Your search keyword '"Oostenveld, Robert"' showing total 10 results

1. The Time Course of Language Production as Revealed by Pattern Classification of MEG Sensor Data.

Author

Carota, Francesca, Schoffelen, Jan-Mathijs, Oostenveld, Robert, and Indefrey, Peter

Subjects

STIMULUS & response (Biology), SYLLABLE (Grammar), PHONETICS, DETECTORS, CLASSIFICATION, LANGUAGE & languages, MULTIVARIATE analysis

Abstract

Language production involves a complex set of computations, from conceptualization to articulation, which are thought to engage cascading neural events in the language network. However, recent neuromagnetic evidence suggests simultaneous meaning-to-speech mapping in picture naming tasks, as indexed by early parallel activation of frontotemporal regions to lexical semantic, phonological, and articulatory information. Here we investigate the time course of word production, asking to what extent such "earliness" is a distinctive property of the associated spatiotemporal dynamics. Using MEG, we recorded the neural signals of 34 human subjects (26 males) overtly naming 134 images from four semantic object categories (animals, foods, tools, clothes). Within each category, we covaried word length, as quantified by the number of syllables contained in a word, and phonological neighborhood density to target lexical and post-lexical phonological/phonetic processes. Multivariate pattern analyses searchlights in sensor space distinguished the stimulus-locked spatiotemporal responses to object categories early on, from 150 to 250 ms after picture onset, whereas word length was decoded in left frontotemporal sensors at 250-350 ms, followed by the latency of phonological neighborhood density (350-450 ms). Our results suggest a progression of neural activity from posterior to anterior language regions for the semantic and phonological/phonetic computations preparing overt speech, thus supporting serial cascading models of word production. [ABSTRACT FROM AUTHOR]

Published

2022

2. Separating Visual and Motor Components of Motor Cortex Activation for Multiple Reach Targets: A Visuomotor Adaptation Study.

Author

Grent-'t-Jong, Tineke, Oostenveld, Robert, Pieter Medendorp, W., and Praamstra, Peter

Subjects

*MOTOR cortex, *VISUOMOTOR coordination, *SENSORIMOTOR cortex, *BRAIN physiology, *OSCILLATING chemical reactions

Abstract

Ethologically inspired models of movement preparation view the sensorimotor system as sampling information from the environment in a parallel fashion in preparation for multiple potential actions. In support, the configuration of the physical workspace, manipulated by the number or spatial separation of potential targets, has been shown to modulate sensorimotor neural activity. It is unclear, however, whether this modulation is driven by the sensory layout of the workspace or through the associated motor plans. Here, we combine a delayed-movement pre-cuing task with visuomotor adaptation to address this question in human subjects while recording MEG. By dissociating visual and motor coordinates of two targets using visuomotor adaptation, the task was designed to evaluate, in a selective fashion, the effects of visual and movement target separation on movement preparatory activity. The results did not allow the intended comparison due to an unanticipated effect of the direction of visuomotor adaptation on baseline oscillatory power in beta and lowgammabands. Fortuitously, this effect was dependent on whether the adaptation direction decreased or increased the angular separation between alternative movements. That is, there was a sustained reduction of oscillatory power, which was stronger at small compared with large target separation. These results support a direct influence of movement target separation on motor cortex neural activity, mediated by lateral interactions between simultaneously active motor plans. The results further demonstrate a novel effect of visuomotor adaptation on motor cortex oscillatory activity, with properties that support the local nature of learned changes in visuomotor mapping. [ABSTRACT FROM AUTHOR]

Published

2015

3. Reduced Occipital Alpha Power Indexes Enhanced Excitability Rather than Improved Visual Perception.

Author

Lange, Joachim, Oostenveld, Robert, and Fries, Pascal

Subjects

*OCCIPITAL lobe, *VISUAL perception, *STIMULUS & response (Biology), *THRESHOLD (Perception), *NEUROSCIENCES, *VISUAL discrimination, *NEURAL circuitry, *NEUROLOGY

