Interaction of leak and IMI conductance on the STG over broad temperature range (Stadele et al 2015)

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Accession:184404
The ZIP file contains a Hodgkin-Huxley based circuit model and the simulation environment MadSim used to study the interaction of leak and IMI on the gastric mill network of the crab (Cancer borealis) as represented in (C. Städele, S. Heigele and W. Stein, 2015) MadSim, the simulation environment used for this study, is freeware and included in the package.
Reference:
1 . Stein W, Straub O, Ausborn J, Mader W, Wolf H (2008) Motor pattern selection by combinatorial code of interneuronal pathways. J Comput Neurosci 25:543-61 [PubMed]
2 . Ausborn J, Stein W, Wolf H (2007) Frequency control of motor patterning by negative sensory feedback. J Neurosci 27:9319-28 [PubMed]
3 . Städele C, Heigele S, Stein W (2015) Neuromodulation to the Rescue: Compensation of Temperature-Induced Breakdown of Rhythmic Motor Patterns via Extrinsic Neuromodulatory Input. PLoS Biol 13:e1002265 [PubMed]
4 . Daur N, Diehl F, Mader W, Stein W (2012) The stomatogastric nervous system as a model for studying sensorimotor interactions in real-time closed-loop conditions. Front Comput Neurosci 6:13 [PubMed]
Citations  Citation Browser
Model Information (Click on a link to find other models with that property)
Model Type: Realistic Network;
Brain Region(s)/Organism: Stomatogastric ganglion;
Cell Type(s): Stomatogastric Ganglion (STG) Lateral Gastric (LG) cell;
Channel(s): I MI;
Gap Junctions:
Receptor(s):
Gene(s):
Transmitter(s): CabTRP 1a;
Simulation Environment: MadSim;
Model Concept(s): Temporal Pattern Generation; Invertebrate; Neuromodulation;
Implementer(s):
Search NeuronDB for information about:  I MI; CabTRP 1a;
/
StaedeleEtAl2015
madSim 6.11
parameter
standard-kanaele
! bloss oinr.knl *
1 kanal.knl *
caK-Kanal.kca
dialog texte de.txt
dialog texte en.txt
form parameter.txt
form parameter.xls
GB.channel *
GB.channel.description *
GB.channel.description.doc *
gb-parameter.txt *
gb-parameter.xls *
HH.channel *
HH.channel.description *
HH.channel.description.doc *
ioTabelle langsam.txt *
ioTabelle normal.txt *
ioTabelle.txt *
izhikevich-typen.txt *
izhikevich-typen.txt.orig *
meldung texte de.txt
meldung texte en.txt
meldung texte en.txt.bak
neuronParameter.xls
ONOFF.channel *
ONOFF.channel.description *
ONOFF.channel.description.doc *
ONOFF.NEU *
reizFuerServerBetrieb kurz.txt *
reizFuerServerBetrieb original.txt *
reizFuerServerBetrieb.txt *
STANDARD.CA *
STANDARD.GEN *
STANDARD.K *
STANDARD.NA *
STANDARD.NEU *
STANDARD.ON *
standardap 2000ms.TXT *
standardap 200ms.txt *
standardap original.TXT *
standardap.txt *
swim example.txt *
SWIM.channel *
SWIM.channel.description *
SWIM.channel.description.doc *
tooltip texte de.txt
tooltip texte en.txt
tooltip texte en.txt.bak
userDef SWIM kanal original.txt *
                            
/************************************************************************************************************************

	PROGRAM:	BIOSIM

	FILENAME:	HH.channel.description

	PURPOSE:	description of all parameters used in the HH.channel file

	35 parameter

************************************************************************************************************************/

HH_NA_E			- equilibrium potential of sodium channel
HH_NA_G			- conductance of sodium channel
HH_K_E			- equilibrium potential of potassium channel
HH_K_G			- conductance of potassium channel
HH_Form_Alpha_M		- form parameter for gate variable m, alpha term
HH_AalphaM		- rate constant
HH_V0alphaM		- half maximum potential
HH_BalphaM		- step width
HH_Form_Beta_M		- form parameter for gate variable m, beta term
HH_AbetaM		- rate constant
HH_V0betaM		- half maximum potential
HH_BbetaM		- step width
HH_M_POWER		- power of gate variable m
HH_M_INITIAL		- initial value of gate variable m
HH_Form_Alpha_H		- form parameter for gate variable h, alpha term
HH_AalphaH		- rate constant
HH_V0alphaH		- half maximum potential
HH_BalphaH		- step width
HH_Form_Beta_H		- form parameter for gate variable h, beta term
HH_AbetaH		- rate constant
HH_V0betaH		- half maximum potential
HH_BbetaH		- step width
HH_H_POWER		- power of gate variable h
HH_H_INITIAL		- initial value of gate variable h
HH_Form_Alpha_N		- form parameter for gate variable n, alpha term
HH_AalphaN		- rate constant
HH_V0alphaN		- half maximum potential
HH_BalphaN		- step width
HH_Form_Beta_N		- form parameter for gate variable n, beta term
HH_AbetaN		- rate constant
HH_V0betaN		- half maximum potential
HH_BbetaN		- step width
HH_N_POWER		- power of gate variable n
HH_N_INITIAL		- initial value of gate variable n
HH_SPIKE_THRESHOLD	- spike threshold, used only for spike identification