BrainPharm: Computational model - Convergence regulates synchronization-dependent AP transfer in feedforward NNs (Sailamul et al 2017)

Computational model

Data

Name

Convergence regulates synchronization-dependent AP transfer in feedforward NNs (Sailamul et al 2017)

Submitter name

Pachaya Sailamul

Pipeline ID

Model File

Sailamul_et_al_2017_code.zip [24415]

Notes

We study how synchronization-dependent spike transfer can be affected by the structure of convergent feedforward wiring. We implemented computer simulations of model neural networks: a source and a target layer connected with different types of convergent wiring rules. In the Gaussian-Gaussian (GG) model, both the connection probability and the strength are given as Gaussian distribution as a function of spatial distance. In the Uniform-Constant (UC) and Uniform-Exponential (UE) models, the connection probability density is a uniform constant within a certain range, but the connection strength is set as a constant value or an exponentially decaying function, respectively. Then we examined how the spike transfer function is modulated under these conditions, while static or synchronized input patterns were introduced to simulate different levels of feedforward spike synchronization. We observed that the synchronization-dependent modulation of the transfer function appeared noticeably different for each convergence condition. The modulation of the spike transfer function was largest in the UC model, and smallest in the UE model. Our analysis showed that this difference was induced by the different spike weight distributions that was generated from convergent synapses in each model. Our results suggest that the structure of the feedforward convergence is a crucial factor for correlation-dependent spike control, thus must be considered important to understand the mechanism of information transfer in the brain.

Model Neurons

More Cells

Hodgkin-Huxley neuron Show Other

Model Currents

I Sodium Show Other
I Potassium Show Other
I T low threshold Show Other
I Cl, leak Show Other

Model Receptors

Model Type

Realistic Network Show Other
Synapse Show Other

Model Concept

Synchronization Show Other
Oscillations Show Other
Action Potentials Show Other
Activity Patterns Show Other
Information transfer Show Other
Synaptic Convergence Show Other

Simulator software

NEURON Show Other
MATLAB Show Other

Model papers

Sailamul P, Jang J, Paik SB (2017) Show Other

Gene

hg folder name (applicable when in ModelDB hg)

Region Organism

Model ID Number

Gap Junctions

Implemented by

Sailamul, Pachaya [pachaya_sailamul at brown.edu] Show Other
Jang, Jaeson Show Other
Paik, Se-Bum Show Other

Public Submitter Email Address

pachaya_sailamul@brown.edu

Other Neuron

Model Neurotransmitters

Other Receptor

Other Current

Other Neurotransmitter

Other Model Type

Feedforward networks

Other Concept

synaptic convergence

Other Simulator

Other Implementer

Sailamul, Pachaya; Jang, Jaeson; Paik, Se-Bum;

Alternative Version

Citation

PMID: 28895002 PMCID: PMC5691111 DOI: 10.1007/s10827-017-0657-5 Sailamul, Pachaya, Jaeson Jang, and Se-Bum Paik. "Synaptic convergence regulates synchronization-dependent spike transfer in feedforward neural networks." Journal of computational neuroscience 43.3 (2017): 189-202.

Default File Notes

Other Gene

Simulation Platform ID

Has Model View

False

Component

RAM

Hide Auto-launch button

True

Run Protocols

ICG Channel Details

Species

Other categories referring to Convergence regulates synchronization-dependent AP transfer in feedforward NNs (Sailamul et al 2017)

Revisions:	6
Last Time:	6/6/2018 5:29:32 PM
Reviewer:	Tom Morse - MoldelDB admin
Owner:	Tom Morse - MoldelDB admin