Abstract

Several studies have demonstrated that prestimulus occipital alpha-band activity substantially influences subjective perception and discrimination of near-threshold or masked visual stimuli. Here, we studied the role of prestimulus power fluctuations in two visual phenomena called double-flash illusion (DFI) and fusion effect (FE), both consisting of suprathreshold stimuli. In both phenomena, human subjects' perception varies on a trial-by-trial basis between perceiving one or two visual stimuli, despite constant stimulation. In the FE, two stimuli correspond to veridical perception. In the DFI, two stimuli correspond to an illusory perception. This provides for a critical test of whether reduced alpha power indeed promotes veridical perception in general. We find that in both, DFI and FE, reduced prestimulus occipital alpha predicts the perception of two stimuli, regardless of whether this is veridical (FE) or illusory (DFI). Our results suggest that reduced alpha-band power does not always predict improved visual processing, but rather enhanced excitability. In addition, for the DFI, enhanced prestimulus occipital gamma-band power predicted the perception of two visual stimuli. These findings provide new insights into the role of prestimulus rhythmic activity for visual processing. [ABSTRACT FROM AUTHOR]

Published

2013

4. Movement-Related Changes in Local and Long-Range Synchronization in Parkinson's Disease Revealed by Simultaneous Magnetoencephalography and Intracranial Recordings.

Author

Litvak, Vladimir, Eusebio, Alexandre, Jha, Ashwani, Oostenveld, Robert, Barnes, Gareth, Foltynie, Tom, Limousin, Patricia, Zrinzo, Ludvic, Hariz, Marwan I., Friston, Karl, and Brown, Peter

Subjects

SYNCHRONIZATION, PARKINSON'S disease, MAGNETOENCEPHALOGRAPHY, NEUROSURGERY, CEREBRAL cortex, BASAL ganglia, DOPA, PRODRUGS

Abstract

Functional neurosurgery has afforded the opportunity to assess interactions between populations of neurons in the human cerebral cortex and basal ganglia in patients with Parkinson's disease (PD). Interactions occur over a wide range of frequencies, and the functional significance of those >30 Hz is particularly unclear. Do they improve movement, and, if so, in what way? We acquired simultaneously magnetoencephalography and direct recordings from the subthalamic nucleus (STN) in 17 PD patients. We examined the effect of synchronous and sequential finger movements and of the dopamine prodrug levodopa on induced power in the contralateral primary motor cortex (Ml ) and STN and on the coherence between the two structures. We observed discrete peaks in Ml and STN power at 60 -90 Hz and at 300 - 400 Hz. All these power peaks increased with movement and levodopa treatment. Only STN activity at 60 -90 Hz was coherent with activity in Ml. Directionality analysis showed that STN gamma activity at 60 -90 Hz tended to drive gamma activity in Ml. The effects of levodopa on both local and distant synchronization at 60 -90 Hz correlated with the degree of improvement in bradykinesia-rigidity as did local STN activity at 300 - 400 Hz. Despite this, there were no effects of movement type, nor interactions between movement type and levodopa in the STN, nor in the coherence between STN and Ml. We conclude that synchronization at 60-90 Hz in the basal ganglia cortical network is prokinetic but likely through a modulatory effect rather than any involvement in explicit motor processing. [ABSTRACT FROM AUTHOR]

Published

2012

5. Selective Movement Preparation Is Subserved by Selective Increases in Corticomuscular Gamma-Band Coherence.

Author

Schoffelen, Jan-Mathijs, Poort, Jasper, Oostenveld, Robert, and Fries, Pascal

Subjects

MAGNETOENCEPHALOGRAPHY, CENTRAL nervous system, MOTOR ability, BRAIN magnetic fields measurement, SYNCHRONIZATION, CEREBRAL cortex

Abstract

Local groups of neurons engaged in a cognitive task often exhibit rhythmically synchronized activity in the gamma band, a phenomenon that likely enhances their impact on downstream areas. The efficacy of neuronal interactions may be enhanced further by interareal synchronization of these local rhythms, establishing mutually well timed fluctuations in neuronal excitability. This notion suggests that long-range synchronization is enhanced selectively for connections that are behaviorally relevant. We tested this prediction in the human motor system, assessing activity from bilateral motor cortices with magnetoencephalography and corresponding spinal activity through electromyography of bilateral hand muscles. A bimanual isometric wrist extension task engaged the two motor cortices simultaneously into interactions and coherence with their respective corresponding contralateral hand muscles. One of the hands was cued before each trial as the response hand and had to be extended further to report an unpredictable visual go cue. We found that, during the isometric hold phase, corticomuscular coherence was enhanced, spatially selective for the corticospinal connection that was effectuating the subsequent motor response. This effect was spectrally selective in the low gamma-frequency band (40-47 Hz) and was observed in the absence of changes in motor output or changes in local cortical gamma-band synchronization. These findings indicate that, in the anatomical connections between the cortex and the spinal cord, gamma-band synchronization is a mechanism that may facilitate behaviorally relevant interactions between these distant neuronal groups. [ABSTRACT FROM AUTHOR]

