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5. Thalamic spindles and Up states coordinate cortical and hippocampal co-ripples in humans.

Author

Dickey, Charles W., Verzhbinsky, Ilya A., Kajfez, Sophie, Rosen, Burke Q., Gonzalez, Christopher E., Chauvel, Patrick Y., Cash, Sydney S., Pati, Sandipan, and Halgren, Eric

Subjects
NON-REM sleep, THALAMUS, LONG-term memory, NEOCORTEX, SLEEP spindles, HIPPOCAMPUS (Brain), THALAMIC nuclei, THALAMOCORTICAL system
Abstract

In the neocortex, ~90 Hz ripples couple to ~12 Hz sleep spindles on the ~1 Hz Down-to-Up state transition during non-rapid eye movement sleep. This conjunction of sleep waves is critical for the consolidation of memories into long-term storage. The widespread co-occurrences of ripples ("co-ripples") may integrate information across the neocortex and hippocampus to facilitate consolidation. While the thalamus synchronizes spindles and Up states in the cortex for memory, it is not known whether it may also organize co-ripples. Using human intracranial recordings during NREM sleep, we investigated whether cortico-cortical co-ripples and hippocampo-cortical co-ripples are either: (1) driven by directly projected thalamic ripples; or (2) coordinated by propagating thalamic spindles or Up states. We found ripples in the anterior and posterior thalamus, with similar characteristics as hippocampal and cortical ripples, including having a center frequency of ~90 Hz and coupling to local spindles on the Down-to-Up state transition. However, thalamic ripples rarely co-occur or phase-lock with cortical or hippocampal ripples. By contrast, spindles and Up states that propagate from the thalamus strongly coordinate co-ripples in the cortex and hippocampus. Thus, thalamo-cortical spindles and Up states, rather than thalamic ripples, may provide input facilitating spatially distributed co-rippling that integrates information for memory consolidation during sleep in humans. The thalamus synchronizes spindles and Up states in the cortex for memory, but does it also organize co-ripples in the hippocampus and neocortex? This study shows that during human sleep, thalamic spindles and Up states synchronize networks that regulate memory consolidation during sleep. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Syllable processing is organized in discrete subregions of the human superior temporal gyrus.

Author

Cleary, Daniel R., Tchoe, Youngbin, Bourhis, Andrew, Dickey, Charles W., Stedelin, Brittany, Ganji, Mehran, Lee, Sang Heon, Lee, Jihweean, Siler, Dominic A., Brown, Erik C., Rosen, Burke Q., Kaestner, Erik, Yang, Jimmy C., Soper, Daniel J., Han, Seunggu Jude, Paulk, Angelique C., Cash, Sydney S., Raslan, Ahmed M., Dayeh, Shadi A., and Halgren, Eric

Subjects
TEMPORAL lobe, SPEECH, CRANIOTOMY, INFORMATION processing, ELECTRODES
Abstract

Modular organization at approximately 1 mm scale could be fundamental to cortical processing, but its presence in human association cortex is unknown. Using custom-built, high-density electrode arrays placed on the cortical surface of 7 patients undergoing awake craniotomy for tumor excision, we investigated receptive speech processing in the left (dominant) human posterior superior temporal gyrus. Responses to consonant-vowel syllables and noise-vocoded controls recorded with 1,024 channel micro-grids at 200 μm pitch demonstrated roughly circular domains approximately 1.7 mm in diameter, with sharp boundaries observed in 128 channel linear arrays at 50 μm pitch, possibly consistent with a columnar organization. Peak latencies to syllables in different modules were bimodally distributed centered at 252 and 386 ms. Adjacent modules were sharply delineated from each other by their distinct time courses and stimulus selectivity. We suggest that receptive language cortex may be organized in discrete processing modules. The brain is anatomically organized in columns, but how these columns relate to function in the human association cortex is not clear. This study reveals that the human superior temporal gyrus is functionally organized in ~1.7-mm diameter modules that process language information. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Emergent effects of synaptic connectivity on the dynamics of global and local slow waves in a large-scale thalamocortical network model of the human brain.

