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孙长凯

Professor
Supervisor of Doctorate Candidates
Supervisor of Master's Candidates


Gender:Male
Alma Mater:第四军医大学
Degree:Doctoral Degree
School/Department:人工智能学院
Discipline:Biomedical Engineering
Business Address:大连理工大学创新园大厦B1202
Contact Information:sunck2@dlut.edu.cn
E-Mail:sunck2@dlut.edu.cn
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Current position: Home >> Scientific Research >> Paper Publications

An axonal model for analysis of ionic concentration alterations induced by high frequency electrical stimulations

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Indexed by:会议论文

Date of Publication:2017-01-01

Included Journals:Scopus

Page Number:1680-1684

Abstract:The nerve conduction blocking by high frequency biphasic (HFB) electrical stimulations has many potentially valuable clinical applications, but its safety margins require further evaluations. This simulation study aimed to construct an axonal model to investigate the effects of HFB electrical currents on the axonal conductibility and ionic concentrations. The axonal model was constructed in the software of NEURON by incorporating the McIntyre-Richardson-Grill model's geometries, Frankenhaeuser-Huxley and passive equations, ionic diffusion mechanism, and sodium pump activities. The applied 5 s HFB electrical stimulation apparently altered the axon's conductibility, which manifested lowered AP amplitudes, elevated resting membrane potentials, and delayed AP initiation times. These changes did not gain complete recoveries within the observed 55 s period, and showed to be mainly attributed to the induced alterations in ionic concentrations of nodal [Na+]i, nodal [K+]i and para-nodal [Na+]o. The results implied that the inter-nodal segments played a buffering role against changes of intracellular nodal ionic concentrations, and the intra-cellular ionic concentrations recovered at the price of increases in para-nodal [Na+]o. This study provided more information useful for evaluating the safety margins of nerve conduction blocking by HFB electrical stimulations, and are valuable for designing more safe and applicable protocols. ? 2016 IEEE.