Published

2011

6. Gamma-Phase Shifting in Awake Monkey Visual Cortex.

Author

Vinck, Martin, Lima, Bruss, Womelsdorf, Thilo, Oostenveld, Robert, Singer, Wolf, Neuenschwander, Sergio, and Fries, Pascal

Subjects

GAMMA functions, VISUAL cortex, OCCIPITAL lobe, NEURONS, NERVOUS system

Abstract

Gamma-band synchronization is abundant in nervous systems. Typically, the strength or precision of gamma-band synchronization is studied. However, the precise phase with which individual neurons are synchronized to the gamma-band rhythm might have interesting consequences for their impact on further processing and for spike timing-dependent plasticity. Therefore, we investigated whether the spike times of individual neurons shift systematically in the gamma cycle as a function of the neuronal activation strength. We found that stronger neuronal activation leads to spikes earlier in the gamma cycle, i.e., we observed gamma-phase shifting. Gamma-phase shifting occurred on very rapid time scales. It was particularly pronounced for periods in which gamma-band synchronization was relatively weak and for neurons that were only weakly coupled to the gamma rhythm. We suggest that gamma-phase shifting is brought about by an interplay between overall excitation and gamma rhythmic synaptic input and has interesting consequences for neuronal coding, competition, and plasticity. [ABSTRACT FROM AUTHOR]

Published

2010

7. The Effects of Visual Stimulation and Selective Visual Attention on Rhythmic Neuronal Synchronization in Macaque Area V4.

Author

Fries, Pascal, Womelsdorf, Thilo, Oostenveld, Robert, and Desimone, Robert

Subjects

VISUAL evoked response, SYNCHRONIZATION, NEURAL physiology, VISUAL learning, MACAQUES

Abstract

Selective attention lends relevant sensory input priority access to higher-level brain areas and ultimately to behavior. Recent studies have suggested that those neurons in visual areas that are activated by an attended stimulus engage in enhanced gamma-band (30 -70 Hz) synchronization compared with neurons activated by a distracter. Such precise synchronization could enhance the postsynaptic impact of cells carrying behaviorally relevant information. Previous studies have used the local field potential (LFP) power spectrum or spike-LFP coherence (SFC) to indirectly estimate spike synchronization. Here, we directly demonstrate zero-phase gamma-band coherence among spike trains of V4 neurons. This synchronization was particularly evident during visual stimulation and enhanced by selective attention, thus confirming the pattern inferred from LFP power and SFC. We therefore investigated the time course of LFP gamma-band power and found rapid dynamics consistent with interactions of top-down spatial and feature attention with bottom-up saliency. In addition to the modulation of synchronization during visual stimulation, selective attention significantly changed the prestimulus pattern of synchronization. Attention inside the receptive field of the recorded neuronal population enhanced gamma-band synchronization and strongly reduced α-band (9 -11 Hz) synchronization in the prestimulus period. These results lend further support for a functional role of rhythmic neuronal synchronization in attentional stimulus selection. [ABSTRACT FROM AUTHOR]

Published

2008

8. Prestimulus Oscillatory Activity in the Alpha Band Predicts Visual Discrimination Ability.

Author

Van Dijk, Hanneke, Schoffelen, Jan-Mathijs, Oostenveld, Robert, and Jensen, Ole

Subjects

OSCILLATIONS, ALPHA rhythm, VISUAL discrimination, VISUAL perception, BRAIN physiology

