Chan CS, Shigemoto R, Mercer JN, Surmeier DJ. (2004). HCN2 and HCN1 channels govern the regularity of autonomous pacemaking and synaptic resetting in globus pallidus neurons. The Journal of neuroscience : the official journal of the Society for Neuroscience. 24 [PubMed]

Fountas Z, Shanahan M. (2017). The role of cortical oscillations in a spiking neural network model of the basal ganglia. PloS one. 12 [PubMed]

• Cortical oscillations and the basal ganglia (Fountas & Shanahan 2017) [Model]

Fujita T, Fukai T, Kitano K. (2012). Influences of membrane properties on phase response curve and synchronization stability in a model globus pallidus neuron. Journal of computational neuroscience. 32 [PubMed]

• Phase response curve of a globus pallidal neuron (Fujita et al. 2011) [Model]

Günay C, Edgerton JR, Jaeger D. (2008). Channel density distributions explain spiking variability in the globus pallidus: a combined physiology and computer simulation database approach. The Journal of neuroscience : the official journal of the Society for Neuroscience. 28 [PubMed]

• Globus pallidus multi-compartmental model neuron with realistic morphology (Gunay et al. 2008) [Model]

Hahn PJ, McIntyre CC. (2010). Modeling shifts in the rate and pattern of subthalamopallidal network activity during deep brain stimulation. Journal of computational neuroscience. 28 [PubMed]

• Basal ganglia network model of subthalamic deep brain stimulation (Hahn and McIntyre 2010) [Model]

Hanson JE, Smith Y, Jaeger D. (2004). Sodium channels and dendritic spike initiation at excitatory synapses in globus pallidus neurons. The Journal of neuroscience : the official journal of the Society for Neuroscience. 24 [PubMed]

Humphries MD, Stewart RD, Gurney KN. (2006). A physiologically plausible model of action selection and oscillatory activity in the basal ganglia. The Journal of neuroscience : the official journal of the Society for Neuroscience. 26 [PubMed]

• Spiking neuron model of the basal ganglia (Humphries et al 2006) [Model]

Kopp-Scheinpflug C et al. (2011). The sound of silence: ionic mechanisms encoding sound termination. Neuron. 71 [PubMed]

• Superior paraolivary nucleus neuron (Kopp-Scheinpflug et al. 2011) [Model]

Liénard J, Girard B. (2014). A biologically constrained model of the whole basal ganglia addressing the paradoxes of connections and selection. Journal of computational neuroscience. 36 [PubMed]

• Biologically Constrained Basal Ganglia model (BCBG model) (Lienard, Girard 2014) [Model]

Pascual A, Modolo J, Beuter A. (2006). Is a computational model useful to understand the effect of deep brain stimulation in Parkinson's disease? Journal of integrative neuroscience. 5 [PubMed]

• Study of augmented Rubin and Terman 2004 deep brain stim. model in Parkinsons (Pascual et al. 2006) [Model]

Rubchinsky LL, Kopell N, Sigvardt KA. (2003). Modeling facilitation and inhibition of competing motor programs in basal ganglia subthalamic nucleus-pallidal circuits. Proceedings of the National Academy of Sciences of the United States of America. 100 [PubMed]

So RQ, Kent AR, Grill WM. (2012). Relative contributions of local cell and passing fiber activation and silencing to changes in thalamic fidelity during deep brain stimulation and lesioning: a computational modeling study. Journal of computational neuroscience. 32 [PubMed]

• Basal ganglia-thalamic network model for deep brain stimulation (So et al. 2012) [Model]

Terman D, Rubin JE, Yew AC, Wilson CJ. (2002). Activity patterns in a model for the subthalamopallidal network of the basal ganglia. The Journal of neuroscience : the official journal of the Society for Neuroscience. 22 [PubMed]

• Optimal deep brain stimulation of the subthalamic nucleus-a computational study (Feng et al. 2007) [Model]
• Activity patterns in a subthalamopallidal network of the basal ganglia model (Terman et al 2002) [Model]