Geminiani A, Pedrocchi A, D'Angelo E, Casellato C. (2019). Response Dynamics in an Olivocerebellar Spiking Neural Network With Non-linear Neuron Properties. Frontiers in computational neuroscience. 13 [PubMed]

• Complex dynamics: reproducing Golgi cell electroresponsiveness (Geminiani et al 2018, 2019ab) [Model]

Luque NR, Garrido JA, Carrillo RR, D'Angelo E, Ros E. (2014). Fast convergence of learning requires plasticity between inferior olive and deep cerebellar nuclei in a manipulation task: a closed-loop robotic simulation. Frontiers in computational neuroscience. 8 [PubMed]

• Fast convergence of cerebellar learning (Luque et al. 2015) [Model]

Ovsepian SV et al. (2013). A defined heteromeric KV1 channel stabilizes the intrinsic pacemaking and regulates the output of deep cerebellar nuclear neurons to thalamic targets. The Journal of physiology. 591 [PubMed]

• KV1 channel governs cerebellar output to thalamus (Ovsepian et al. 2013) [Model]

Steuber V, Jaeger D. (2013). Modeling the generation of output by the cerebellar nuclei. Neural networks : the official journal of the International Neural Network Society. 47 [PubMed]

• Robust transmission in the inhibitory Purkinje Cell to Cerebellar Nuclei pathway (Abbasi et al 2017) [Model]

Sudhakar SK, Torben-Nielsen B, De Schutter E. (2015). Cerebellar Nuclear Neurons Use Time and Rate Coding to Transmit Purkinje Neuron Pauses. PLoS computational biology. 11 [PubMed]

• Cerebellar nuclear neuron (Sudhakar et al., 2015) [Model]

Torben-Nielsen B, Segev I, Yarom Y. (2012). The generation of phase differences and frequency changes in a network model of inferior olive subthreshold oscillations. PLoS computational biology. 8 [PubMed]

• Inferior Olive, subthreshold oscillations (Torben-Nielsen, Segev, Yarom 2012) [Model]

Zang Y, Hong S, De Schutter E. (2020). Firing rate-dependent phase responses of Purkinje cells support transient oscillations. eLife. 9 [PubMed]

• Purkinje neuron network (Zang et al. 2020) [Model]