Abstract

Although the resting and baseline states of the human electroencephalogram and magnetoencephalogram (MEG) are dominated by oscillations in the alpha band (~10 Hz), the functional role of these oscillations remains unclear. In this study we used MEG to investigate how spontaneous oscillations in humans presented before visual stimuli modulate visual perception. Subjects had to report if there was a subtle difference in gray levels between two superimposed presented discs. We then compared the prestimulus brain activity for correctly (hits) versus incorrectly (misses) identified stimuli. We found that visual discrimination ability decreased with an increase in prestimulus alpha power. Given that reaction times did not vary systematically with prestimulus alpha power changes in vigilance are not likely to explain the change in discrimination ability. Source reconstruction using spatial filters allowed us to identify the brain areas accounting for this effect. The dominant sources modulating visual perception were localized around the parieto-occipital sulcus. We suggest that the parieto-occipital alpha power reflects functional inhibition imposed by higher level areas, which serves to modulate the gain of the visual stream. [ABSTRACT FROM AUTHOR]

Published

2008

9. Tactile Spatial Attention Enhances Gamma-Band Activity in Somatosensory Cortex and Reduces Low-Frequency Activity in Parieto-Occipital Areas.

Author

Bauer, Markus, Oostenveld, Robert, Peeters, Maarten, and Fries, Pascal

Subjects

*NEURONS, *BRAIN, *CEREBRAL cortex, *OCCIPITAL lobe, *NERVOUS system

Abstract

We investigated the effects of spatial-selective attention on oscillatory neuronal dynamics in a tactile delayed-match-to-sample task. Whole-head magnetoencephalography was recorded in healthy subjects while dot patterns were presented to their index fingers using Braille stimulators. The subjects' task was to report the reoccurrence of an initially presented sample pattern in a series of up to eight test stimuli that were presented unpredictably to their right or left index finger. Attention was cued to one side (finger) at the beginning of each trial, and subjects performed the task at the attended side, ignoring the unattended side. After stimulation, high-frequency gamma-band activity (60-95 Hz) in presumed primary somatosensory cortex (S1) was enhanced, whereas alpha- and beta-band activity were suppressed in somatosensory and occipital areas and then rebounded. Interestingly, despite the absence of any visual stimulation, we also found time-locked activation of medial occipital, presumably visual, cortex. Most relevant, spatial tactile attention enhanced stimulus-induced gamma-band activity in brain regions consistent with contralateral S1 and deepened and prolonged the stimulus induced suppression of beta- and alpha-band activity, maximal in parieto-occipital cortex. Additionally, the beta rebound over contralateral sensorimotor areas was suppressed. We hypothesize that spatial-selective attention enhances the saliency of sensory representations by synchronizing neuronal responses in early somatosensory cortex and thereby enhancing their impact on downstream areas and facilitating interareal processing. Furthermore, processing of tactile patterns also seems to recruit visual cortex and this even more so for attended compared with unattended stimuli. [ABSTRACT FROM AUTHOR]

Published

2006

10. Theta and Gamma Oscillations Predict Encoding and Retrieval of Declarative Memory.

Author

Osipova, Daria, Takashima, Atsuko, Oostenveld, Robert, Fernández, Guillén, Maris, Eric, and Jensen, Ole

Subjects

OSCILLATING chemical reactions, MNEMONICS, SHORT-term memory, MAGNETOENCEPHALOGRAPHY, ELECTROENCEPHALOGRAPHY

Abstract

Although studies in animals and patients have demonstrated that brain oscillations play a role in declarative memory encoding and retrieval, little has been done to investigate the temporal dynamics and sources of brain activity in healthy human subjects performing such tasks. In a magnetoencephalography study using pictorial stimuli, we have now identified oscillatory activity in the gamma (60-90 Hz) and theta (4.5-8.5 Hz) band during declarative memory operations in healthy participants. Both theta and gamma activity was stronger for the later remembered compared with the later forgotten items (the "subsequent memory effect"). In the retrieval session, theta and gamma activity was stronger for recognized items compared with correctly rejected new items (the "old/new effect"). The gamma activity was also stronger for recognized compared with forgotten old items (the "recognition effect"). The effects in the theta band were observed over right parietotemporal areas, whereas the sources of the effects in the gamma band were identified in Brodmann area 18/19. We propose that the theta activity is directly engaged in mnemonic operations. The increase in neuronal synchronization in the gamma band in occipital areas may result in a stronger drive to subsequent areas, thus facilitating both memory encoding and retrieval. Alternatively, the gamma synchronization might reflect representations being reinforced by top-down activity from higher-level memory areas. Our results provide additional insight on human declarative memory operations and oscillatory brain activity that complements previous electrophysiological and brain imaging studies. [ABSTRACT FROM AUTHOR]

Published

2006