Author

Marsh, Brianna, Navas-Zuloaga, M. Gabriela, Rosen, Burke Q., Sokolov, Yury, Delanois, Jean Erik, Gonzalez, Oscar C., Krishnan, Giri P., Halgren, Eric, and Bazhenov, Maxim

Subjects
THALAMOCORTICAL system, LARVAL dispersal, SLOW wave sleep, NEURAL circuitry, FUNCTIONAL connectivity, EYE movements
Abstract

Slow-wave sleep (SWS), characterized by slow oscillations (SOs, <1Hz) of alternating active and silent states in the thalamocortical network, is a primary brain state during Non-Rapid Eye Movement (NREM) sleep. In the last two decades, the traditional view of SWS as a global and uniform whole-brain state has been challenged by a growing body of evidence indicating that SO can be local and can coexist with wake-like activity. However, the mechanisms by which global and local SOs arise from micro-scale neuronal dynamics and network connectivity remain poorly understood. We developed a multi-scale, biophysically realistic human whole-brain thalamocortical network model capable of transitioning between the awake state and SWS, and we investigated the role of connectivity in the spatio-temporal dynamics of sleep SO. We found that the overall strength and a relative balance between long and short-range synaptic connections determined the network state. Importantly, for a range of synaptic strengths, the model demonstrated complex mixed SO states, where periods of synchronized global slow-wave activity were intermittent with the periods of asynchronous local slow-waves. An increase in the overall synaptic strength led to synchronized global SO, while a decrease in synaptic connectivity produced only local slow-waves that would not propagate beyond local areas. These results were compared to human data to validate probable models of biophysically realistic SO. The model producing mixed states provided the best match to the spatial coherence profile and the functional connectivity estimated from human subjects. These findings shed light on how the spatio-temporal properties of SO emerge from local and global cortical connectivity and provide a framework for further exploring the mechanisms and functions of SWS in health and disease. Author summary: Slow Wave Sleep (SWS) is a primary brain state found during Non-Rapid Eye Movement (NREM) sleep. While previously thought of as homogeneous waves of activity that sweep across the entire brain, recent research has suggested a more nuanced pattern of activity that can vary between local and global slow waves. However, understanding how these states emerge from small-scale neuronal dynamics and network connectivity remains unclear. We developed a biophysically realistic model of the human brain capable of generating SWS-like behavior and investigated the role of connectivity in the spatio-temporal dynamics of the sleep slow waves. We found that the overall strength and relative balance between long and short-range synaptic connections determined the network behavior—specifically, models with relatively weaker long-range connectivity resulted in mixed states of global and local slow waves. Comparing these results to human data, we found that models producing mixed states best matched the network behavior and functional connectivity observed in human subjects. These findings shed light on how the spatio-temporal properties of SWS emerge from local and global cortical connectivity and provide a framework for further exploring the mechanisms and functions of SWS in health and disease. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Estimating the absolute number of axons connecting different cortical areas in humans with diffusion MRI

Author

Rosen, Burke Q

Subjects
diffusion MRI, Human Connectome Project, structural connectivity, white matter, computational neuroanatomy
Abstract

This is a collection of preprocesseddata and standalone Matlab analysis code for the bioRxiv preprint of the same name,https://doi.org/10.1101/2021.06.07.447453. The processed diffusion MRI connectivity data was reported and previous distributed in the eNeuro articlehttps://doi.org/10.1523/ENEURO.0416-20.2020.Please cite these publicationswhen using relevant code or data.Files with the .mat extension are Matlab v7.3 data files. The raw imaging data from which these fileswere derived are available fromhttps://db.humanconnectome.org.

Published
2021
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12. Human cortical areas are sparsely connected: Combining histology with diffusion MRI to estimate the absolute number of axons

Author

Rosen, Burke Q and Halgren, Eric

Subjects
diffusion MRI, Human Connectome Project, structural connectivity, white matter, neuroanatomy
Abstract

This is a collection of preprocesseddata and standalone Matlab analysis code for the bioRxiv preprint of the same name,https://doi.org/10.1101/2021.06.07.447453. The primary processed diffusion MRI connectivity data was reported and previous distributed in our eNeuro articlehttps://doi.org/10.1523/ENEURO.0416-20.2020. The replication dataset was reported and previous distributed by Arnatkeviciute et al. 2021, Nature Communications (https://doi.org/10.1038/s41467-021-24306-2). Please cite these publicationswhen using relevant code or data.Files with the .mat extension are Matlab v7.3 data files. The raw imaging data from which these fileswere derived are available fromhttps://db.humanconnectome.org.

Published
2021
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13. Cortical Ripples during NREM Sleep and Waking in Humans.

