BrainPharm: Computational model - Depolarization Enhacement of Dendritic Spike Propagation (Bock et al 2022)

Computational model

Data

Name

Depolarization Enhacement of Dendritic Spike Propagation (Bock et al 2022)

Submitter name

Adrian Negrean

Pipeline ID

Model File

dedsp [118689]

Notes

This model shows that small subthreshold depolarization of the soma powerfully enhances the propagation of dendritic spikes, through inactivation of dendritic A-type potassium channels.

Model Neurons

Hippocampus CA1 pyramidal GLU cell Show Other

More Cells

Model Currents

I R Show Other
I T low threshold Show Other
I A Show Other
I h Show Other
I K Show Other
I K,Ca Show Other

Model Receptors

Model Type

Neuron or other electrically excitable cell Show Other

Model Concept

Calcium dynamics Show Other
Synaptic Plasticity Show Other

Simulator software

NEURON Show Other
Python Show Other

Model papers

Bock T, Negrean A, Siegelbaum AS (2022) Show Other

Gene

hg folder name (applicable when in ModelDB hg)

Region Organism

Mouse Show Other

Model ID Number

Gap Junctions

Implemented by

Negrean, Adrian [negreanadrian at gmail.com] Show Other
Bock, Tobias [htb2110 at columbia.edu] Show Other

Public Submitter Email Address

negreanadrian@gmail.com

Other Neuron

Model Neurotransmitters

Other Receptor

Other Current

Other Neurotransmitter

Other Model Type

Other Concept

Other Simulator

Other Implementer

Alternative Version

Citation

Bock, T., Negrean, A., & Siegelbaum, A.S. (2022). Somatic depolarization enhances hippocampal CA1 dendritic spike propagation and distal input-driven synaptic plasticity. Journal of Neuroscience.

Default File Notes

Other Gene

Simulation Platform ID

Has Model View

False

Component

RAM

Hide Auto-launch button

False

Run Protocols

ICG Channel Details

Species

Other categories referring to Depolarization Enhacement of Dendritic Spike Propagation (Bock et al 2022)

Revisions:	9
Last Time:	3/12/2022 1:31:07 PM
Reviewer:
Owner:	Tom Morse - MoldelDB admin