Advanced search
SenseLab
SimToolDB
ModelDB Help
User account
Login
Register
Find models by
Model name
First author
Each author
Region(circuits)
Find models for
Cell type
Current
Receptor
Gene
Transmitters
Concept
Simulators
Methods
Find models of
Realistic Networks
Neurons
Electrical synapses (gap junctions)
Chemical synapses
Ion channels
Neuromuscular junctions
Axons
Pathophysiology
Other resources
SenseLab mailing list
ModelDB related resources
Computational neuroscience ecosystem
Models in a git repository
Inferring connection proximity in electrically coupled networks (Cali et al. 2007)
Download zip file
Help downloading and running models
Model Information
Model File
Citations
Simulation Platform
Accession:
94321
In order to explore electrical coupling in the nervous system and its network-level organization, it is imperative to map the electrical synaptic microcircuits, in analogy with in vitro studies on monosynaptic and disynaptic chemical coupling. However, walking from cell to cell over large distances with a glass pipette is challenging, and microinjection of (fluorescent) dyes diffusing through gap-junctions remains so far the only method available to decipher such microcircuits even though technical limitations exist. Based on circuit theory, we derived analytical descriptions of the AC electrical coupling in networks of isopotential cells. We then proposed an operative electrophysiological protocol to distinguish between direct electrical connections and connections involving one or more intermediate cells. This method allows inferring the number of intermediate cells, generalizing the conventional coupling coefficient, which provides limited information. We provide here some analysis and simulation scripts that used to test our method through computer simulations, in vitro recordings, theoretical and numerical methods. Key words: Gap-Junctions; Electrical Coupling; Networks; ZAP current; Impedance.
Reference:
1 .
Calì C, Berger TK, Pignatelli M, Carleton A, Markram H, Giugliano M (2008) Inferring connection proximity in networks of electrically coupled cells by subthreshold frequency response analysis.
J Comput Neurosci
24
:330-45
[
PubMed
]
Model Information
(Click on a link to find other models with that property)
Model Type:
Neuron or other electrically excitable cell;
Glia;
Brain Region(s)/Organism:
Cell Type(s):
Channel(s):
I Na,t;
I K;
I Potassium;
Gap Junctions:
Gap junctions;
Receptor(s):
Gene(s):
Transmitter(s):
Simulation Environment:
NEURON;
MATLAB;
PSpice;
Sspice Symbolic SPICE;
Model Concept(s):
Methods;
Implementer(s):
Giugliano, Michele [mgiugliano at gmail.com];
Search NeuronDB
for information about:
I Na,t
;
I K
;
I Potassium
;
/
chain_1d
AnalysisGUI
matlab
Fitme.fig
Fitme.m
File not selected
<- Select file from this column.
Loading data, please wait...
Simulation Platform