Author

Dickey, Charles W., Verzhbinsky, Ilya A., Xi Jiang, Rosen, Burke Q., Kajfez, Sophie, Eskandar, Emad N., Gonzalez-Martinez, Jorge, Cash, Sydney S., and Halgren, Eric

Subjects
NON-REM sleep, RECOLLECTION (Psychology), ACTION potentials, FREQUENCIES of oscillating systems, CO-combustion
Abstract

Hippocampal ripples index the reconstruction of spatiotemporal neuronal firing patterns essential for the consolidation of memories in the cortex during non-rapid eye movement sleep (NREM). Recently, cortical ripples in humans have been shown to enfold the replay of neuron firing patterns during cued recall. Here, using intracranial recordings from 18 patients (12 female), we show that cortical ripples also occur during NREM in humans, with similar density, oscillation frequency (~90 Hz), duration, and amplitude to waking. Ripples occurred in all cortical regions with similar characteristics, unrelated to putative hippocampal connectivity, and were less dense and robust in higher association areas. Putative pyramidal and interneuron spiking phase-locked to cortical ripples during NREM, with phase delays consistent with ripple generation through pyramidal-interneuron feedback. Cortical ripples were smaller in amplitude than hippocampal ripples but were similar in density, frequency, and duration. Cortical ripples during NREM typically occurred just before the upstate peak, often during spindles. Upstates and spindles have previously been associated with memory consolidation, and we found that cortical ripples grouped cofiring between units within the window of spike timing-dependent plasticity. Thus, human NREM cortical ripples are as follows: ubiquitous and stereotyped with a tightly focused oscillation frequency; similar to hippocampal ripples; associated with upstates and spindles; and associated with unit cofiring. These properties are consistent with cortical ripples possibly contributing to memory consolidation and other functions during NREM in humans. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Theta oscillatory dynamics of inhibitory control, error processing, and post‐error adjustments: Neural underpinnings and alcohol‐induced dysregulation in social drinkers.

Author

Marinkovic, Ksenija and Rosen, Burke Q.

Subjects
*EXECUTIVE function, *NEURAL pathways, *ELECTROENCEPHALOGRAPHY, *TIME, *ALCOHOLIC intoxication, *BEHAVIOR, *TASK performance, *MAGNETIC resonance imaging, *COGNITION, *ALCOHOL drinking, *NEUROLOGIC examination
Abstract

Background: Alcohol intoxication impairs inhibitory control, resulting in disinhibited, impulsive behavior. The anterior cingulate cortex (ACC) plays an essential role in a range of executive functions and is sensitive to the effects of alcohol, which contributes to the top‐down cognitive dysregulation. This study used a multimodal approach to examine the acute effects of alcohol on the neural underpinnings of inhibitory control, inhibition failures, and neurobehavioral optimization as reflected in trial‐to‐trial dynamics of post‐error adjustments. Methods: Adult social drinkers served as their own controls by participating in the Go/NoGo task during acute alcohol and placebo conditions in a multi‐session, counterbalanced design. Distributed source modeling of the magnetoencephalographic signal was combined with structural magnetic resonance imaging to characterize the spatio‐temporal dynamics of inhibitory control in the time‐frequency domain. Results: Successful response inhibition (NoGo) elicited right‐lateralized event‐related theta power (4 to 7 Hz). Errors elicited a short‐latency increase in theta power in the dorsal (dACC), followed by activity in the rostral (rACC), which may underlie an affective "oh, no!" orienting response to errors. Error‐related theta in the dACC was associated with subsequent activity of the motor areas on the first post‐error trial, suggesting the occurrence of post‐error output adjustments. Importantly, a gradual increase of the dACC theta across post‐error trials closely tracked improvements in accuracy under placebo, which may reflect cognitive control engagement to optimize response accuracy. In contrast, alcohol increased NoGo commission errors, dysregulated theta during correct NoGo withholding, and abolished the post‐error theta enhancement of cognitive control. Conclusions: Confirming the sensitivity of frontal theta to inhibitory control and error monitoring, the results support functional and temporal dissociation along the dorso‐rostral axis of the ACC and the deleterious effects of alcohol on the frontal circuitry subserving top‐down regulation. Over time, alcohol‐induced disinhibition may give rise to compulsive drinking and contribute to alcohol misuse. [ABSTRACT FROM AUTHOR]

Published
2022
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15. An estimation of the absolute number of axons indicates that human cortical areas are sparsely connected.

Author

Rosen, Burke Q. and Halgren, Eric

Subjects
*DIFFUSION magnetic resonance imaging, *AXONS, *INFORMATION processing
Abstract

The tracts between cortical areas are conceived as playing a central role in cortical information processing, but their actual numbers have never been determined in humans. Here, we estimate the absolute number of axons linking cortical areas from a whole-cortex diffusion MRI (dMRI) connectome, calibrated using the histologically measured callosal fiber density. Median connectivity is estimated as approximately 6,200 axons between cortical areas within hemisphere and approximately 1,300 axons interhemispherically, with axons connecting functionally related areas surprisingly sparse. For example, we estimate that <5% of the axons in the trunk of the arcuate and superior longitudinal fasciculi connect Wernicke's and Broca's areas. These results suggest that detailed information is transmitted between cortical areas either via linkage of the dense local connections or via rare, extraordinarily privileged long-range connections. Using data from Human Connectome Project to estimate the absolute number of axons linking cortical areas yields surprisingly sparse connectivity; reconciling large-scale functional synchronization with sparse anatomical connectivity presents a challenge for our present understanding of human brain organization. [ABSTRACT FROM AUTHOR]

Published
2022
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16. Compensatory neuroadaptation to binge drinking: Human evidence for allostasis.

