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Pre-processing and transfer entropy measures in motor neurons controlling limb movements

Pre-processing and transfer entropy measures in motor neurons controlling limb movements
Pre-processing and transfer entropy measures in motor neurons controlling limb movements
Directed information transfer measures are increasingly being employed in modeling neural system behavior due to their model-free approach, applicability to nonlinear and stochastic signals, and the potential to integrate repetitions of an experiment. Intracellular physiological recordings of graded synaptic potentials provide a number of additional challenges compared to spike signals due to non-stationary behaviour generated through extrinsic processes. We therefore propose a method to overcome this difficulty by using a preprocessing step based on Singular Spectrum Analysis (SSA) to remove nonlinear trends and discontinuities. We apply the method to intracellular recordings of synaptic responses of identified motor neurons evoked by stimulation of a proprioceptor that monitors limb position in leg of the desert locust. We then apply normalized delayed transfer entropy measures to neural responses evoked by displacements of the proprioceptor, the femoral chordotonal organ, that contains sensory neurones that monitor movements about the femoral-tibial joint. We then determine the consistency of responses within an individual recording of an identified motor neuron in a single animal, between repetitions of the same experiment in an identified motor neurons in the same animal and in repetitions of the same experiment from the same identified motor neuron in different animals. We found that delayed transfer entropy measures were consistent for a given identified neuron within and between animals and that they predict neural connectivity for the fast extensor tibiae motor neuron.
0929-5313
159-171
Santos, Fernando P.
f6e06f62-38ce-48bf-8d7e-5dd13791fa00
Maciel, Carlos D.
0b9d2f77-4d09-49f8-a8f6-8ceb2254d14b
Newland, Philip L.
7a018c0e-37ba-40f5-bbf6-49ab0f299dbb
Santos, Fernando P.
f6e06f62-38ce-48bf-8d7e-5dd13791fa00
Maciel, Carlos D.
0b9d2f77-4d09-49f8-a8f6-8ceb2254d14b
Newland, Philip L.
7a018c0e-37ba-40f5-bbf6-49ab0f299dbb

Santos, Fernando P., Maciel, Carlos D. and Newland, Philip L. (2017) Pre-processing and transfer entropy measures in motor neurons controlling limb movements. Journal of Computational Neuroscience, 43 (2), 159-171. (doi:10.1007/s10827-017-0656-6).

Record type: Article

Abstract

Directed information transfer measures are increasingly being employed in modeling neural system behavior due to their model-free approach, applicability to nonlinear and stochastic signals, and the potential to integrate repetitions of an experiment. Intracellular physiological recordings of graded synaptic potentials provide a number of additional challenges compared to spike signals due to non-stationary behaviour generated through extrinsic processes. We therefore propose a method to overcome this difficulty by using a preprocessing step based on Singular Spectrum Analysis (SSA) to remove nonlinear trends and discontinuities. We apply the method to intracellular recordings of synaptic responses of identified motor neurons evoked by stimulation of a proprioceptor that monitors limb position in leg of the desert locust. We then apply normalized delayed transfer entropy measures to neural responses evoked by displacements of the proprioceptor, the femoral chordotonal organ, that contains sensory neurones that monitor movements about the femoral-tibial joint. We then determine the consistency of responses within an individual recording of an identified motor neuron in a single animal, between repetitions of the same experiment in an identified motor neurons in the same animal and in repetitions of the same experiment from the same identified motor neuron in different animals. We found that delayed transfer entropy measures were consistent for a given identified neuron within and between animals and that they predict neural connectivity for the fast extensor tibiae motor neuron.

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Accepted/In Press date: 25 July 2017
e-pub ahead of print date: 9 August 2017
Published date: 1 October 2017

Identifiers

Local EPrints ID: 413829
URI: http://eprints.soton.ac.uk/id/eprint/413829
DOI: doi:10.1007/s10827-017-0656-6
ISSN: 0929-5313
PURE UUID: a6a29c88-8b53-467c-9a13-bbc2d10f4357
ORCID for Philip L. Newland: ORCID iD orcid.org/0000-0003-4124-8507

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Date deposited: 07 Sep 2017 16:31
Last modified: 16 Mar 2024 05:42

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Contributors

Author: Fernando P. Santos
Author: Carlos D. Maciel
Author: Philip L. Newland ORCID iD

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