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1. A click-based electrocorticographic brain-computer interface enables long-term high-performance switch scan spelling

Author

Daniel N. Candrea, Samyak Shah, Shiyu Luo, Miguel Angrick, Qinwan Rabbani, Christopher Coogan, Griffin W. Milsap, Kevin C. Nathan, Brock A. Wester, William S. Anderson, Kathryn R. Rosenblatt, Alpa Uchil, Lora Clawson, Nicholas J. Maragakis, Mariska J. Vansteensel, Francesco V. Tenore, Nicolas F. Ramsey, Matthew S. Fifer, and Nathan E. Crone

Subjects
Medicine
Abstract

Abstract Background Brain-computer interfaces (BCIs) can restore communication for movement- and/or speech-impaired individuals by enabling neural control of computer typing applications. Single command click detectors provide a basic yet highly functional capability. Methods We sought to test the performance and long-term stability of click decoding using a chronically implanted high density electrocorticographic (ECoG) BCI with coverage of the sensorimotor cortex in a human clinical trial participant (ClinicalTrials.gov, NCT03567213) with amyotrophic lateral sclerosis. We trained the participant’s click detector using a small amount of training data (

Published
2024
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2. Cortical sites critical to language function act as connectors between language subnetworks

Author

Jason K. Hsieh, Prashanth R. Prakash, Robert D. Flint, Zachary Fitzgerald, Emily Mugler, Yujing Wang, Nathan E. Crone, Jessica W. Templer, Joshua M. Rosenow, Matthew C. Tate, Richard Betzel, and Marc W. Slutzky

Subjects
Science
Abstract

Abstract Historically, eloquent functions have been viewed as localized to focal areas of human cerebral cortex, while more recent studies suggest they are encoded by distributed networks. We examined the network properties of cortical sites defined by stimulation to be critical for speech and language, using electrocorticography from sixteen participants during word-reading. We discovered distinct network signatures for sites where stimulation caused speech arrest and language errors. Both demonstrated lower local and global connectivity, whereas sites causing language errors exhibited higher inter-community connectivity, identifying them as connectors between modules in the language network. We used machine learning to classify these site types with reasonably high accuracy, even across participants, suggesting that a site’s pattern of connections within the task-activated language network helps determine its importance to function. These findings help to bridge the gap in our understanding of how focal cortical stimulation interacts with complex brain networks to elicit language deficits.

Published
2024
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3. Cascade of neural processing orchestrates cognitive control in human frontal cortex

Author

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

Subjects
frontal cortex, human neurophysiology, cognitive control, volitional control, computational neuroscience, Medicine, Science, Biology (General), QH301-705.5
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.

Published
2016
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4. Online speech synthesis using a chronically implanted brain–computer interface in an individual with ALS

Author

Miguel Angrick, Shiyu Luo, Qinwan Rabbani, Daniel N. Candrea, Samyak Shah, Griffin W. Milsap, William S. Anderson, Chad R. Gordon, Kathryn R. Rosenblatt, Lora Clawson, Donna C. Tippett, Nicholas Maragakis, Francesco V. Tenore, Matthew S. Fifer, Hynek Hermansky, Nick F. Ramsey, and Nathan E. Crone

Subjects
Medicine, Science
Abstract

Abstract Brain–computer interfaces (BCIs) that reconstruct and synthesize speech using brain activity recorded with intracranial electrodes may pave the way toward novel communication interfaces for people who have lost their ability to speak, or who are at high risk of losing this ability, due to neurological disorders. Here, we report online synthesis of intelligible words using a chronically implanted brain-computer interface (BCI) in a man with impaired articulation due to ALS, participating in a clinical trial (ClinicalTrials.gov, NCT03567213) exploring different strategies for BCI communication. The 3-stage approach reported here relies on recurrent neural networks to identify, decode and synthesize speech from electrocorticographic (ECoG) signals acquired across motor, premotor and somatosensory cortices. We demonstrate a reliable BCI that synthesizes commands freely chosen and spoken by the participant from a vocabulary of 6 keywords previously used for decoding commands to control a communication board. Evaluation of the intelligibility of the synthesized speech indicates that 80% of the words can be correctly recognized by human listeners. Our results show that a speech-impaired individual with ALS can use a chronically implanted BCI to reliably produce synthesized words while preserving the participant’s voice profile, and provide further evidence for the stability of ECoG for speech-based BCIs.

