Dependence of Transformation of Intrinsic Rhythmic Impulse Activity of Neurons on Spatio-Temporal Organization of Synaptic Actions on Dendrites: A Simulation Study

Dependence of Transformation of Intrinsic Rhythmic Impulse Activity of Neurons on Spatio-Temporal Organization of Synaptic Actions on Dendrites: A Simulation Study

The aim of the study to elucidate the biophysical mechanisms able to determine specific transformations of the patterns of output signals of neurons (neuronal impulse codes) depending on the spatio-temporal organization of synaptic actions coming to the dendrites. We studied mathematical models of t...

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Bibliographic Details
Published in:Neurophysiology (New York) Vol. 43; no. 6; pp. 425 - 431
Main Authors: Kulagina, I. B., Korogod, S. M.
Format: Journal Article
Language:English
Published: Boston Springer US 01-03-2012
Springer
Springer Nature B.V
Subjects:
Action potential
Analysis
Asymmetry
Biomedical and Life Sciences
Biomedicine
Biophysics
Computers
Cortex
Data processing
Dendrites
Dendritic branching
Electric properties
Mathematical models
Neural networks
Neurons
Neurosciences
Phase shift
Pyramidal cells
Rhythms
Simulation
Transformation
synaptic activation
dendrites
spatial electrical patterns
local phase relationships
controlled transformation of impulse pattern
voltage-dependent ion conductances
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Summary:The aim of the study to elucidate the biophysical mechanisms able to determine specific transformations of the patterns of output signals of neurons (neuronal impulse codes) depending on the spatio-temporal organization of synaptic actions coming to the dendrites. We studied mathematical models of the neocortical layer 5 pyramidal neurons built according to the results of computer reconstruction of their dendritic arborizations and experimental data on the voltage-dependent conductivities of their dendritic membrane. This work is a continuation of our previous studies that showed the existence of certain relations between the complexity of neural impulse codes, on the one hand, and the complexity, size, metrical asymmetry of branching, and nonlinear membrane properties of the dendrites, on the other hand. This relation determines synchronous (with some phase shifts) or asynchronous transitions of asymmetrical dendritic subtrees between high and low depolarization states during the generation of output impulse patterns in response to distributed tonic activation of dendritic inputs. In this work we demonstrate the first time that the appearance and pattern of transformations of complex periodical impulse trains at the neuron’s output associated with receiving a short series of presynaptic action potentials are determined not only by the time of arrival of such a series, but also by their spatial addressing to asymmetric dendritic subtrees; the latter, in this case, may be in the same (synchronous transitions) or different (asynchronous transitions) electrical states. Biophysically, this phenomenon is based on a significant excess of the driving potential for a synaptic excitatory current in low-depolarization regions, as compared with that in high-depolarization dendritic regions receiving phasic synaptic stimuli. These findings open a novel aspect of the functioning of neurons and neuronal networks.
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ISSN:0090-2977
1573-9007
DOI:10.1007/s11062-012-9246-4