Characterization of Human Motor Units From Surface EMG Decomposition

Characterization of Human Motor Units From Surface EMG Decomposition

Motor units are the smallest functional units of our movements. The study of their activation provides a window into the mechanisms of neural control of movement in humans. The classic methods for motor unit investigations date to several decades ago. They are based on invasive recordings with selec...

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Bibliographic Details
Published in:Proceedings of the IEEE Vol. 104; no. 2; pp. 353 - 373
Main Authors: Farina, Dario, Holobar, Ales
Format: Journal Article
Language:English
Published: New York IEEE 01-02-2016
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Activation
Biomedical signal processing
Decomposition
Electromyography
Fault diagnosis
Human
Interference
Motors
Movements
Muscles
Neurons
Signal processing
Surface chemistry
Surface discharges
Surface treatment
motor unit
motor neuron
decomposition
Blind source separation (BSS)
delay estimators
spatial filters
EMG
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Summary:Motor units are the smallest functional units of our movements. The study of their activation provides a window into the mechanisms of neural control of movement in humans. The classic methods for motor unit investigations date to several decades ago. They are based on invasive recordings with selective needle or wire electrodes. Conversely, the noninvasive (surface) EMG has been commonly processed as an interference signal, with the extraction of its global characteristics, e.g., amplitude. These characteristics, however, are only crudely associated to the underlying motor unit activities. In the last decade, methods have been proposed for reliably extracting individual motor unit activities from the interference surface EMG signal. We describe these methods in this review, with a focus on blind source separation (BSS) and techniques used on decomposed EMG signals. For example, from the motor unit discharge timings, information can be extracted regarding the synaptic input received by the corresponding motor neurons. In reviewing these methods, we also provide examples of applications in representative conditions, such as pathological tremor. In conclusion, we provide an overview of processing methods of the surface EMG signal that allow a reliable characterization of individual motor units in vivo in humans.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0018-9219
1558-2256
DOI:10.1109/JPROC.2015.2498665