Published
2024
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5. Spatio-temporal dynamics of word selection in speech production: Insights from electrocorticography

Author

Stephanie K Ries, Alex D Clarke, David King-Stephen, Rachel Kuperman, Peter Brunner, Jack J Lin, Josef Parvizi, Nathan E Crone, and Nina F Dronkers

Subjects
electrocorticography, Semantic interference, Brain Dynamics, Language production, Word selection, Psychology, BF1-990
Abstract

Background Word selection refers to the act of choosing words as we speak. Different regions of the left lateral and medial prefrontal cortex (PFC), and left temporal cortex (LTC) are associated with word selection (Price, 2012) but their role and how they interact remain underspecified. Methods We recorded electrocorticography (ECoG) in 9 neurosurgical patients to examine where and when subregions of the PFC and the LTC were engaged in word selection (7 left, 2 right hemisphere cases). Patients performed picture naming wherein semantic context was manipulated to affect word selection difficulty: pictures of objects were presented within semantically-homogeneous or heterogeneous blocks and presented 4 times per block. This paradigm is known to elicit the classical semantic interference effect where performance is worse in homogeneous than in heterogeneous blocks from the 2nd presentation onward (Damian et al., 2001). Results Behavioral results: Subjects’ performance was worse in homogeneous vs. heterogeneous blocks, showing the usual semantic interference effect. There was a significant interaction between semantic context and presentation number for both reaction times (Wald Χ2 = 11.96, p = .008) and error rates (Wald Z = -2.00, p = .046). ECoG results: High-gamma (HG, 70 to 150 Hz) amplitude, indexing cortical activation magnitude, was sensitive to semantic interference at several cortical sites (i.e. greater in homogeneous vs. heterogenous blocks, Figure 1). Early effects were seen in HG activity starting before 250 ms post-stimulus at posterior inferior LTC and middle and superior frontal sites. Response-locked effects were seen in medial and left lateral PFC activity peaking before vocal onset and also in posterior superior and middle LTC activity peaking after vocal onset. Finally, across trials, HG amplitude co-varied between responsive left PFC and LTC sites. Single-case: One patient, whose seizure focus was in the posterior medial PFC, had poor performance (error rate > 40%) and his data was therefore analyzed separately. His semantic interference effect (321 ms) was more than 3 standard deviations larger than that of the other patients (mean = 43 ms, SD = 82 ms). Thus, when brain tissue in the posterior medial PFC is abnormal, interference caused by semantically-related alternatives is more difficult to overcome. Conclusions Our results suggest that the posterior inferior LTC is involved in word selection as semantic concepts become available. Posterior medial and left PFC regions may be involved in trial-by-trial top-down control over LTC to help overcome interference caused by semantically-related alternatives in word selection. The single-case result supports this hypothesis and suggests that the posterior medial PFC plays a causal role in resolving this interference in word selection. Lastly, the sensitivity to semantic interference of the post-vocal onset posterior LTC activity suggests the semantic interference effect does not only reflect word selection difficulty but is also present at post-selection stages such as verbal response monitoring. In sum, this study reveals a dynamic network of interacting brain regions that support word selection in language production.

Published
2015
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6. Dynamic changes in phase-amplitude coupling facilitate spatial attention control in fronto-parietal cortex.

