Nonlinear Coupling between Cortical Oscillations and Muscle Activity during Isotonic Wrist Flexion

Yang, Yuan; Solis‐Escalante, Teodoro; Ruit, Mark van de; Helm, F.C.T. van der; Schouten, Alfred C.

doi:10.3389/fncom.2016.00126

Cited by 50 publications

(47 citation statements)

References 69 publications

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“…Recently, we proposed a frequency domain approach namely cross‐spectral coherence (CSC) to investigate the nonlinear corticomuscular interaction (Yang et al ., ). CSC is a generalised coherence framework for quantifying nonlinear coupling between signals across different frequency bands as well as the linear coupling within the same frequency band (Yang et al ., ).…”

Section: Assessing the Nonlinear Corticomuscular Interactionmentioning

confidence: 97%

“…Using CSC and independent component analysis, we assessed both linear and nonlinear interaction between muscle activity and multiple brain sources in healthy participants during an isotonic wrist flexion task (Yang et al ., ). In consistent with previous studies, we found beta‐band peak in the linear corticomuscular interaction for both motor and sensory‐related cortices, that is primary sensorimotor areas (S1‐M1), premotor area (PMA), supplementary motor area (SMA) and posterior parietal cortex (PPC).…”

Section: Assessing the Nonlinear Corticomuscular Interactionmentioning

confidence: 97%

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Unveiling neural coupling within the sensorimotor system: directionality and nonlinearity

Yang

Dewald

Helm

et al. 2017

Eur J of Neuroscience

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Neural coupling between the central nervous system and the periphery is essential for the neural control of movement. Corticomuscular coherence is a popular linear technique to assess synchronised oscillatory activity in the sensorimotor system. This oscillatory coupling originates from ascending somatosensory feedback and descending motor commands. However, corticomuscular coherence cannot separate this bidirectionality. Furthermore, the sensorimotor system is nonlinear, resulting in cross-frequency coupling. Cross-frequency oscillations cannot be assessed nor exploited by linear measures. Here, we emphasise the need of novel coupling measures, which provide directionality and acknowledge nonlinearity, to unveil neural coupling in the sensorimotor system. We highlight recent advances in the field and argue that assessing directionality and nonlinearity of neural coupling will break new ground in the study of the control of movement in healthy and neurologically impaired individuals.

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Section: Assessing the Nonlinear Corticomuscular Interactionmentioning

confidence: 97%

Section: Assessing the Nonlinear Corticomuscular Interactionmentioning

confidence: 97%

Unveiling neural coupling within the sensorimotor system: directionality and nonlinearity

Yang

Dewald

Helm

et al. 2017

Eur J of Neuroscience

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“…There are several important considerations in its current formulation (H4: relationship between motor unit actions and force). [36][37][38][39][40][41][42] The question of why force is related to the rectified sEMG, and not to sEMG, apparently has to see with the way in which sEMG is recorded, using pairs of electrodes symmetrically placed at both sides of the neuromotor innervation zone on the muscle, as suggested by the experts. 37,39 The force exerted by a muscle is a consequence of the neuromotor stimulation of the muscular fibers by impulse-like action potentials, 43 which accumulate on the muscular cell membranes as a de facto integration of the positive peaks of individual actions, therefore the muscular force appearing responds to the rectified integral of sEMG recordings (r m (t)).…”

Section: Neuromechanic Articulation Modelmentioning

confidence: 99%

Neuromechanical Modelling of Articulatory Movements from Surface Electromyography and Speech Formants

Gómez-Vilda

Gómez-Rodellar

Vicente

et al. 2019

Int. J. Neur. Syst.

