Electroencephalographic and magnetoencephalographic data have characterized two types of brain–body interactions observed during various types of motor actions, “corticokinematic” and “corticomuscular” coupling. Here, we review the literature on these interactions in healthy individuals, discuss several open debates, and outline current limitations and directions for future research. Corticokinematic coupling (commonly referred to as corticokinematic coherence) probes the relationship between activity of sensorimotor network nodes and various movement-related signals (e.g., speed, velocity, acceleration). It is mainly driven by movement rhythmicity during active, passive, and observed dynamic motor actions. It typically predominates at the ...
As humans, we seamlessly hold objects in our hands, and may even lose consciousness of these objects...
Aims of the study: This study investigates the effect of movement rate on the coupling between corti...
Large areas of the human motor cortex are devoted to the control of the contralateral hand and forea...
Electroencephalographic and magnetoencephalographic data have characterized two types of brain–body ...
Available online 9 September 2019Electroencephalographic and magnetoencephalographic data have chara...
Coupling between cortical oscillations and muscle activity facilitates neuronal communication during...
Neural oscillations are thought to underlie coupling of spatially remote neurons and gating of infor...
This study investigates whether movement kinematics modulates similarly the rolandic α and β rhythm ...
To gain fundamental knowledge on how the brain controls motor actions, we studied in detail the inte...
To gain fundamental knowledge on how the brain controls motor actions, we studied in detail the inte...
Corticokinematic coherence (CKC) reflects coupling between magnetoencephalographic (MEG) signals and...
Previously, the effects of external visual stimulation on cortico-muscular synchronization was studi...
Previously, the effects of external visual stimulation on cortico-muscular synchronization was studi...
Human movements often spontaneously fall into synchrony with auditory and visual environmental rhyth...
Neural coupling between the central nervous system and the periphery is essential for the neural con...
As humans, we seamlessly hold objects in our hands, and may even lose consciousness of these objects...
Aims of the study: This study investigates the effect of movement rate on the coupling between corti...
Large areas of the human motor cortex are devoted to the control of the contralateral hand and forea...
Electroencephalographic and magnetoencephalographic data have characterized two types of brain–body ...
Available online 9 September 2019Electroencephalographic and magnetoencephalographic data have chara...
Coupling between cortical oscillations and muscle activity facilitates neuronal communication during...
Neural oscillations are thought to underlie coupling of spatially remote neurons and gating of infor...
This study investigates whether movement kinematics modulates similarly the rolandic α and β rhythm ...
To gain fundamental knowledge on how the brain controls motor actions, we studied in detail the inte...
To gain fundamental knowledge on how the brain controls motor actions, we studied in detail the inte...
Corticokinematic coherence (CKC) reflects coupling between magnetoencephalographic (MEG) signals and...
Previously, the effects of external visual stimulation on cortico-muscular synchronization was studi...
Previously, the effects of external visual stimulation on cortico-muscular synchronization was studi...
Human movements often spontaneously fall into synchrony with auditory and visual environmental rhyth...
Neural coupling between the central nervous system and the periphery is essential for the neural con...
As humans, we seamlessly hold objects in our hands, and may even lose consciousness of these objects...
Aims of the study: This study investigates the effect of movement rate on the coupling between corti...
Large areas of the human motor cortex are devoted to the control of the contralateral hand and forea...