Modeling the interactions between stimulation and physiologically induced APs in a mammalian nerve fiber: dependence on frequency and fiber diameter

Vijay Sadashivaiah; Pierre Sacré; Yun Guan; William S. Anderson; Sridevi V. Sarma

doi:10.1007/s10827-018-0703-y

Modeling the interactions between stimulation and physiologically induced APs in a mammalian nerve fiber: dependence on frequency and fiber diameter

Vijay Sadashivaiah, Pierre Sacré, Yun Guan, William S. Anderson, Sridevi V. Sarma

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

Abstract

Electrical stimulation of nerve fibers is used as a therapeutic tool to treat neurophysiological disorders. Despite efforts to model the effects of stimulation, its underlying mechanisms remain unclear. Current mechanistic models quantify the effects that the electrical field produces near the fiber but do not capture interactions between action potentials (APs) initiated by stimulus and APs initiated by underlying physiological activity. In this study, we aim to quantify the effects of stimulation frequency and fiber diameter on AP interactions involving collisions and loss of excitability. We constructed a mechanistic model of a myelinated nerve fiber receiving two inputs: the underlying physiological activity at the terminal end of the fiber, and an external stimulus applied to the middle of the fiber. We define conduction reliability as the percentage of physiological APs that make it to the somatic end of the nerve fiber. At low input frequencies, conduction reliability is greater than 95% and decreases with increasing frequency due to an increase in AP interactions. Conduction reliability is less sensitive to fiber diameter and only decreases slightly with increasing fiber diameter. Finally, both the number and type of AP interactions significantly vary with both input frequencies and fiber diameter. Modeling the interactions between APs initiated by stimulus and APs initiated by underlying physiological activity in a nerve fiber opens opportunities towards understanding mechanisms of electrical stimulation therapies.

Original language	English (US)
Pages (from-to)	193-206
Number of pages	14
Journal	Journal of Computational Neuroscience
Volume	45
Issue number	3
DOIs	https://doi.org/10.1007/s10827-018-0703-y
State	Published - Dec 1 2018

Keywords

Action potential interactions
Conduction reliability
Electrical stimulation
Mechanistic model
Nerve fiber

ASJC Scopus subject areas

Sensory Systems
Cognitive Neuroscience
Cellular and Molecular Neuroscience

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10.1007/s10827-018-0703-y

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title = "Modeling the interactions between stimulation and physiologically induced APs in a mammalian nerve fiber: dependence on frequency and fiber diameter",

abstract = "Electrical stimulation of nerve fibers is used as a therapeutic tool to treat neurophysiological disorders. Despite efforts to model the effects of stimulation, its underlying mechanisms remain unclear. Current mechanistic models quantify the effects that the electrical field produces near the fiber but do not capture interactions between action potentials (APs) initiated by stimulus and APs initiated by underlying physiological activity. In this study, we aim to quantify the effects of stimulation frequency and fiber diameter on AP interactions involving collisions and loss of excitability. We constructed a mechanistic model of a myelinated nerve fiber receiving two inputs: the underlying physiological activity at the terminal end of the fiber, and an external stimulus applied to the middle of the fiber. We define conduction reliability as the percentage of physiological APs that make it to the somatic end of the nerve fiber. At low input frequencies, conduction reliability is greater than 95% and decreases with increasing frequency due to an increase in AP interactions. Conduction reliability is less sensitive to fiber diameter and only decreases slightly with increasing fiber diameter. Finally, both the number and type of AP interactions significantly vary with both input frequencies and fiber diameter. Modeling the interactions between APs initiated by stimulus and APs initiated by underlying physiological activity in a nerve fiber opens opportunities towards understanding mechanisms of electrical stimulation therapies.",

