STD-dependent and independent encoding of Input irregularity as spike rate (Luthman et al. 2011)

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Accession:144523
"... We use a conductance-based model of a CN neuron to study the effect of the regularity of Purkinje cell spiking on CN neuron activity. We find that increasing the irregularity of Purkinje cell activity accelerates the CN neuron spike rate and that the mechanism of this recoding of input irregularity as output spike rate depends on the number of Purkinje cells converging onto a CN neuron. ..."
Reference:
1 . Luthman J, Hoebeek FE, Maex R, Davey N, Adams R, De Zeeuw CI, Steuber V (2011) STD-dependent and independent encoding of input irregularity as spike rate in a computational model of a cerebellar nucleus neuron. Cerebellum 10:667-82 [PubMed]
Model Information (Click on a link to find other models with that property)
Model Type: Neuron or other electrically excitable cell;
Brain Region(s)/Organism:
Cell Type(s): Cerebellum deep nucleus neuron;
Channel(s): I Na,p; I Na,t; I L high threshold; I T low threshold; I K; I h; I K,Ca;
Gap Junctions:
Receptor(s):
Gene(s):
Transmitter(s):
Simulation Environment: NEURON;
Model Concept(s): Temporal Pattern Generation; Short-term Synaptic Plasticity;
Implementer(s): Luthman, Johannes [jwluthman at gmail.com];
Search NeuronDB for information about:  I Na,p; I Na,t; I L high threshold; I T low threshold; I K; I h; I K,Ca;
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LuthmanEtAl2011
readme.txt
CaConc.mod *
CaHVA.mod *
CalConc.mod *
CaLVA.mod *
DCNsyn.mod *
DCNsynGABA.mod *
DCNsynNMDA.mod *
fKdr.mod *
GammaStim.mod *
h.mod *
NaF.mod *
NaP.mod *
pasDCN.mod *
SK.mod *
sKdr.mod *
TNC.mod *
DCN_mechs.hoc
DCN_morph.hoc *
DCN_recording.hoc
DCN_run.hoc
DCN_simulation.hoc
mosinit.hoc
OutputDCN_soma_1s_ap.dat
OutputDCN_soma_1s_time.dat
OutputDCN_soma_1s_trace.dat
                            
TITLE Fast delayed rectifier (fKdr) of deep cerebellar nucleus (DCN) neuron
COMMENT
    Translated from GENESIS by Johannes Luthman and Volker Steuber.
ENDCOMMENT

NEURON {
	SUFFIX fKdr
	USEION k READ ek WRITE ik
	RANGE gbar, m, ik
	GLOBAL qdeltat
}

UNITS {
	(mA) = (milliamp)
	(mV) = (millivolt)
}

PARAMETER {
    qdeltat = 1
    gbar = 1e-5 (siemens/cm2)
}

ASSIGNED {
	v (mV)
	ek (mV)
	ik (mA/cm2)
	minf
	taum (ms)
}

STATE {
	m
}

INITIAL {
    rate(v)
    m = minf
}

BREAKPOINT {
    SOLVE states METHOD cnexp
	ik = gbar * m*m*m*m * (v - ek)
}

DERIVATIVE states {
	rate(v)
	m' = (minf - m) / taum
}

PROCEDURE rate(v(mV)) {
	TABLE minf, taum FROM -150 TO 100 WITH 300
    minf = 1 / (1 + exp((v + 40) / -7.8))
    taum = 13.9 / (exp((v + 40) / 12) + exp((v + 40) / -13)) + 0.1
    taum = taum / qdeltat
}

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