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Adjustable primitive pattern generator: A novel cerebellar model for reaching movements

Vahdat, S ; Sharif University of Technology | 2006

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  1. Type of Document: Article
  2. DOI: 10.1016/j.neulet.2006.07.038
  3. Publisher: 2006
  4. Abstract:
  5. Cerebellum has been assumed as an array of adjustable pattern generators (APGs). In recent years, electrophysiological researches have suggested the existence of modular structures in spinal cord called motor primitives. In our proposed model, each "adjustable primitive pattern generator" (APPG) module in the cerebellum is consisted of a large number of parallel APGs, the output of each module being the weighted sum of the outputs of these APGs. Each spinal field is tuned by a coefficient, representing a descending supraspinal command, which is modulated by ith APPG correspondingly. According to this model, motor control can be interpreted in terms of the modification of these coefficients. Vector summation of force fields implies that the complex nonlinearities in neuronal behavior are eliminated, causing our model to be simple and linear. The force field vectors, derived from motor primitives, depend on the state of movement and its derivative and the time that causes different repertoire of movement. This is physiologically plausible. Our model agrees with virtual trajectory hypothesis, stating that dynamics are not computed explicitly in central nervous system, but the desired trajectory, is fed into the spinal cord. We think that the dysmetria and the ataxia seen in some cerebellar diseases may be the result of local disruption of some APPGs. Accordingly, determining the exact location of related motor primitives in human spinal cord and stimulating them by functional neurostimulation may provide a good management for these clinical signs. Surely, experimental researches and clinical trials are needed to validate our hypothesis. © 2006 Elsevier Ireland Ltd. All rights reserved
  6. Keywords:
  7. Adjustable primitive pattern generator ; Central nervous system ; Mathematical model ; Motion ; Motor control ; Nerve stimulation ; Priority journal ; Animals ; Cerebellum ; Humans ; Models, Neurological ; Movement ; Nerve Net ; Neural Networks (Computer) ; Neural Pathways ; Spinal Cord
  8. Source: Neuroscience Letters ; Volume 406, Issue 3 , 2006 , Pages 232-234 ; 03043940 (ISSN)
  9. URL: https://www.sciencedirect.com/science/article/abs/pii/S0304394006007336