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Speech articulation is produced by the movements of muscles in the larynx, pharynx, mouth and face. Therefore speech shows acoustic features as formants which are directly related with neuromotor actions of these muscles. The first two formants are strongly related with jaw and tongue muscular activity. Speech can be used as a simple and ubiquitous signal, easy to record and process, either locally or on e-Health platforms. This fact may open a wide set of applications in the study of functional grading and monitoring neurodegenerative diseases. A relevant question, in this sense, is how far speech correlates and neuromotor actions are related. This preliminary study is intended to find answers to this question by using surface electromyographic recordings on the masseter and the acoustic kinematics related with the first formant. It is shown in the study that relevant correlations can be found among the surface electromyographic activity (dynamic muscle behavior) and the positions and first derivatives of the first formant (kinematic variables related to vertical velocity and acceleration of the joint jaw and tongue biomechanical system). As an application example, it is shown that the probability density function associated to these kinematic variables is more sensitive than classical features as Vowel Space Area † †

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“…1D) was then obtained with parameters 'nvoice' (scale resolution of the wavelet), 'J1' (number of scales) and 'wavenumber' (Morlet mother wavelet parameter) set, respectively, to 0.125, 871 and 7 to yield accurate identification of oscillatory activity from 0.13 Hz to 114.39 Hz in 1.07 Hz step. EMG signals were not rectified to properly model EMG time series as centered Gaussian processes (Bigot et al, 2011;Charissou et al, 2016) and not to lose important information contained in the EMG signal spectrum (Neto & Christou, 2010;McClelland et al, 2012;Yang et al, 2016). The wavelet cross-spectrum ( Fig.…”

Section: Corticomuscular Coherencementioning

confidence: 99%

“…where S EEG, EEG (x, u) is the wavelet cross-spectrum between EMG and EEG signals (Eqn 2), and S EMG (x, u) and S EEG (x, u) are the wavelet auto-spectrum of each EMG and EEG signal (Eqns 3 and 4). The magnitude of the CMC was calculated from 0 to 1 bounded corticomuscular values as the volume under the time-frequency map of magnitude-squared coherence only where the wavelet crossspectrum between the EEG and EMG signals was detected as significant (Charissou et al, 2016;Yoshida et al, 2017). Over the [+3 + 6] s period of interest, the magnitude of the CMC was computed in two frequency bands of interest: [8-13] Hz (CMC 8-13 ) (Christou et al, 2007) and [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31] Hz (CMC 13-31 ) .…”

Section: Corticomuscular Coherencementioning

confidence: 99%

Impaired corticomuscular coherence during isometric elbow flexion contractions in humans with cervical spinal cord injury

Crémoux

Tallet

Maso

et al. 2017

Eur J of Neuroscience

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After spinal cord injury (SCI), the reorganization of the neuromuscular system leads to increased antagonist muscles' co-activation-that is, increased antagonist vs. agonist muscles activation ratio-during voluntary contractions. Increased muscle co-activation is supposed to result from reduced cortical influences on spinal mechanisms inhibiting antagonist muscles. The assessment of the residual interactions between cortical and muscles activity with corticomuscular coherence (CMC) in participants with SCI producing different force levels may shed new lights on the regulation of muscle co-activation. To achieve this aim, we compared the net joint torque, the muscle co-activation and the CMC ~ 10 and ~ 20 Hz with both agonist and antagonist muscles in participants with SCI and healthy participants performing actual isometric elbow flexion contractions at three force levels. For all participants, overall CMC and muscle co-activation decreased with the increase in the net joint torque, but only CMC ~ 10 Hz was correlated with muscle co-activation. Participants with SCI had greater muscle co-activation and lower CMC ~ 10 Hz, at the highest force levels. These results emphasize the importance of CMC as a mechanism that could take part in the modulation of muscle co-activation to maintain a specific force level. Lower CMC ~ 10 Hz in SCI participants may reflect the decreased cortical influence on spinal mechanisms, leading to increased muscle co-activation, although plasticity of the corticomuscular coupling seems to be preserved after SCI to modulate the force level. Clinically, the CMC may efficiently evaluate the residual integrity of the neuromuscular system after SCI and the effects of rehabilitation.

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Nonlinear Coupling between Cortical Oscillations and Muscle Activity during Isotonic Wrist Flexion

Cited by 50 publications

References 69 publications

Unveiling neural coupling within the sensorimotor system: directionality and nonlinearity

Unveiling neural coupling within the sensorimotor system: directionality and nonlinearity

Neuromechanical Modelling of Articulatory Movements from Surface Electromyography and Speech Formants

Impaired corticomuscular coherence during isometric elbow flexion contractions in humans with cervical spinal cord injury

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