Author

Sara M Szczepanski, Nathan E Crone, Rachel A Kuperman, Kurtis I Auguste, Josef Parvizi, and Robert T Knight

Subjects
Biology (General), QH301-705.5
Abstract

Attention is a core cognitive mechanism that allows the brain to allocate limited resources depending on current task demands. A number of frontal and posterior parietal cortical areas, referred to collectively as the fronto-parietal attentional control network, are engaged during attentional allocation in both humans and non-human primates. Numerous studies have examined this network in the human brain using various neuroimaging and scalp electrophysiological techniques. However, little is known about how these frontal and parietal areas interact dynamically to produce behavior on a fine temporal (sub-second) and spatial (sub-centimeter) scale. We addressed how human fronto-parietal regions control visuospatial attention on a fine spatiotemporal scale by recording electrocorticography (ECoG) signals measured directly from subdural electrode arrays that were implanted in patients undergoing intracranial monitoring for localization of epileptic foci. Subjects (n = 8) performed a spatial-cuing task, in which they allocated visuospatial attention to either the right or left visual field and detected the appearance of a target. We found increases in high gamma (HG) power (70-250 Hz) time-locked to trial onset that remained elevated throughout the attentional allocation period over frontal, parietal, and visual areas. These HG power increases were modulated by the phase of the ongoing delta/theta (2-5 Hz) oscillation during attentional allocation. Critically, we found that the strength of this delta/theta phase-HG amplitude coupling predicted reaction times to detected targets on a trial-by-trial basis. These results highlight the role of delta/theta phase-HG amplitude coupling as a mechanism for sub-second facilitation and coordination within human fronto-parietal cortex that is guided by momentary attentional demands.

Published
2014
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7. Coarse electrocorticographic decoding of ipsilateral reach in patients with brain lesions.

Author

Guy Hotson, Matthew S Fifer, Soumyadipta Acharya, Heather L Benz, William S Anderson, Nitish V Thakor, and Nathan E Crone

Subjects
Medicine, Science
Abstract

In patients with unilateral upper limb paralysis from strokes and other brain lesions, strategies for functional recovery may eventually include brain-machine interfaces (BMIs) using control signals from residual sensorimotor systems in the damaged hemisphere. When voluntary movements of the contralateral limb are not possible due to brain pathology, initial training of such a BMI may require use of the unaffected ipsilateral limb. We conducted an offline investigation of the feasibility of decoding ipsilateral upper limb movements from electrocorticographic (ECoG) recordings in three patients with different lesions of sensorimotor systems associated with upper limb control. We found that the first principal component (PC) of unconstrained, naturalistic reaching movements of the upper limb could be decoded from ipsilateral ECoG using a linear model. ECoG signal features yielding the best decoding accuracy were different across subjects. Performance saturated with very few input features. Decoding performances of 0.77, 0.73, and 0.66 (median Pearson's r between the predicted and actual first PC of movement using nine signal features) were achieved in the three subjects. The performance achieved here with small numbers of electrodes and computationally simple decoding algorithms suggests that it may be possible to control a BMI using ECoG recorded from damaged sensorimotor brain systems.

Published
2014
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8. Virtual stimulation of the interictal EEG network localizes the EZ as a measure of cortical excitability

Author

Sophia R. Zhai, Sridevi V. Sarma, Kristin Gunnarsdottir, Nathan E. Crone, Adam G. Rouse, Jennifer J. Cheng, Michael J. Kinsman, Patrick Landazuri, Utku Uysal, Carol M. Ulloa, Nathaniel Cameron, Sara Inati, Kareem A. Zaghloul, Varina L. Boerwinkle, Sarah Wyckoff, Niravkumar Barot, Jorge A. González-Martínez, Joon Y. Kang, and Rachel June Smith

Subjects
epileptogenic zone, dynamic network model, intracranial EEG, virtual stimulation, cortical excitability, single-pulse electrical stimulation, Electronic computers. Computer science, QA75.5-76.95
Abstract

