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Antidromic propagation of action potentials in branched axons: implications for the mechanisms of action of deep brain stimulation.

Publication ,  Journal Article
Grill, WM; Cantrell, MB; Robertson, MS
Published in: Journal of computational neuroscience
February 2008

Electrical stimulation of the central nervous system creates both orthodromically propagating action potentials, by stimulation of local cells and passing axons, and antidromically propagating action potentials, by stimulation of presynaptic axons and terminals. Our aim was to understand how antidromic action potentials navigate through complex arborizations, such as those of thalamic and basal ganglia afferents-sites of electrical activation during deep brain stimulation. We developed computational models to study the propagation of antidromic action potentials past the bifurcation in branched axons. In both unmyelinated and myelinated branched axons, when the diameters of each axon branch remained under a specific threshold (set by the antidromic geometric ratio), antidromic propagation occurred robustly; action potentials traveled both antidromically into the primary segment as well as "re-orthodromically" into the terminal secondary segment. Propagation occurred across a broad range of stimulation frequencies, axon segment geometries, and concentrations of extracellular potassium, but was strongly dependent on the geometry of the node of Ranvier at the axonal bifurcation. Thus, antidromic activation of axon terminals can, through axon collaterals, lead to widespread activation or inhibition of targets remote from the site of stimulation. These effects should be included when interpreting the results of functional imaging or evoked potential studies on the mechanisms of action of DBS.

Duke Scholars

Published In

Journal of computational neuroscience

DOI

EISSN

1573-6873

ISSN

0929-5313

Publication Date

February 2008

Volume

24

Issue

1

Start / End Page

81 / 93

Related Subject Headings

  • Time Factors
  • Synaptic Transmission
  • Reaction Time
  • Ranvier's Nodes
  • Presynaptic Terminals
  • Potassium Channels
  • Neurology & Neurosurgery
  • Neural Pathways
  • Membrane Potentials
  • Humans
 

Citation

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Grill, W. M., Cantrell, M. B., & Robertson, M. S. (2008). Antidromic propagation of action potentials in branched axons: implications for the mechanisms of action of deep brain stimulation. Journal of Computational Neuroscience, 24(1), 81–93. https://doi.org/10.1007/s10827-007-0043-9
Grill, Warren M., Meredith B. Cantrell, and Matthew S. Robertson. “Antidromic propagation of action potentials in branched axons: implications for the mechanisms of action of deep brain stimulation.Journal of Computational Neuroscience 24, no. 1 (February 2008): 81–93. https://doi.org/10.1007/s10827-007-0043-9.
Grill WM, Cantrell MB, Robertson MS. Antidromic propagation of action potentials in branched axons: implications for the mechanisms of action of deep brain stimulation. Journal of computational neuroscience. 2008 Feb;24(1):81–93.
Grill, Warren M., et al. “Antidromic propagation of action potentials in branched axons: implications for the mechanisms of action of deep brain stimulation.Journal of Computational Neuroscience, vol. 24, no. 1, Feb. 2008, pp. 81–93. Epmc, doi:10.1007/s10827-007-0043-9.
Grill WM, Cantrell MB, Robertson MS. Antidromic propagation of action potentials in branched axons: implications for the mechanisms of action of deep brain stimulation. Journal of computational neuroscience. 2008 Feb;24(1):81–93.
Journal cover image

Published In

Journal of computational neuroscience

DOI

EISSN

1573-6873

ISSN

0929-5313

Publication Date

February 2008

Volume

24

Issue

1

Start / End Page

81 / 93

Related Subject Headings

  • Time Factors
  • Synaptic Transmission
  • Reaction Time
  • Ranvier's Nodes
  • Presynaptic Terminals
  • Potassium Channels
  • Neurology & Neurosurgery
  • Neural Pathways
  • Membrane Potentials
  • Humans