Isotonic ion replacement can lower the threshold for selective infrared neural inhibition

Significance: Infrared (IR) inhibition can selectively block peripheral sensory nerve fibers, a potential treatment for autonomic-dysfunction-related diseases (e.g., neuropathic pain and interstitial cystitis). Lowering the IR inhibition threshold can increase its translational potentials. Aim: Infr...

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Veröffentlicht in:	Neurophotonics (Print) 2021-01, Vol.8 (1), p.015005-015005
Hauptverfasser:	Zhuo, Junqi, Ou, Zihui, Zhang, Yuhan, Jackson, Elizabeth M, Shankar, Sachin S, McPheeters, Matthew T, Ford, Jeremy B, Jansen, E. Duco, Chiel, Hillel J, Jenkins, Michael W
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Schlagworte:	Autonomic nervous system Chloride Choline Electric currents Glucose Hypotheses Lasers Peripheral neuropathy Research Papers Sensory neurons Translation
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creator	Zhuo, Junqi Ou, Zihui Zhang, Yuhan Jackson, Elizabeth M Shankar, Sachin S McPheeters, Matthew T Ford, Jeremy B Jansen, E. Duco Chiel, Hillel J Jenkins, Michael W
description	Significance: Infrared (IR) inhibition can selectively block peripheral sensory nerve fibers, a potential treatment for autonomic-dysfunction-related diseases (e.g., neuropathic pain and interstitial cystitis). Lowering the IR inhibition threshold can increase its translational potentials. Aim: Infrared induces inhibition by enhancing potassium channel activation. We hypothesized that the IR dose threshold could be reduced by combining it with isotonic ion replacement. Approach: We tested the IR inhibition threshold on the pleural-abdominal connective of Aplysia californica. Using a customized chamber system, the IR inhibition was applied either in normal saline or in isotonic ion-replaced saline, which could be high glucose saline, high choline saline, or high glucose/high choline saline. Each modified saline was at a subthreshold concentration for inhibiting neural conduction. Results: We showed that isotonically replacing ions in saline with glucose and/or choline can reduce the IR threshold and temperature threshold of neural inhibition. Furthermore, the size selectivity of IR inhibition was preserved when combined with high glucose/high choline saline. Conclusions: The present work of IR inhibition combined with isotonic ion replacement will guide further development of a more effective size-selective IR inhibition modality for future research and translational applications.
doi_str_mv	10.1117/1.NPh.8.1.015005
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subjects	Autonomic nervous system Chloride Choline Electric currents Glucose Hypotheses Lasers Peripheral neuropathy Research Papers Sensory neurons Translation
title	Isotonic ion replacement can lower the threshold for selective infrared neural inhibition
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