Author

Correas, Angeles, Cuesta, Pablo, Rosen, Burke Q., Maestu, Fernando, and Marinkovic, Ksenija

Subjects
BINGE drinking, ALCOHOLISM, NEURAL inhibition, ALCOHOLIC intoxication, YOUNG adults
Abstract

Animal studies have established that acute alcohol increases neural inhibition and that frequent intoxication episodes elicit neuroadaptive changes in the excitatory/inhibitory neurotransmission balance. To compensate for the depressant effects of alcohol, neural hyperexcitability develops in alcohol use disorder and is manifested through withdrawal symptoms. It is unclear, however, whether neuroadaptive changes can be observed in young, emerging adults at lower levels of consumption in the absence of withdrawal symptoms. Here, we used an anatomically constrained magnetoencephalography method to assess cortical excitability in two independent sets of experiments. We measured early visual activity (1) in social drinkers during alcohol intoxication versus placebo conditions and (2) in parallel cohorts of sober binge drinkers (BDs) and light drinkers (LDs). Acute alcohol intoxication attenuated early sensory activity in the visual cortex in social drinkers, confirming its inhibitory effects on neurotransmission. In contrast, sober BDs showed greater neural responsivity compared with a matched group of LDs. A positive correlation between alcohol consumption and neural activity in BDs is indicative of cortical hyperexcitability associated with hazardous drinking. Furthermore, neural responsivity was positively correlated with alcohol intake in social drinkers whose drinking did not reach binge levels. This study provides novel evidence of compensatory imbalance reflected in the downregulation of inhibitory and upregulation of excitatory signaling associated with binge drinking in young, emerging adults. By contrasting acute effects and a history of BD, these results support the mechanistic model of allostasis. Direct neural measures are sensitive to synaptic currents and could serve as biomarkers of neuroadaptation. [ABSTRACT FROM AUTHOR]

Published
2021
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17. 1/f neural noise is a better predictor of schizophrenia than neural oscillations

Author

Peterson, Erik J., Rosen, Burke Q., Campbell, Alana M., Belger, Aysenil, and Voytek, Bradley

Subjects
mental disorders
Abstract

Schizophrenia has been associated with separate irregularities in several neural oscillatory frequency bands, including theta, alpha, and gamma. Our multivariate classification of human EEG suggests that instead of irregularities in many frequency bands, schizophrenia-related electrophysiological differences may better be explained by an overall shift in neural noise, reflected by a change in the 1/f slope of the power spectrum. Significance statement Understanding the neurobiological origins of schizophrenia, and identifying reliable biomarkers, are both of critical importance in improving treatment of that disease. While we lack predictive biomarkers, numerous studies have observed disruptions to neural oscillations in schizophrenia patients. This literature has, in part, lead to schizophrenia being characterized as disease of disrupted neural coordination. We report however that changes to background noise (i.e., 1/f noise) are a substantially better predictor of schizophrenia than both oscillatory power and participants own behavioral performance. The observed alterations in neural noise are consistent with inhibitory neuron dysfunctions associated with schizophrenia, allowing for a direct link between noninvasive EEG and neurobiological deficits.

Published
2017
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19. Theta Bursts Precede, and Spindles Follow, Cortical and Thalamic Downstates in Human NREM Sleep.

Author

Gonzalez, Christopher E., Mak-McCully, Rachel A., Rosen, Burke Q., Cash, Sydney S., Chauvel, Patrick Y., Bastuji, Helene, Rey, Marc, and Halgren, Eric

