Does abnormal spinal reciprocal inhibition lead to co-contraction of antagonist motor units?: A modeling study

Vassilis Cutsuridis

doi:10.1142/S0129065707001160

Does abnormal spinal reciprocal inhibition lead to co-contraction of antagonist motor units? A modeling study

Vassilis Cutsuridis

University of Stirling

Research output: Contribution to journal › Article › peer-review

Abstract

It is suggested that co-contraction of antagonist motor units perhaps due to abnormal disynaptic I(a) reciprocal inhibition is responsible for Parkinsonian rigidity. A neural model of Parkinson's disease bradykinesia is extended to incorporate the effects of spindle feedback on key cortical cells and examine the effects of dopamine depletion on spinal activities. Simulation results show that although reciprocal inhibition is reduced in DA depleted case, it doesn't lead to co-contraction of antagonist motor neurons. Implications to Parkinsonian rigidity are discussed.

Original language	English
Pages (from-to)	319-27
Number of pages	9
Journal	International Journal of Neural Systems
Volume	17
Issue number	4
DOIs	https://doi.org/10.1142/S0129065707001160
Publication status	Published - Aug 2007
Externally published	Yes

Keywords

Action Potentials
Computer Simulation
Humans
Mathematics
Models, Neurological
Motor Neurons/physiology
Neural Inhibition/physiology
Parkinson Disease/pathology
Spinal Cord/pathology

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10.1142/S0129065707001160

https://www.worldscientific.com/doi/abs/10.1142/S0129065707001160

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abstract = "It is suggested that co-contraction of antagonist motor units perhaps due to abnormal disynaptic I(a) reciprocal inhibition is responsible for Parkinsonian rigidity. A neural model of Parkinson's disease bradykinesia is extended to incorporate the effects of spindle feedback on key cortical cells and examine the effects of dopamine depletion on spinal activities. Simulation results show that although reciprocal inhibition is reduced in DA depleted case, it doesn't lead to co-contraction of antagonist motor neurons. Implications to Parkinsonian rigidity are discussed.",

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AB - It is suggested that co-contraction of antagonist motor units perhaps due to abnormal disynaptic I(a) reciprocal inhibition is responsible for Parkinsonian rigidity. A neural model of Parkinson's disease bradykinesia is extended to incorporate the effects of spindle feedback on key cortical cells and examine the effects of dopamine depletion on spinal activities. Simulation results show that although reciprocal inhibition is reduced in DA depleted case, it doesn't lead to co-contraction of antagonist motor neurons. Implications to Parkinsonian rigidity are discussed.

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KW - Computer Simulation

KW - Humans

KW - Mathematics

KW - Models, Neurological

KW - Motor Neurons/physiology

KW - Neural Inhibition/physiology

KW - Parkinson Disease/pathology

KW - Spinal Cord/pathology

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EP - 327

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JF - International Journal of Neural Systems

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ER -

Does abnormal spinal reciprocal inhibition lead to co-contraction of antagonist motor units? A modeling study

Abstract

Keywords

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