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A system identification analysis of neural adaptation dynamics and nonlinear responses in the local reflex control of locust hind limbs

A system identification analysis of neural adaptation dynamics and nonlinear responses in the local reflex control of locust hind limbs
A system identification analysis of neural adaptation dynamics and nonlinear responses in the local reflex control of locust hind limbs
Nonlinear type system identification models coupled with white noise stimulation provide an experimentally convenient and quick way to investigate the often complex and nonlinear interactions between the mechanical and neural elements of reflex limb control systems. Previous steady state analysis has allowed the neurons in such systems to be categorised by their sensitivity to position, velocity or acceleration (dynamics) and has improved our understanding of network function. These neurons, however, are known to adapt their output amplitude or spike firing rate during repetitive stimulation and this transient response may be more important than the steady state response for reflex control. In the current study previously used system identification methods are developed and applied to investigate both steady state and transient dynamic and nonlinear changes in the neural circuit responsible for controlling reflex movements of the locust hind limbs. Through the use of a parsimonious model structure and Monte Carlo simulations we conclude that key system dynamics remain relatively unchanged during repetitive stimulation while output amplitude adaptation is occurring. Whilst some evidence of a significant change was found in parts of the systems nonlinear response, the effect was small and probably of little physiological relevance. Analysis using biologically more realistic stimulation reinforces this conclusion.
0929-5313
39-58
Dewhirst, O.P.
bffe05a0-f341-452f-93bc-6824370c5ff9
Angarita, N.
e2299cca-4ec3-4123-8bd8-25d5c02125dd
Simpson, D.M.
53674880-f381-4cc9-8505-6a97eeac3c2a
Allan, R.
2975f2ca-02cb-41c2-bd12-2186286a61ec
Newland, P.L.
7a018c0e-37ba-40f5-bbf6-49ab0f299dbb
Dewhirst, O.P.
bffe05a0-f341-452f-93bc-6824370c5ff9
Angarita, N.
e2299cca-4ec3-4123-8bd8-25d5c02125dd
Simpson, D.M.
53674880-f381-4cc9-8505-6a97eeac3c2a
Allan, R.
2975f2ca-02cb-41c2-bd12-2186286a61ec
Newland, P.L.
7a018c0e-37ba-40f5-bbf6-49ab0f299dbb

Dewhirst, O.P., Angarita, N., Simpson, D.M., Allan, R. and Newland, P.L. (2012) A system identification analysis of neural adaptation dynamics and nonlinear responses in the local reflex control of locust hind limbs. Journal of Computational Neuroscience, 34 (1), 39-58. (doi:10.1007/s10827-012-0405-9). (PMID:22729521)

Record type: Article

Abstract

Nonlinear type system identification models coupled with white noise stimulation provide an experimentally convenient and quick way to investigate the often complex and nonlinear interactions between the mechanical and neural elements of reflex limb control systems. Previous steady state analysis has allowed the neurons in such systems to be categorised by their sensitivity to position, velocity or acceleration (dynamics) and has improved our understanding of network function. These neurons, however, are known to adapt their output amplitude or spike firing rate during repetitive stimulation and this transient response may be more important than the steady state response for reflex control. In the current study previously used system identification methods are developed and applied to investigate both steady state and transient dynamic and nonlinear changes in the neural circuit responsible for controlling reflex movements of the locust hind limbs. Through the use of a parsimonious model structure and Monte Carlo simulations we conclude that key system dynamics remain relatively unchanged during repetitive stimulation while output amplitude adaptation is occurring. Whilst some evidence of a significant change was found in parts of the systems nonlinear response, the effect was small and probably of little physiological relevance. Analysis using biologically more realistic stimulation reinforces this conclusion.

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Published date: 23 June 2012
Organisations: Signal Processing & Control Grp

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Local EPrints ID: 358029
URI: http://eprints.soton.ac.uk/id/eprint/358029
DOI: doi:10.1007/s10827-012-0405-9
ISSN: 0929-5313
PURE UUID: 90261ef0-6798-4db8-98c4-fc48ed90dbcd
ORCID for D.M. Simpson: ORCID iD orcid.org/0000-0001-9072-5088
ORCID for P.L. Newland: ORCID iD orcid.org/0000-0003-4124-8507

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Date deposited: 08 Oct 2013 13:37
Last modified: 15 Mar 2024 03:14

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Contributors

Author: O.P. Dewhirst
Author: N. Angarita
Author: D.M. Simpson ORCID iD
Author: R. Allan
Author: P.L. Newland ORCID iD

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