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author = "Vijay Sadashivaiah and Pierre Sacr{\'e} and Yun Guan and Anderson, {William S.} and Sarma, {Sridevi V.}",

note = "Funding Information: In this study, we investigated the interactions between APs traveling along a mammalian nerve fiber induced by both electrical stimulation and physiological activity. To our knowledge, this is the first mechanistic modeling effort to quantify these interactions. We found that the conduction reliability of APs depends on the frequency of stimulation and the rate of the physiological activity. Specifically, overall conduction reliability Rall is modulated by the rate of physiological activity. This is also supported by the dominant occurrence of physiological–stimulus loss of excitability interactions. Conduction reliability of physiological APs, Rphys is high for low stimulus frequencies and low physiological rates and decreases with an increase of either stimulus frequency or physiological rate. On the other hand, conduction reliability of stimulus APs, Rstim is Funding Information: Work supported by NIH R01 AT009401 to S.V.S, Y.G., and W.S.A., and by NPRI postdoctoral fellowship awarded to P.S. We would like to thank Dr. Michael Caterina, Neurosurgery Pain Research Institute, The Johns Hopkins University School of Medicine for valuable and insightful discussions. Publisher Copyright: {\textcopyright} 2018, Springer Science+Business Media, LLC, part of Springer Nature.",

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doi = "10.1007/s10827-018-0703-y",

language = "English (US)",

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T1 - Modeling the interactions between stimulation and physiologically induced APs in a mammalian nerve fiber

T2 - dependence on frequency and fiber diameter

AU - Sadashivaiah, Vijay

AU - Sacré, Pierre

AU - Guan, Yun

AU - Anderson, William S.

AU - Sarma, Sridevi V.

N1 - Funding Information: In this study, we investigated the interactions between APs traveling along a mammalian nerve fiber induced by both electrical stimulation and physiological activity. To our knowledge, this is the first mechanistic modeling effort to quantify these interactions. We found that the conduction reliability of APs depends on the frequency of stimulation and the rate of the physiological activity. Specifically, overall conduction reliability Rall is modulated by the rate of physiological activity. This is also supported by the dominant occurrence of physiological–stimulus loss of excitability interactions. Conduction reliability of physiological APs, Rphys is high for low stimulus frequencies and low physiological rates and decreases with an increase of either stimulus frequency or physiological rate. On the other hand, conduction reliability of stimulus APs, Rstim is Funding Information: Work supported by NIH R01 AT009401 to S.V.S, Y.G., and W.S.A., and by NPRI postdoctoral fellowship awarded to P.S. We would like to thank Dr. Michael Caterina, Neurosurgery Pain Research Institute, The Johns Hopkins University School of Medicine for valuable and insightful discussions. Publisher Copyright: © 2018, Springer Science+Business Media, LLC, part of Springer Nature.

PY - 2018/12/1

Y1 - 2018/12/1

N2 - Electrical stimulation of nerve fibers is used as a therapeutic tool to treat neurophysiological disorders. Despite efforts to model the effects of stimulation, its underlying mechanisms remain unclear. Current mechanistic models quantify the effects that the electrical field produces near the fiber but do not capture interactions between action potentials (APs) initiated by stimulus and APs initiated by underlying physiological activity. In this study, we aim to quantify the effects of stimulation frequency and fiber diameter on AP interactions involving collisions and loss of excitability. We constructed a mechanistic model of a myelinated nerve fiber receiving two inputs: the underlying physiological activity at the terminal end of the fiber, and an external stimulus applied to the middle of the fiber. We define conduction reliability as the percentage of physiological APs that make it to the somatic end of the nerve fiber. At low input frequencies, conduction reliability is greater than 95% and decreases with increasing frequency due to an increase in AP interactions. Conduction reliability is less sensitive to fiber diameter and only decreases slightly with increasing fiber diameter. Finally, both the number and type of AP interactions significantly vary with both input frequencies and fiber diameter. Modeling the interactions between APs initiated by stimulus and APs initiated by underlying physiological activity in a nerve fiber opens opportunities towards understanding mechanisms of electrical stimulation therapies.

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Modeling the interactions between stimulation and physiologically induced APs in a mammalian nerve fiber: dependence on frequency and fiber diameter

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