Introduction: For patients with drug-resistant epilepsy, successful localization and surgical treatment of the epileptogenic zone (EZ) can bring seizure freedom. However, surgical success rates vary widely because there are currently no clinically validated biomarkers of the EZ. Highly epileptogenic regions often display increased levels of cortical excitability, which can be probed using single-pulse electrical stimulation (SPES), where brief pulses of electrical current are delivered to brain tissue. It has been shown that high-amplitude responses to SPES can localize EZ regions, indicating a decreased threshold of excitability. However, performing extensive SPES in the epilepsy monitoring unit (EMU) is time-consuming. Thus, we built patient-specific in silico dynamical network models from interictal intracranial EEG (iEEG) to test whether virtual stimulation could reveal information about the underlying network to identify highly excitable brain regions similar to physical stimulation of the brain.Methods: We performed virtual stimulation in 69 patients that were evaluated at five centers and assessed for clinical outcome 1 year post surgery. We further investigated differences in observed SPES iEEG responses of 14 patients stratified by surgical outcome.Results: Clinically-labeled EZ cortical regions exhibited higher excitability from virtual stimulation than non-EZ regions with most significant differences in successful patients and little difference in failure patients. These trends were also observed in responses to extensive SPES performed in the EMU. Finally, when excitability was used to predict whether a channel is in the EZ or not, the classifier achieved an accuracy of 91%.Discussion: This study demonstrates how excitability determined via virtual stimulation can capture valuable information about the EZ from interictal intracranial EEG.

Published
2024
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9. Reconstructing speech from human auditory cortex.

Author

Brian N Pasley, Stephen V David, Nima Mesgarani, Adeen Flinker, Shihab A Shamma, Nathan E Crone, Robert T Knight, and Edward F Chang

Subjects
Biology (General), QH301-705.5
Abstract

How the human auditory system extracts perceptually relevant acoustic features of speech is unknown. To address this question, we used intracranial recordings from nonprimary auditory cortex in the human superior temporal gyrus to determine what acoustic information in speech sounds can be reconstructed from population neural activity. We found that slow and intermediate temporal fluctuations, such as those corresponding to syllable rate, were accurately reconstructed using a linear model based on the auditory spectrogram. However, reconstruction of fast temporal fluctuations, such as syllable onsets and offsets, required a nonlinear sound representation based on temporal modulation energy. Reconstruction accuracy was highest within the range of spectro-temporal fluctuations that have been found to be critical for speech intelligibility. The decoded speech representations allowed readout and identification of individual words directly from brain activity during single trial sound presentations. These findings reveal neural encoding mechanisms of speech acoustic parameters in higher order human auditory cortex.

Published
2012
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10. Coherence potentials encode simple human sensorimotor behavior.

Author

Dhanya Parameshwaran, Nathan E Crone, and Tara C Thiagarajan

Subjects
Medicine, Science
Abstract

Recent work has shown that large amplitude negative periods in the local field potential (nLFPs) are able to spread in saltatory manner across large distances in the cortex without distortion in their temporal structure forming 'coherence potentials'. Here we analysed subdural electrocorticographic (ECoG) signals recorded at 59 sites in the sensorimotor cortex in the left hemisphere of a human subject performing a simple visuomotor task (fist clenching and foot dorsiflexion) to understand how coherence potentials arising in the recordings relate to sensorimotor behavior. In all behaviors we found a particular coherence potential (i.e. a cascade of a particular nLFP wave pattern) arose consistently across all trials with temporal specificity. During contrateral fist clenching, but not the foot dorsiflexion or ipsilateral fist clenching, the coherence potential most frequently originated in the hand representation area in the somatosensory cortex during the anticipation and planning periods of the trial, moving to other regions during the actual motor behavior. While these 'expert' sites participated more consistently, other sites participated only a small fraction of the time. Furthermore, the timing of the coherence potential at the hand representation area after onset of the cue predicted the timing of motor behavior. We present the hypothesis that coherence potentials encode information relevant for behavior and are generated by the 'expert' sites that subsequently broadcast to other sites as a means of 'sharing knowledge'.

Published
2012
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11. Towards optimizing single pulse electrical stimulation: High current intensity, short pulse width stimulation most effectively elicits evoked potentials