Subjects
NON-REM sleep, SLEEP, ELECTROPHYSIOLOGY, THALAMUS
Abstract

Since their discovery, slow oscillations have been observed to group spindles during non-REM sleep. Previous studies assert that the slow-oscillation downstate (DS) is preceded by slow spindles (10-12 Hz) and followed by fast spindles (12-16 Hz). Here, using both direct transcortical recordings in patients with intractable epilepsy (ti = 10,8 female), as well as scalp EEG recordings from a healthy cohort (n = 3, 1 female), we find in multiple cortical areas that both slow and fast spindles follow the DS. Although discrete oscillations do precede DSs, they are theta bursts (TBs) centered at 5-8 Hz. TBs were more pronounced for DSs in NREM stage 2 (N2) sleep compared with N3. TB with similar properties occur in the thalamus, but unlike spindles they have no clear temporal relationship with cortical TB. I hese differences in corticothalamic dynamics, as well as differences between spindles and theta in coupling high-frequency content, are consistent with N REM theta having separate generative mechanisms from spindles. The final inhibitory cycle of the TB coincides with the DS peak, suggesting that in N2, 1B may help trigger the DS. Since the transition to N1 is marked by the appearance of theta, and the transition to N2 by the appearance of DS and thus spindles, a role of TB in triggering DS could help explain the sequence of electrophysiological events characterizing sleep. Finally, the coordinated appearance ot spindles and DSs are implicated in memory consolidation processes, and the current findings redefine their temporal coupling with theta during NREM sleep. [ABSTRACT FROM AUTHOR]

Published
2018
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20. Thalamocortical and intracortical laminar connectivity determines sleep spindle properties.

Author

Krishnan, Giri P., Rosen, Burke Q., Chen, Jen-Yung, Muller, Lyle, Sejnowski, Terrence J., Cash, Sydney S., Halgren, Eric, and Bazhenov, Maxim

Subjects
*NON-REM sleep, *SLEEP spindles, *MAGNETOENCEPHALOGRAPHY, *ELECTROENCEPHALOGRAPHY, *THALAMOCORTICAL system, *EXCITATION (Physiology), *PHENOTYPIC plasticity
Abstract

Sleep spindles are brief oscillatory events during non-rapid eye movement (NREM) sleep. Spindle density and synchronization properties are different in MEG versus EEG recordings in humans and also vary with learning performance, suggesting spindle involvement in memory consolidation. Here, using computational models, we identified network mechanisms that may explain differences in spindle properties across cortical structures. First, we report that differences in spindle occurrence between MEG and EEG data may arise from the contrasting properties of the core and matrix thalamocortical systems. The matrix system, projecting superficially, has wider thalamocortical fanout compared to the core system, which projects to middle layers, and requires the recruitment of a larger population of neurons to initiate a spindle. This property was sufficient to explain lower spindle density and higher spatial synchrony of spindles in the superficial cortical layers, as observed in the EEG signal. In contrast, spindles in the core system occurred more frequently but less synchronously, as observed in the MEG recordings. Furthermore, consistent with human recordings, in the model, spindles occurred independently in the core system but the matrix system spindles commonly co-occurred with core spindles. We also found that the intracortical excitatory connections from layer III/IV to layer V promote spindle propagation from the core to the matrix system, leading to widespread spindle activity. Our study predicts that plasticity of intra- and inter-cortical connectivity can potentially be a mechanism for increased spindle density as has been observed during learning. [ABSTRACT FROM AUTHOR]

Published
2018
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21. Synchronization of Isolated Downstates (K-Complexes) May Be Caused by Cortically-Induced Disruption of Thalamic Spindling.

Author

Mak-McCully, Rachel A., Deiss, Stephen R., Rosen, Burke Q., Jung, Ki-Young, Sejnowski, Terrence J., Bastuji, Hélène, Rey, Marc, Cash, Sydney S., Bazhenov, Maxim, and Halgren, Eric

Subjects
COMPUTATIONAL biology, COMPUTATIONAL neuroscience, SENSORY neurons, PYRAMIDAL neurons, THALAMOCORTICAL system, LABORATORY monkeys
Abstract

Sleep spindles and K-complexes (KCs) define stage 2 NREM sleep (N2) in humans. We recently showed that KCs are isolated downstates characterized by widespread cortical silence. We demonstrate here that KCs can be quasi-synchronous across scalp EEG and across much of the cortex using electrocorticography (ECOG) and localized transcortical recordings (bipolar SEEG). We examine the mechanism of synchronous KC production by creating the first conductance based thalamocortical network model of N2 sleep to generate both spontaneous spindles and KCs. Spontaneous KCs are only observed when the model includes diffuse projections from restricted prefrontal areas to the thalamic reticular nucleus (RE), consistent with recent anatomical findings in rhesus monkeys. Modeled KCs begin with a spontaneous focal depolarization of the prefrontal neurons, followed by depolarization of the RE. Surprisingly, the RE depolarization leads to decreased firing due to disrupted spindling, which in turn is due to depolarization-induced inactivation of the low-threshold Ca2+ current (IT). Further, although the RE inhibits thalamocortical (TC) neurons, decreased RE firing causes decreased TC cell firing, again because of disrupted spindling. The resulting abrupt removal of excitatory input to cortical pyramidal neurons then leads to the downstate. Empirically, KCs may also be evoked by sensory stimuli while maintaining sleep. We reproduce this phenomenon in the model by depolarization of either the RE or the widely-projecting prefrontal neurons. Again, disruption of thalamic spindling plays a key role. Higher levels of RE stimulation also cause downstates, but by directly inhibiting the TC neurons. SEEG recordings from the thalamus and cortex in a single patient demonstrated the model prediction that thalamic spindling significantly decreases before KC onset. In conclusion, we show empirically that KCs can be widespread quasi-synchronous cortical downstates, and demonstrate with the first model of stage 2 NREM sleep a possible mechanism whereby this widespread synchrony may arise. [ABSTRACT FROM AUTHOR]

