurements from concurrent auditory evoked N1 responses. Results All patients showed increases in gamma-band power, 50–120 ms post-stimulus onset, that were highly robust across recordings, comparable to the evoked N1 responses. Gamma-band responses occurred regardless of patients’ performance on behavioral tests of auditory processing, medication changes, seizure focus, or duration of test–retest interval. Test–retest reproducibility was greatest for the timing of peak power changes in the high-gamma range (65–150 Hz). Reliability of low-gamma responses and evoked N1 responses improved at higher signal-to-noise levels. Conclusions Early cortical auditory gamma-band responses are robust, spatially concordant, and reproducible over time. Significance These test–retest ECoG results confirm the reliability of auditory gamma-band responses, supporting their utility as objective measures of cortical processing in clinical and research studies.

Published

2013

46. Altered task-related modulation of long-range connectivity in children with autism

Author

Ajay S, Pillai, Danielle, McAuliffe, Balaji M, Lakshmanan, Stewart H, Mostofsky, Nathan E, Crone, and Joshua B, Ewen

Subjects

Cerebral Cortex, Male, Brain Mapping, Motivation, Gestures, Autism Spectrum Disorder, Electroencephalography, behavioral disciplines and activities, Magnetic Resonance Imaging, Article, Alpha Rhythm, mental disorders, Humans, Female, Nerve Net, Psychomotor Disorders, Beta Rhythm, Child, Correlation of Data

Abstract

Functional connectivity differences between children with autism spectrum disorder (ASD) and typically developing children have been described in multiple datasets. However, few studies examine the task-related changes in connectivity in disorder-relevant behavioral paradigms. In this paper, we examined the task-related changes in functional connectivity using EEG and a movement-based paradigm that has behavioral relevance to ASD. Resting-state studies motivated our hypothesis that children with ASD would show a decreased magnitude of functional connectivity during the performance of a motor-control task. Contrary to our initial hypothesis, however, we observed that task-related modulation of functional connectivity in children with ASD was in the direction opposite to that of TDs. The task-related connectivity changes were correlated with clinical symptom scores. Our results suggest that children with ASD may have differences in cortical segregation/integration during the performance of a task, and that part of the differences in connectivity modulation may serve as a compensatory mechanism. Autism Res 2018, 11: 245-257. © 2017 International Society for Autism Research, Wiley Periodicals, Inc.Decreased connectivity between brain regions is thought to cause the symptoms of autism. Because most of our knowledge comes from data in which children are at rest, we do not know how connectivity changes directly lead to autistic behaviors, such as impaired gestures. When typically developing children produced complex movements, connectivity decreased between brain regions. In children with autism, connectivity increased. It may be that behavior-related changes in brain connectivity are more important than absolute differences in connectivity in autism.

Published

2016

47. Rapid tuning shifts in human auditory cortex enhance speech intelligibility

Author

Jochem W. Rieger, Wendy A. de Heer, Robert T. Knight, Jack J. Lin, Brian N. Pasley, Chris Holdgraf, Nathan E. Crone, and Frédéric E. Theunissen

Subjects

0301 basic medicine, Computer science, 1.2 Psychological and socioeconomic processes, Acoustics, media_common.quotation_subject, Science, 1.1 Normal biological development and functioning, General Physics and Astronomy, Bioengineering, Stimulus (physiology), Auditory cortex, Brain mapping, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Phonetics, Underpinning research, Perception, otorhinolaryngologic diseases, Animals, Humans, Evoked Potentials, Auditory, media_common, Auditory Cortex, Brain Mapping, Multidisciplinary, Neuronal Plasticity, Speech Intelligibility, Neurosciences, General Chemistry, Neurophysiology, 030104 developmental biology, Acoustic Stimulation, Receptive field, Neurological, Evoked Potentials, Auditory, Auditory Perception, Neurocomputational speech processing, Electrocorticography, Neuroscience, 030217 neurology & neurosurgery

Abstract

Experience shapes our perception of the world on a moment-to-moment basis. This robust perceptual effect of experience parallels a change in the neural representation of stimulus features, though the nature of this representation and its plasticity are not well-understood. Spectrotemporal receptive field (STRF) mapping describes the neural response to acoustic features, and has been used to study contextual effects on auditory receptive fields in animal models. We performed a STRF plasticity analysis on electrophysiological data from recordings obtained directly from the human auditory cortex. Here, we report rapid, automatic plasticity of the spectrotemporal response of recorded neural ensembles, driven by previous experience with acoustic and linguistic information, and with a neurophysiological effect in the sub-second range. This plasticity reflects increased sensitivity to spectrotemporal features, enhancing the extraction of more speech-like features from a degraded stimulus and providing the physiological basis for the observed ‘perceptual enhancement' in understanding speech., Experience constantly shapes perception, but the neural mechanisms of this rapid plasticity are unclear. Here, Holdgraf et al. record neural activity in the human auditory cortex and show that listening to normal speech elicits rapid plasticity that increases the neural gain for features of sound that are key for speech intelligibility.