Author

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

Subjects
Single pulse electrical stimulation, Cortico-cortical evoked potential, Intracranial EEG, Effective connectivity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Background: While single pulse electrical stimulation (SPES) is increasingly used to study effective connectivity, the effects of varying stimulation parameters on the resulting cortico-cortical evoked potentials (CCEPs) have not been systematically explored. Objective: We sought to understand the interacting effects of stimulation pulse width, current intensity, and charge on CCEPs through an extensive testing of this parameter space and analysis of several response metrics. Methods: We conducted SPES in 11 patients undergoing intracranial EEG monitoring using five combinations of current intensity (1.5, 2.0, 3.0, 5.0, and 7.5 mA) and pulse width at each of three charges (0.750, 1.125, and 1.500 μC/phase) to study how CCEP amplitude, distribution, latency, morphology, and stimulus artifact amplitude vary with each parameter. Results: Stimulations with a greater charge or a greater current intensity and shorter pulse width at a given charge generally resulted in greater CCEP amplitudes and spatial distributions, shorter latencies, and increased waveform correlation. These effects interacted such that stimulations with the lowest charge and highest current intensities resulted in greater response amplitudes and spatial distributions than stimulations with the highest charge and lowest current intensities. Stimulus artifact amplitude increased with charge, but this could be mitigated by using shorter pulse widths. Conclusions: Our results indicate that individual combinations of current intensity and pulse width, in addition to charge, are important determinants of CCEP magnitude, morphology, and spatial extent. Together, these findings suggest that high current intensity, short pulse width stimulations are optimal SPES settings for eliciting strong and consistent responses while minimizing charge.

Published
2023
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12. Stable Decoding from a Speech BCI Enables Control for an Individual with ALS without Recalibration for 3 Months

Author

Shiyu Luo, Miguel Angrick, Christopher Coogan, Daniel N. Candrea, Kimberley Wyse‐Sookoo, Samyak Shah, Qinwan Rabbani, Griffin W. Milsap, Alexander R. Weiss, William S. Anderson, Donna C. Tippett, Nicholas J. Maragakis, Lora L. Clawson, Mariska J. Vansteensel, Brock A. Wester, Francesco V. Tenore, Hynek Hermansky, Matthew S. Fifer, Nick F. Ramsey, and Nathan E. Crone

Subjects
amyotrophic lateral sclerosis (ALS), brain‐computer interfaces, neural decoding, speech brain‐computer interface (BCI), Science
Abstract

Abstract Brain‐computer interfaces (BCIs) can be used to control assistive devices by patients with neurological disorders like amyotrophic lateral sclerosis (ALS) that limit speech and movement. For assistive control, it is desirable for BCI systems to be accurate and reliable, preferably with minimal setup time. In this study, a participant with severe dysarthria due to ALS operates computer applications with six intuitive speech commands via a chronic electrocorticographic (ECoG) implant over the ventral sensorimotor cortex. Speech commands are accurately detected and decoded (median accuracy: 90.59%) throughout a 3‐month study period without model retraining or recalibration. Use of the BCI does not require exogenous timing cues, enabling the participant to issue self‐paced commands at will. These results demonstrate that a chronically implanted ECoG‐based speech BCI can reliably control assistive devices over long time periods with only initial model training and calibration, supporting the feasibility of unassisted home use.

Published
2023
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18. Cross-task specificity and within-task invariance of cognitive control processes

Author

Yuchen Xiao, Chien-Chen Chou, Garth Rees Cosgrove, Nathan E. Crone, Scellig Stone, Joseph R. Madsen, Ian Reucroft, Yen-Cheng Shih, Daniel Weisholtz, Hsiang-Yu Yu, William S. Anderson, and Gabriel Kreiman

Subjects
CP: Neuroscience, Biology (General), QH301-705.5
Abstract

Summary: Cognitive control involves flexibly combining multiple sensory inputs with task-dependent goals during decision making. Several tasks involving conflicting sensory inputs and motor outputs have been proposed to examine cognitive control, including the Stroop, Flanker, and multi-source interference task. Because these tasks have been studied independently, it remains unclear whether the neural signatures of cognitive control reflect abstract control mechanisms or specific combinations of sensory and behavioral aspects of each task. To address these questions, we record invasive neurophysiological signals from 16 patients with pharmacologically intractable epilepsy and compare neural responses within and between tasks. Neural signals differ between incongruent and congruent conditions, showing strong modulation by conflicting task demands. These neural signals are mostly specific to each task, generalizing within a task but not across tasks. These results highlight the complex interplay between sensory inputs, motor outputs, and task demands underlying cognitive control processes.