Published
2014
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22. Oscillatory spatial profile of alcohol's effects on the resting state: Anatomically-constrained MEG.

Author

Rosen, Burke Q., O'Hara, Ryan, Kovacevic, Sanja, Schulman, Andrew, Padovan, Nevena, and Marinkovic, Ksenija

Subjects
*PHYSIOLOGICAL effects of alcohol, *OSCILLATIONS, *ELECTROENCEPHALOGRAPHY, *MAGNETOENCEPHALOGRAPHY, *WAKEFULNESS, *BIOMARKERS, *BRAIN physiology
Abstract

It has been firmly established that opening and closing the eyes strongly modulate the electro- and magnetoencephalography (EEG and MEG) signals acquired during wakeful rest. Certain features of the resting EEG are altered in chronic alcoholics and their offspring, and have been proposed as biomarkers for alcoholism. Spontaneous brain oscillations are also affected by pharmacological manipulations, but the spectral and spatial characteristics of these changes are not clear. This study examined effects of the eyes-open (EO) and eyes-closed (EC) resting paradigm and alcohol challenge on the spatial profile of spontaneous MEG and EEG oscillations. Whole-head MEG and scalp EEG signals were acquired simultaneously from healthy social drinkers (n = 17) who participated in both alcohol (0.6 g/kg ethanol for men, 0.55 g/kg for women) and placebo conditions in a counterbalanced design. Power of the signal was calculated with Fast Fourier Transform and was decomposed into its constituent theta (4e7 Hz), alpha (8 e12 Hz), and beta (15e20 Hz) frequency bands. High-resolution structural MRI images were additionally obtained from all participants and used to constrain distributed minimum norm inverse source power estimates. The spatial estimates of the main generator nodes were in agreement with studies using a combined fMRI-EEG approach. Alpha band oscillations dominated the spectral profile and their source was estimated to the medial parieto-occipital area. Power in theta and beta bands was weaker overall and their sources were estimated to a more focal medial prefrontal area. EO and EC manipulation most strongly modulated power in the alpha band, but a wide-band power increase was observed during the EC condition. Alcohol intoxication increased alpha power, particularly during the EC condition. Application of this methodology to cohorts of chronic alcoholics or individuals at risk could potentially provide insight into the neural basis of oscillatory differences that may be predictive of the vulnerability to alcoholism. [ABSTRACT FROM AUTHOR]

Published
2014
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23. Distribution, Amplitude, Incidence, Co-Occurrence, and Propagation of Human K-Complexes in Focal Transcortical Recordings1,2,3

Author

Mak-McCully, Rachel A., Rosen, Burke Q., Rolland, Matthieu, Régis, Jean, Bartolomei, Fabrice, Rey, Marc, Chauvel, Patrick, Cash, Sydney S., and Halgren, Eric

Subjects
Integrative Systems, depth recordings, k-complex, memory, SEEG, sleep
Abstract

K-complexes (KCs) are thought to play a key role in sleep homeostasis and memory consolidation; however, their generation and propagation remain unclear. The commonly held view from scalp EEG findings is that KCs are primarily generated in medial frontal cortex and propagate parietally, whereas an electrocorticography (ECOG) study suggested dorsolateral prefrontal generators and an absence of KCs in many areas. In order to resolve these differing views, we used unambiguously focal bipolar depth electrode recordings in patients with intractable epilepsy to investigate spatiotemporal relationships of human KCs. KCs were marked manually on each channel, and local generation was confirmed with decreased gamma power. In most cases (76%), KCs occurred in a single location, and rarely (1%) in all locations. However, if automatically detected KC-like phenomena were included, only 15% occurred in a single location, and 27% occurred in all recorded locations. Locally generated KCs were found in all sampled areas, including cingulate, ventral temporal, and occipital cortices. Surprisingly, KCs were smallest and occurred least frequently in anterior prefrontal channels. When KCs occur on two channels, their peak order is consistent in only 13% of cases, usually from prefrontal to lateral temporal. Overall, the anterior–posterior separation of electrode pairs explained only 2% of the variance in their latencies. KCs in stages 2 and 3 had similar characteristics. These results open a novel view where KCs overall are universal cortical phenomena, but each KC may variably involve small or large cortical regions and spread in variable directions, allowing flexible and heterogeneous contributions to sleep homeostasis and memory consolidation.