Published

2016

48. Cascade of neural processing orchestrates cognitive control in human frontal cortex

Author

Joseph R. Madsen, Hsiang Yu Yu, Gabriel Kreiman, William S. Anderson, Chien-Chen Chou, Nathan E. Crone, and Hanlin Tang

Subjects

Male, 0301 basic medicine, Cognition, 0302 clinical medicine, Cortex (anatomy), cognitive control, Biology (General), Child, Brain Mapping, frontal cortex, General Neuroscience, Cognitive flexibility, Electroencephalography, General Medicine, Middle Aged, human neurophysiology, Frontal Lobe, medicine.anatomical_structure, Frontal lobe, Medicine, Female, Psychology, Goals, Research Article, Human, Adult, Adolescent, QH301-705.5, Science, Models, Neurological, Sensation, Posterior parietal cortex, Sensory system, behavioral disciplines and activities, General Biochemistry, Genetics and Molecular Biology, Young Adult, 03 medical and health sciences, Reaction Time, medicine, Humans, Anterior cingulate cortex, General Immunology and Microbiology, Dorsolateral prefrontal cortex, 030104 developmental biology, Orbitofrontal cortex, volitional control, Neuroscience, 030217 neurology & neurosurgery, computational neuroscience

Abstract

Rapid and flexible interpretation of conflicting sensory inputs in the context of current goals is a critical component of cognitive control that is orchestrated by frontal cortex. The relative roles of distinct subregions within frontal cortex are poorly understood. To examine the dynamics underlying cognitive control across frontal regions, we took advantage of the spatiotemporal resolution of intracranial recordings in epilepsy patients while subjects resolved color-word conflict. We observed differential activity preceding the behavioral responses to conflict trials throughout frontal cortex; this activity was correlated with behavioral reaction times. These signals emerged first in anterior cingulate cortex (ACC) before dorsolateral prefrontal cortex (dlPFC), followed by medial frontal cortex (mFC) and then by orbitofrontal cortex (OFC). These results disassociate the frontal subregions based on their dynamics, and suggest a temporal hierarchy for cognitive control in human cortex. DOI: http://dx.doi.org/10.7554/eLife.12352.001, eLife digest The brain adapts to control our behavior in different ways depending on the specific situation, which is particularly useful when deciding how to interpret conflicting sets of information. The 'Stroop task' is a classic demonstration of this process. In this task, individuals are shown words where the color and the meaning of the text conflict – for example, the word 'green' is written in blue. When asked what the color of the text is, individuals must suppress the instinct to read the word. This causes them to make more mistakes and take longer to decide on an answer than when they perform the same task using words that have no conflict (for example, when “red” is written in red). Previous work has suggested that several regions within part of the brain called the frontal cortex play a role in this cognitive control process. However, the relative contributions of each of these regions, and the order in which they are activated, remain unclear. This is in part due to the fact that accurately measuring the electrical activity of the frontal cortex requires implanting electrodes into the brain. Tang et al. took advantage of a rare opportunity to record this activity from a group of patients who had electrodes implanted in their frontal cortex to treat epilepsy. The electrical signals recorded by these electrodes as the subjects performed the Stroop task revealed that four regions in the frontal cortex altered their activity during trials where the color and the meaning of a word conflicted. These responses corresponded with the subject’s reaction time, changed depending on the exact nature of the task, and even reflected the subjects’ errors. These responses arose at different times in different regions, allowing Tang et al. to suggest how signals flow through the frontal cortex during cognitive control. In the future it will be important to further understand how the regions of the frontal cortex identified by Tang et al. interact with each other and to establish their roles in cognitive control. These observations could then be used to produce a theoretical framework that describes how the brain adapts behavior to different circumstances. DOI: http://dx.doi.org/10.7554/eLife.12352.002

