Analysis of a nonlinear cascade model for sensory encoding by modification of ion channels

A. S. French; M. J. Korenberg

Analysis of a nonlinear cascade model for sensory encoding by modification of ion channels

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Mechanotransconduction is often modeled as a three-stage process in which the input stimulus is first transformed by mechanical components, then transduced into an intracellular receptor current, and finally encoded into a train of action potentials. In the cockroach tactile spine, a rapidly adapting sensory organ, the dynamic behavior is controlled by the encoding stage. It has been previously shown that a nonlinear cascaded model can account for much of the dynamic response. Here, the authors describe the dissection of the cascade by the use of phentolamine, a drug which appears to selectively modify the behavior of sodium channels in the encoder region of the neuron. Phentolamine raised the threshold of the neuron and slowed its discharge rate to a constant white noise stimulus, but did not prevent system identification. Preliminary results suggest that the nonlinear static component of the cascade is unaffected by this drug, while the nonlinear dynamic components are changed. These results may be due to the ionic processes involved in action potential encoding.

Original language	English
Title of host publication	Biomedical Engineering Perspectives
Subtitle of host publication	Health Care Technologies for the 1990's and Beyond
Publisher	Publ by IEEE
Pages	25-26
Number of pages	2
Edition	pt 1
ISBN (Print)	0879425598
Publication status	Published - 1990
Externally published	Yes
Event	Proceedings of the 12th Annual International Conference of the IEEE Engineering in Medicine and Biology Society - Philadelphia, PA, USA Duration: Nov 1 1990 → Nov 4 1990

Publication series

Name	Proceedings of the Annual Conference on Engineering in Medicine and Biology
Number	pt 1
ISSN (Print)	0589-1019

Conference

Conference	Proceedings of the 12th Annual International Conference of the IEEE Engineering in Medicine and Biology Society
City	Philadelphia, PA, USA
Period	11/1/90 → 11/4/90

ASJC Scopus Subject Areas

Signal Processing
Biomedical Engineering
Computer Vision and Pattern Recognition
Health Informatics

Cite this

Analysis of a nonlinear cascade model for sensory encoding by modification of ion channels. / French, A. S.; Korenberg, M. J.
Biomedical Engineering Perspectives: Health Care Technologies for the 1990's and Beyond. pt 1. ed. Publ by IEEE, 1990. p. 25-26 (Proceedings of the Annual Conference on Engineering in Medicine and Biology; No. pt 1).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

French, AS & Korenberg, MJ 1990, Analysis of a nonlinear cascade model for sensory encoding by modification of ion channels. in Biomedical Engineering Perspectives: Health Care Technologies for the 1990's and Beyond. pt 1 edn, Proceedings of the Annual Conference on Engineering in Medicine and Biology, no. pt 1, Publ by IEEE, pp. 25-26, Proceedings of the 12th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Philadelphia, PA, USA, 11/1/90.

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AB - Mechanotransconduction is often modeled as a three-stage process in which the input stimulus is first transformed by mechanical components, then transduced into an intracellular receptor current, and finally encoded into a train of action potentials. In the cockroach tactile spine, a rapidly adapting sensory organ, the dynamic behavior is controlled by the encoding stage. It has been previously shown that a nonlinear cascaded model can account for much of the dynamic response. Here, the authors describe the dissection of the cascade by the use of phentolamine, a drug which appears to selectively modify the behavior of sodium channels in the encoder region of the neuron. Phentolamine raised the threshold of the neuron and slowed its discharge rate to a constant white noise stimulus, but did not prevent system identification. Preliminary results suggest that the nonlinear static component of the cascade is unaffected by this drug, while the nonlinear dynamic components are changed. These results may be due to the ionic processes involved in action potential encoding.

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Analysis of a nonlinear cascade model for sensory encoding by modification of ion channels

Abstract

Publication series

Conference

ASJC Scopus Subject Areas

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