Canavier CC. (1999). Sodium dynamics underlying burst firing and putative mechanisms for the regulation of the firing pattern in midbrain dopamine neurons: a computational approach. Journal of computational neuroscience. 6 [PubMed]

• Midbrain dopamine neuron: firing patterns (Canavier 1999) [Model]

Canavier CC, Landry RS. (2006). An increase in AMPA and a decrease in SK conductance increase burst firing by different mechanisms in a model of a dopamine neuron in vivo. Journal of neurophysiology. 96 [PubMed]

• Differential modulation of pattern and rate in a dopamine neuron model (Canavier and Landry 2006) [Model]

Canavier CC, Oprisan SA, Callaway JC, Ji H, Shepard PD. (2007). Computational model predicts a role for ERG current in repolarizing plateau potentials in dopamine neurons: implications for modulation of neuronal activity. Journal of neurophysiology. 98 [PubMed]

• ERG current in repolarizing plateau potentials in dopamine neurons (Canavier et al 2007) [Model]

Cutsuridis V, Perantonis S. (2006). A neural network model of Parkinson's disease bradykinesia. Neural networks : the official journal of the International Neural Network Society. 19 [PubMed]

• A neural model of Parkinson`s disease (Cutsuridis and Perantonis 2006, Cutsuridis 2006, 2007) [Model]

Dougalis AG, Matthews GAC, Liss B, Ungless MA. (2017). Ionic currents influencing spontaneous firing and pacemaker frequency in dopamine neurons of the ventrolateral periaqueductal gray and dorsal raphe nucleus (vlPAG/DRN): A voltage-clamp and computational modelling study. Journal of computational neuroscience. 42 [PubMed]

• Dopamine neuron of the vent. periaqu. gray and dors. raphe nucleus (vlPAG/DRN) (Dougalis et al 2017) [Model]

Komendantov AO, Komendantova OG, Johnson SW, Canavier CC. (2004). A modeling study suggests complementary roles for GABAA and NMDA receptors and the SK channel in regulating the firing pattern in midbrain dopamine neurons. Journal of neurophysiology. 91 [PubMed]

• Regulation of the firing pattern in dopamine neurons (Komendantov et al 2004) [Model]

Kuznetsov AS, Kopell NJ, Wilson CJ. (2006). Transient high-frequency firing in a coupled-oscillator model of the mesencephalic dopaminergic neuron. Journal of neurophysiology. 95 [PubMed]

• Dopaminergic cell bursting model (Kuznetsov et al 2006) [Model]

Kuznetsova AY, Huertas MA, Kuznetsov AS, Paladini CA, Canavier CC. (2010). Regulation of firing frequency in a computational model of a midbrain dopaminergic neuron. Journal of computational neuroscience. 28 [PubMed]

• Regulation of firing frequency in a midbrain dopaminergic neuron model (Kuznetsova et al. 2010) [Model]

Li YX, Bertram R, Rinzel J. (1996). Modeling N-methyl-D-aspartate-induced bursting in dopamine neurons. Neuroscience. 71 [PubMed]

• Bursting in dopamine neurons (Li YX et al 1996) [Model]

Liu CY, Xiao C, Fraser SE, Lester HA, Koos DS. (2012). Electrophysiological characterization of Grueneberg ganglion olfactory neurons: spontaneous firing, sodium conductance, and hyperpolarization-activated currents. Journal of neurophysiology. 108 [PubMed]

• Model of repetitive firing in Grueneberg ganglion olfactory neurons (Liu et al., 2012) [Model]

Meza RC, López-Jury L, Canavier CC, Henny P. (2018). Role of the Axon Initial Segment in the Control of Spontaneous Frequency of Nigral Dopaminergic Neurons In Vivo. The Journal of neuroscience : the official journal of the Society for Neuroscience. 38 [PubMed]

• Role of the AIS in the control of spontaneous frequency of dopaminergic neurons (Meza et al 2017) [Model]

Migliore M, Cannia C, Canavier CC. (2008). A modeling study suggesting a possible pharmacological target to mitigate the effects of ethanol on reward-related dopaminergic signaling. Journal of neurophysiology. 99 [PubMed]

• Nigral dopaminergic neurons: effects of ethanol on Ih (Migliore et al. 2008) [Model]

Morozova EO et al. (2016). Contribution of synchronized GABAergic neurons to dopaminergic neuron firing and bursting. Journal of neurophysiology. 116 [PubMed]

• Excitability of DA neurons and their regulation by synaptic input (Morozova et al. 2016a, 2016b) [Model]

Muddapu VR, Mandali A, Chakravarthy VS, Ramaswamy S. (2019). A Computational Model of Loss of Dopaminergic Cells in Parkinson's Disease Due to Glutamate-Induced Excitotoxicity. Frontiers in neural circuits. 13 [PubMed]

• Excitotoxic loss of dopaminergic cells in PD (Muddapu et al 2019) [Model]

Phillips AJ, Robinson PA. (2007). A quantitative model of sleep-wake dynamics based on the physiology of the brainstem ascending arousal system. Journal of biological rhythms. 22 [PubMed]

• Quantitative model of sleep-wake dynamics (Phillips & Robinson 2007) [Model]

Rumbell T, Kozloski J. (2019). Dimensions of control for subthreshold oscillations and spontaneous firing in dopamine neurons PLOS Computational Biology. 15

• Control of oscillations and spontaneous firing in dopamine neurons (Rumbell & Kozloski 2019) [Model]

Ursino M, Baston C. (2018). Aberrant learning in Parkinson's disease: A neurocomputational study on bradykinesia. The European journal of neuroscience. 47 [PubMed]

• A basal ganglia model of aberrant learning (Ursino et al. 2018) [Model]

Yu N, Canavier CC. (2015). A Mathematical Model of a Midbrain Dopamine Neuron Identifies Two Slow Variables Likely Responsible for Bursts Evoked by SK Channel Antagonists and Terminated by Depolarization Block. Journal of mathematical neuroscience. 5 [PubMed]

• Phase plane reveals two slow variables in midbrain dopamine neuron bursts (Yu and Canavier, 2015) [Model]