Published

2016

49. Individual finger control of a modular prosthetic limb using high-density electrocorticography in a human subject

Author

Nathan E. Crone, Matthew S. Fifer, Robert S. Armiger, Brock A. Wester, David P. McMullen, Matthew P. Para, Guy Hotson, Matthew S. Johannes, Kapil D. Katyal, William S. Anderson, and Nitish V. Thakor

Subjects

Male, Speech recognition, Movement, 0206 medical engineering, Biomedical Engineering, Sensory system, Artificial Limbs, 02 engineering and technology, Vibration, Article, Fingers, 03 medical and health sciences, Cellular and Molecular Neuroscience, User-Computer Interface, Young Adult, 0302 clinical medicine, Ring finger, medicine, Humans, Electrocorticography, Brain–computer interface, Cued speech, medicine.diagnostic_test, business.industry, Modular design, Linear discriminant analysis, 020601 biomedical engineering, Numerical digit, Electrodes, Implanted, body regions, medicine.anatomical_structure, Brain-Computer Interfaces, Sensorimotor Cortex, Psychology, business, 030217 neurology & neurosurgery

Abstract

Objective. We used native sensorimotor representations of fingers in a brain–machine interface (BMI) to achieve immediate online control of individual prosthetic fingers. Approach. Using high gamma responses recorded with a high-density electrocorticography (ECoG) array, we rapidly mapped the functional anatomy of cued finger movements. We used these cortical maps to select ECoG electrodes for a hierarchical linear discriminant analysis classification scheme to predict: (1) if any finger was moving, and, if so, (2) which digit was moving. To account for sensory feedback, we also mapped the spatiotemporal activation elicited by vibrotactile stimulation. Finally, we used this prediction framework to provide immediate online control over individual fingers of the Johns Hopkins University Applied Physics Laboratory modular prosthetic limb. Main results. The balanced classification accuracy for detection of movements during the online control session was 92% (chance: 50%). At the onset of movement, finger classification was 76% (chance: 20%), and 88% (chance: 25%) if the pinky and ring finger movements were coupled. Balanced accuracy of fully flexing the cued finger was 64%, and 77% had we combined pinky and ring commands. Offline decoding yielded a peak finger decoding accuracy of 96.5% (chance: 20%) when using an optimized selection of electrodes. Offline analysis demonstrated significant finger-specific activations throughout sensorimotor cortex. Activations either prior to movement onset or during sensory feedback led to discriminable finger control. Significance. Our results demonstrate the ability of ECoG-based BMIs to leverage the native functional anatomy of sensorimotor cortical populations to immediately control individual finger movements in real time.

Published

2016

50. Frontal and motor cortex contributions to response inhibition: evidence from electrocorticography

Author

Elinor Tzvi, Robert T. Knight, Yvonne M. Fonken, Nathan E. Crone, Jochem W. Rieger, Josef Parvizi, Ulrike M. Krämer, and Edward F. Chang

Subjects

Adult, Male, Drug Resistant Epilepsy, Physiology, Neural Inhibition, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Gamma Rhythm, medicine, Humans, 0501 psychology and cognitive sciences, Beta Rhythm, Attention, Electrocorticography, Response inhibition, medicine.diagnostic_test, General Neuroscience, 05 social sciences, Motor Cortex, Motor control, medicine.anatomical_structure, Higher Neural Functions and Behavior, Female, Psychology, Neuroscience, 030217 neurology & neurosurgery, Psychomotor Performance, Motor cortex

Abstract

Changes in the environment require rapid modification or inhibition of ongoing behavior. We used the stop-signal paradigm and intracranial recordings to investigate response preparation, inhibition, and monitoring of task-relevant information. Electrocorticographic data were recorded in eight patients with electrodes covering frontal, temporal, and parietal cortex, and time-frequency analysis was used to examine power differences in the beta (13–30 Hz) and high-gamma bands (60–180 Hz). Over motor cortex, beta power decreased, and high-gamma power increased during motor preparation for both go trials (Go) and unsuccessful stops (US). For successful stops (SS), beta increased, and high-gamma was reduced, indexing the cancellation of the prepared response. In the middle frontal gyrus (MFG), stop signals elicited a transient high-gamma increase. The MFG response occurred before the estimated stop-signal reaction time but did not distinguish between SS and US trials, likely signaling attention to the salient stop stimulus. A postresponse high-gamma increase in MFG was stronger for US compared with SS and absent in Go, supporting a role in behavior monitoring. These results provide evidence for differential contributions of frontal subregions to response inhibition, including motor preparation and inhibitory control in motor cortex and cognitive control and action evaluation in lateral prefrontal cortex.

Published

2016