Defective Utilization of Sensory Input as the Basis for Bradykinesia, Rigidity and Decreased Movement Repertoire in Parkinson’s Disease: A Hypothesis

From a review of the anatomical relationships and single unit activity in the components of the basal ganglia related to limb movement, it is concluded that the major outflow from basal ganglia circuits is via the motor cortex (area 4). Recent results of recording from area 4 neurons revealed that t...

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Bibliographic Details
Published in:Canadian journal of neurological sciences 1984-02, Vol.11 (S1), p.136-143
Main Authors: Tatton, W.G., Eastman, M.J., Bedingham, W., Verrier, M.C., Bruce, I.C.
Format: Article
Language:English
Subjects:
1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine
2. Physiology of the Basal Ganglia and Pathophysiology of Parkinson’s Disease
Afferent Pathways - physiopathology
Animals
Cats
Humans
Mechanoreceptors - physiopathology
Models, Neurological
Movement Disorders - complications
Movement Disorders - physiopathology
Muscle Rigidity - complications
Muscle Rigidity - physiopathology
Parkinson Disease - complications
Primates
Pyridines - pharmacology
Reflex - drug effects
Reflex - physiology
Sensation - physiology
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Summary:From a review of the anatomical relationships and single unit activity in the components of the basal ganglia related to limb movement, it is concluded that the major outflow from basal ganglia circuits is via the motor cortex (area 4). Recent results of recording from area 4 neurons revealed that they preferentially “encode” the higher derivatives of movement, i.e. acceleration and jerk. In the parkinsonian (PK) patient and in the monkeys treated with l-methyl-4-phenyl-1, 2, 3, 6-tetrahydropyridine (MPTP), EMG responses to imposed loads show a markedly increased gain of the “M2” component which depends upon the integrity of area 4 and which correlates with the severity of PK rigidity. The above observations are considered, along with those of others (demonstrating prolonged movement times, a decreased “repertoire” of voluntary movements fractionation of voluntary movements’, inability in tracking movements without visual input, and failure to improve performance in PK’s) in relation to a model of the interactions between sensory input and motor programs. Using this model, it is hypothesized that the above PK movement deficits, as well as rigidity, can be accounted for by abnormal processing of the mechanoreceptor sensory input utilized in the generation and execution of movements. The MPTP treated monkey is suggested as a model in which to directly test the hypothesis.
ISSN:0317-1671
2057-0155
DOI:10.1017/S0317167100046291