Akemann W, Knöpfel T (2006) Interaction of Kv3 potassium channels and resurgent sodium current influences the rate of spontaneous firing of Purkinje neurons. J Neurosci 26:4602-12 [Journal] [PubMed]

•	Cerebellar purkinje cell: interacting Kv3 and Na currents influence firing (Akemann, Knopfel 2006) [Model]

Arsiero M, Lüscher HR, Lundstrom BN, Giugliano M (2007) The impact of input fluctuations on the frequency-current relationships of layer 5 pyramidal neurons in the rat medial prefrontal cortex. J Neurosci 27:3274-84 [Journal] [PubMed]

•	Input Fluctuations effects on f-I curves (Arsiero et al. 2007) [Model]

Buckingham SD, Spencer AN (2002) Role of high-voltage activated potassium currents in high-frequency neuronal firing: evidence from a basal metazoan. J Neurophysiol 88:861-8 [Journal] [PubMed]

Damodaran S, Evans RC, Blackwell KT (2014) Synchronized firing of fast-spiking interneurons is critical to maintain balanced firing between direct and indirect pathway neurons of the striatum. J Neurophysiol 111:836-48 [Journal] [PubMed]

•	Synchronicity of fast-spiking interneurons balances medium-spiny neurons (Damodaran et al. 2014) [Model]

Fernandez FR, Mehaffey WH, Molineux ML, Turner RW (2005) High-threshold K+ current increases gain by offsetting a frequency-dependent increase in low-threshold K+ current. J Neurosci 25:363-71 [Journal] [PubMed]

•	Pyramidal neurons: IKHT offsets activation of IKLT to increase gain (Fernandez et al 2005) [Model]

Geisler C, Brunel N, Wang XJ (2005) Contributions of intrinsic membrane dynamics to fast network oscillations with irregular neuronal discharges. J Neurophysiol 94:4344-61 [Journal] [PubMed]

Golomb D, Donner K, Shacham L, Shlosberg D, Amitai Y, Hansel D (2007) Mechanisms of firing patterns in fast-spiking cortical interneurons. PLoS Comput Biol 3:e156 [Journal] [PubMed]

•	Fast-spiking cortical interneuron (Golomb et al. 2007) [Model]

Gu N, Vervaeke K, Storm JF (2007) BK potassium channels facilitate high-frequency firing and cause early spike frequency adaptation in rat CA1 hippocampal pyramidal cells. J Physiol 580:859-82 [Journal] [PubMed]

Hemond P, Epstein D, Boley A, Migliore M, Ascoli GA, Jaffe DB (2008) Distinct classes of pyramidal cells exhibit mutually exclusive firing patterns in hippocampal area CA3b. Hippocampus 18:411-24 [Journal] [PubMed]

•	CA3 pyramidal neuron: firing properties (Hemond et al. 2008) [Model]

Huang CW, Tsai JJ, Huang CC, Wu SN (2009) Experimental and simulation studies on the mechanisms of levetiracetam-mediated inhibition of delayed-rectifier potassium current (KV3.1): contribution to the firing of action potentials. J Physiol Pharmacol 60:37-47 [Journal] [PubMed]

•	Simulation studies on mechanisms of levetiracetam-mediated inhibition of IK(DR) (Huang et al. 2009) [Model]

Jaffe DB, Brenner R (2018) A computational model for how the fast afterhyperpolarization paradoxically increases gain in regularly firing neurons. J Neurophysiol 119:1506-1520 [Journal] [PubMed]

•	Paradoxical effect of fAHP amplitude on gain in dentate gyrus granule cells (Jaffe & Brenner 2018) [Model]

Jolivet R, Gerstner W (2004) Predicting spike times of a detailed conductance-based neuron model driven by stochastic spike arrival. J Physiol Paris 98:442-51 [Journal] [PubMed]

Jolivet R, Lewis TJ, Gerstner W (2004) Generalized integrate-and-fire models of neuronal activity approximate spike trains of a detailed model to a high degree of accuracy. J Neurophysiol 92:959-76 [Journal] [PubMed]

•	Spike Response Model simulator (Jolivet et al. 2004, 2006, 2008) [Model]

Jolivet R, Rauch A, Lüscher HR, Gerstner W (2006) Predicting spike timing of neocortical pyramidal neurons by simple threshold models. J Comput Neurosci 21:35-49 [Journal] [PubMed]

•	Spike Response Model simulator (Jolivet et al. 2004, 2006, 2008) [Model]

Kitano K, Fukai T (2007) Variability v.s. synchronicity of neuronal activity in local cortical network models with different wiring topologies. J Comput Neurosci 23:237-50 [Journal] [PubMed]

Kotaleski JH, Plenz D, Blackwell KT (2006) Using potassium currents to solve signal-to-noise problems in inhibitory feedforward networks of the striatum. J Neurophysiol 95:331-41 [Journal] [PubMed]

•	FS Striatal interneuron: K currents solve signal-to-noise problems (Kotaleski et al 2006) [Model]

Lien CC, Martina M, Schultz JH, Ehmke H, Jonas P (2002) Gating, modulation and subunit composition of voltage-gated K(+) channels in dendritic inhibitory interneurones of rat hippocampus. J Physiol 538:405-19 [PubMed]

•	CA1 interneuron: K currents (Lien et al 2002) [Model]

Pfeuty B, Mato G, Golomb D, Hansel D (2003) Electrical synapses and synchrony: the role of intrinsic currents. J Neurosci 23:6280-94 [PubMed]

Prescott SA, De Koninck Y, Sejnowski TJ (2008) Biophysical basis for three distinct dynamical mechanisms of action potential initiation. PLoS Comput Biol 4:e1000198 [Journal] [PubMed]

•	Dynamics of Spike Initiation (Prescott et al. 2008) [Model]

Prescott SA, Ratté S, De Koninck Y, Sejnowski TJ (2008) Pyramidal neurons switch from integrators in vitro to resonators under in vivo-like conditions. J Neurophysiol 100:3030-42 [Journal] [PubMed]

•	Pyramidal neurons switch from integrators to resonators (Prescott et al. 2008) [Model]

Tikidji-Hamburyan RA, Martínez JJ, White JA, Canavier CC (2015) Resonant Interneurons Can Increase Robustness of Gamma Oscillations. J Neurosci 35:15682-95 [Journal] [PubMed]

•	PIR gamma oscillations in network of resonators (Tikidji-Hamburyan et al. 2015) [Model]

Vida I, Bartos M, Jonas P (2006) Shunting inhibition improves robustness of gamma oscillations in hippocampal interneuron networks by homogenizing firing rates. Neuron 49:107-17 [Journal] [PubMed]