Disinhibition in the gamma motoneuron circuitry : A neglected mechanism for understanding myofascial pain syndromes ?

Dysregulation in the gamma motoneuron circuitry is proposed as one mechanism to explain the development of trigger point activity in myofascial pain syndrome. Dysregulation in this context is defined operationally as significantly (and functionally) different levels of electrical activity detected i...

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Bibliographic Details
Published in:Applied psychophysiology and biofeedback 1998-03, Vol.23 (1), p.43-57
Main Authors: DONALDSON, C. C. S, NELSON, D. V, SCHULZ, R
Format: Article
Language:English
Subjects:
Biological and medical sciences
Diseases of striated muscles. Neuromuscular diseases
Facial Muscles - physiopathology
Facial Pain - physiopathology
Humans
Medical sciences
Motor Neurons, Gamma - physiology
Neurology
Temporomandibular Joint Dysfunction Syndrome - physiopathology
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Summary:Dysregulation in the gamma motoneuron circuitry is proposed as one mechanism to explain the development of trigger point activity in myofascial pain syndrome. Dysregulation in this context is defined operationally as significantly (and functionally) different levels of electrical activity detected in the same muscle on the left and right sides of the body that is persistently present with movement of that muscle. Neurophysiological concepts as they pertain to muscles and motor control principles are reviewed. Research is integrated that ties together material from diverse fields of psychology and medicine. Dysregulation in the gamma motoneuron circuitry may lead to disinhibition of muscle that causes it to remain hyperactive after contraction, generate excessive electrical activity during movement, and/or inappropriately coactivate with other muscles during movement. Any or all of these phenomena may occur with dysregulation. Such dysregulation may be corrected by learning. Immediate clinical implications are discussed, including the addition of specifically targeted neuromuscular retraining procedures via surface electromyography, as well as some conceptual and research issues that require further clarification.
ISSN:1090-0586
1573-3270
DOI:10.1023/A:1022122113050