Published
2015
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24. Emergent effects of synaptic connectivity on the dynamics of global and local slow waves in a large-scale thalamocortical network model of the human brain.

Author

Marsh BM, Navas-Zuloaga MG, Rosen BQ, Sokolov Y, Delanois JE, González OC, Krishnan GP, Halgren E, and Bazhenov M

Abstract

Slow-wave sleep (SWS), characterized by slow oscillations (SO, <1Hz) of alternating active and silent states in the thalamocortical network, is a primary brain state during Non-Rapid Eye Movement (NREM) sleep. In the last two decades, the traditional view of SWS as a global and uniform whole-brain state has been challenged by a growing body of evidence indicating that SO can be local and can coexist with wake-like activity. However, the understanding of how global and local SO emerges from micro-scale neuron dynamics and network connectivity remains unclear. We developed a multi-scale, biophysically realistic human whole-brain thalamocortical network model capable of transitioning between the awake state and slow-wave sleep, and we investigated the role of connectivity in the spatio-temporal dynamics of sleep SO. We found that the overall strength and a relative balance between long and short-range synaptic connections determined the network state. Importantly, for a range of synaptic strengths, the model demonstrated complex mixed SO states, where periods of synchronized global slow-wave activity were intermittent with the periods of asynchronous local slow-waves. Increase of the overall synaptic strength led to synchronized global SO, while decrease of synaptic connectivity produced only local slow-waves that would not propagate beyond local area. These results were compared to human data to validate probable models of biophysically realistic SO. The model producing mixed states provided the best match to the spatial coherence profile and the functional connectivity estimated from human subjects. These findings shed light on how the spatio-temporal properties of SO emerge from local and global cortical connectivity and provide a framework for further exploring the mechanisms and functions of SWS in health and disease.

Published
2024
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25. Modular Phoneme Processing in Human Superior Temporal Gyrus.

Author

Cleary DR, Tchoe Y, Bourhis A, Dickey CW, Stedelin B, Ganji M, Lee SH, Lee J, Siler DA, Brown EC, Rosen BQ, Kaestner E, Yang JC, Soper DJ, Han SJ, Paulk AC, Cash SS, Raslan AMT, Dayeh SA, and Halgren E

Abstract

Modular organization is fundamental to cortical processing, but its presence is human association cortex is unknown. We characterized phoneme processing with 128-1024 channel micro-arrays at 50-200µm pitch on superior temporal gyrus of 7 patients. High gamma responses were highly correlated within ~1.7mm diameter modules, sharply delineated from adjacent modules with distinct time-courses and phoneme-selectivity. We suggest that receptive language cortex may be organized in discrete processing modules.

Published
2024
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26. A Whole-Cortex Probabilistic Diffusion Tractography Connectome.

Author

Rosen BQ and Halgren E

Subjects
Brain diagnostic imaging, Diffusion Magnetic Resonance Imaging, Diffusion Tensor Imaging, Humans, Magnetic Resonance Imaging, Connectome
Abstract

The WU-Minn Human Connectome Project (HCP) is a publicly-available dataset containing state-of-the-art structural magnetic resonance imaging (MRI), functional MRI (fMRI), and diffusion MRI (dMRI) for over a thousand healthy subjects. While the planned scope of the HCP included an anatomic connectome, resting-state fMRI (rs-fMRI) forms the bulk of the HCP's current connectomic output. We address this by presenting a full-cortex connectome derived from probabilistic diffusion tractography and organized into the HCP-MMP1.0 atlas. Probabilistic methods and large sample sizes are preferable for whole-connectome mapping as they increase the fidelity of traced low-probability connections. We find that overall, connection strengths are lognormally distributed and decay exponentially with tract length, that connectivity reasonably matches macaque histologic tracing in homologous areas, that contralateral homologs and left-lateralized language areas are hyperconnected, and that hierarchical similarity influences connectivity. We compare the dMRI connectome to existing rs-fMRI and cortico-cortico-evoked potential connectivity matrices and find that it is more similar to the latter. This work helps fulfill the promise of the HCP and will make possible comparisons between the underlying structural connectome and functional connectomes of various modalities, brain states, and clinical conditions., (Copyright © 2021 Rosen and Halgren.)