Published
2023
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24. Cortico-cortical evoked potentials in response to varying stimulation intensity improves seizure localization

Author

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

Subjects
Neurology, Physiology (medical), Neurology (clinical), Sensory Systems
Abstract

As single pulse electrical stimulation (SPES) is increasingly utilized to help localize the seizure onset zone (SOZ), it is important to understand how stimulation intensity can affect the ability to use cortico-cortical evoked potentials (CCEPs) to delineate epileptogenic regions.We studied 15 drug-resistant epilepsy patients undergoing intracranial EEG monitoring and SPES with titrations of stimulation intensity. The N1 amplitude and distribution of CCEPs elicited in the SOZ and non-seizure onset zone (nSOZ) were quantified at each intensity. The separability of the SOZ and nSOZ using N1 amplitudes was compared between models using responses to titrations, responses to one maximal intensity, or both.At 2 mA and above, the increase in N1 amplitude with current intensity was greater for responses within the SOZ, and SOZ response distribution was maximized by 4-6 mA. Models incorporating titrations achieved better separability of SOZ and nSOZ compared to those using one maximal intensity.We demonstrated that differences in CCEP amplitude over a range of current intensities can improve discriminability of SOZ regions.This study provides insight into the underlying excitability of the SOZ and how differences in current-dependent amplitudes of CCEPs may be used to help localize epileptogenic sites.

Published
2023
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28. Semi-autonomous Hybrid Brain-Machine Interface.

Author

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

Published
2015
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29. A supervised data-driven spatial filter denoising method for acoustic-induced artifacts in intracranial electrophysiological recordings

Author

Victoria Peterson, Matteo Vissani, Shiyu Luo, Qinwan Rabbani, Nathan E. Crone, Alan Bush, and R. Mark Richardson

Abstract

Neurosurgical procedures, in which electrodes can be placed in the brain of awake patients, offer remarkable opportunities to discover the neurophysiology underlying human speech. The relative scarcity of these opportunities and the altruism of participating patients obligates us to apply the highest possible rigor to signal interpretation. Intracranial electroencephalography (iEEG) signals recorded during overt speech can present an acoustic-induced vibration artifact that tracks the fundamental frequency (F0) of the participant’s voice, encompassing high-gamma frequencies that are used for neural activation during speech production and perception. To advance our understanding of the neural control of speech production and develop reliable speech models, we developed a spatial filtering approach to identify and remove acoustic-induced artifactual components of the recorded signal. We show that traditional reference schemes may jeopardize signal quality, but our data-driven method can denoise the recording while preserving signals from the underlying neural activity.

Published
2023
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35. 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
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36. 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
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41. 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
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46. The dynamics of cortical interactions in visual recognition of object category: living versus nonliving

Author

Kiyohide Usami, Riki Matsumoto, Anna Korzeniewska, Akihiro Shimotake, Masao Matsuhashi, Takuro Nakae, Takayuki Kikuchi, Kazumichi Yoshida, Takeharu Kunieda, Ryosuke Takahashi, Nathan E Crone, and Akio Ikeda

Subjects
picture naming, Cellular and Molecular Neuroscience, event-related causality, Cognitive Neuroscience, high-gamma activity, causal interaction
Abstract

Noninvasive brain imaging studies have shown that higher visual processing of objects occurs in neural populations that are separable along broad semantic categories, particularly living versus nonliving objects. However, because of their limited temporal resolution, these studies have not been able to determine whether broad semantic categories are also reflected in the dynamics of neural interactions within cortical networks. We investigated the time course of neural propagation among cortical areas activated during object naming in 12 patients implanted with subdural electrode grids prior to epilepsy surgery, with a special focus on the visual recognition phase of the task. Analysis of event-related causality revealed significantly stronger neural propagation among sites within ventral temporal lobe (VTL) at early latencies, around 250 ms, for living objects compared to nonliving objects. Differences in other features, including familiarity, visual complexity, and age of acquisition, did not significantly change the patterns of neural propagation. Our findings suggest that the visual processing of living objects relies on stronger causal interactions among sites within VTL, perhaps reflecting greater integration of visual feature processing. In turn, this may help explain the fragility of naming living objects in neurological diseases affecting VTL.

Published
2022

47. 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

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