Published
2021
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27. Disruption of Frontal Lobe Neural Synchrony During Cognitive Control by Alcohol Intoxication.

Author

Marinkovic K, Beaton LE, Rosen BQ, Happer JP, and Wagner LC

Subjects
Adult, Brain diagnostic imaging, Brain drug effects, Brain Mapping methods, Cognition drug effects, Female, Frontal Lobe diagnostic imaging, Frontal Lobe drug effects, Humans, Magnetic Resonance Imaging methods, Magnetoencephalography methods, Male, Prefrontal Cortex diagnostic imaging, Prefrontal Cortex drug effects, Psychomotor Performance, Alcoholic Intoxication physiopathology, Brain physiopathology, Central Nervous System Depressants adverse effects, Cognition physiology, Ethanol adverse effects, Frontal Lobe physiopathology, Prefrontal Cortex physiopathology
Abstract

Decision making relies on dynamic interactions of distributed, primarily frontal brain regions. Extensive evidence from functional magnetic resonance imaging (fMRI) studies indicates that the anterior cingulate (ACC) and the lateral prefrontal cortices (latPFC) are essential nodes subserving cognitive control. However, because of its limited temporal resolution, fMRI cannot accurately reflect the timing and nature of their presumed interplay. The present study combines distributed source modeling of the temporally precise magnetoencephalography (MEG) signal with structural MRI in the form of "brain movies" to: (1) estimate the cortical areas involved in cognitive control ("where"), (2) characterize their temporal sequence ("when"), and (3) quantify the oscillatory dynamics of their neural interactions in real time. Stroop interference was associated with greater event-related theta (4 - 7 Hz) power in the ACC during conflict detection followed by sustained sensitivity to cognitive demands in the ACC and latPFC during integration and response preparation. A phase-locking analysis revealed co-oscillatory interactions between these areas indicating their increased neural synchrony in theta band during conflict-inducing incongruous trials. These results confirm that theta oscillations are fundamental to long-range synchronization needed for integrating top-down influences during cognitive control. MEG reflects neural activity directly, which makes it suitable for pharmacological manipulations in contrast to fMRI that is sensitive to vasoactive confounds. In the present study, healthy social drinkers were given a moderate alcohol dose and placebo in a within-subject design. Acute intoxication attenuated theta power to Stroop conflict and dysregulated co-oscillations between the ACC and latPFC, confirming that alcohol is detrimental to neural synchrony subserving cognitive control. It interferes with goal-directed behavior that may result in deficient self-control, contributing to compulsive drinking. In sum, this method can provide insight into real-time interactions during cognitive processing and can characterize the selective sensitivity to pharmacological challenge across relevant neural networks.

Published
2019
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28. Event-Related Theta Power during Lexical-Semantic Retrieval and Decision Conflict is Modulated by Alcohol Intoxication: Anatomically Constrained MEG.

Author

Marinkovic K, Rosen BQ, Cox B, and Kovacevic S

Abstract

Language processing is commonly characterized by an event-related increase in theta power (4-7 Hz) in scalp EEG. Oscillatory brain dynamics underlying alcohol's effects on language are poorly understood despite impairments on verbal tasks. To investigate how moderate alcohol intoxication modulates event-related theta activity during visual word processing, healthy social drinkers (N = 22, 11 females) participated in both alcohol (0.6 g/kg ethanol for men, 0.55 g/kg for women) and placebo conditions in a counterbalanced design. They performed a double-duty lexical decision task as they detected real words among non-words. An additional requirement to respond to all real words that also referred to animals induced response conflict. High density whole-head MEG signals and midline scalp EEG data were decomposed for each trial with Morlet wavelets. Each person's reconstructed cortical surface was used to constrain noise-normalized distributed minimum norm inverse solutions for theta frequencies. Alcohol intoxication increased reaction time and marginally affected accuracy. The overall spatio-temporal pattern is consistent with the left-lateralized fronto-temporal activation observed in language studies applying time-domain analysis. Event-related theta power was sensitive to the two functions manipulated by the task. First, theta estimated to the left-lateralized fronto-temporal areas reflected lexical-semantic retrieval, indicating that this measure is well suited for investigating the neural basis of language functions. While alcohol attenuated theta power overall, it was particularly deleterious to semantic retrieval since it reduced theta to real words but not pseudowords. Second, a highly overlapping prefrontal network comprising lateral prefrontal and anterior cingulate cortex was sensitive to decision conflict and was also affected by intoxication, in agreement with previous studies indicating that executive functions are especially vulnerable to alcohol intoxication.

Published
2012
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