Inverse stochastic resonance of cerebellar Purkinje cell (Buchin et al. 2016)


Buchin A, Rieubland S, Häusser M, Gutkin BS, Roth A. (2016). Inverse Stochastic Resonance in Cerebellar Purkinje Cells. PLoS computational biology. 12 [PubMed]

See more from authors: Buchin A · Rieubland S · Häusser M · Gutkin BS · Roth A

References and models cited by this paper

Badel L et al. (2008). Dynamic I-V curves are reliable predictors of naturalistic pyramidal-neuron voltage traces. Journal of neurophysiology. 99 [PubMed]

Brette R, Gerstner W. (2005). Adaptive exponential integrate-and-fire model as an effective description of neuronal activity. Journal of neurophysiology. 94 [PubMed]

Camalet S, Duke T, Jülicher F, Prost J. (2000). Auditory sensitivity provided by self-tuned critical oscillations of hair cells. Proceedings of the National Academy of Sciences of the United States of America. 97 [PubMed]

Chizhov AV. (2002). [A model for evoked activity of hippocampal neuronal population]. Biofizika. 47 [PubMed]

Clopath C, Nadal JP, Brunel N. (2012). Storage of correlated patterns in standard and bistable Purkinje cell models. PLoS computational biology. 8 [PubMed]

Couto J, Linaro D, De Schutter E, Giugliano M. (2015). On the firing rate dependency of the phase response curve of rat Purkinje neurons in vitro. PLoS computational biology. 11 [PubMed]

Davie JT et al. (2006). Dendritic patch-clamp recording. Nature protocols. 1 [PubMed]

De Schutter E, Bower JM. (1994). An active membrane model of the cerebellar Purkinje cell. I. Simulation of current clamps in slice. Journal of neurophysiology. 71 [PubMed]

Dean P, Porrill J. (2011). Evaluating the adaptive-filter model of the cerebellum. The Journal of physiology. 589 [PubMed]

Dean P, Porrill J, Ekerot CF, Jörntell H. (2010). The cerebellar microcircuit as an adaptive filter: experimental and computational evidence. Nature reviews. Neuroscience. 11 [PubMed]

Dipoppa M, Gutkin BS. (2013). Flexible frequency control of cortical oscillations enables computations required for working memory. Proceedings of the National Academy of Sciences of the United States of America. 110 [PubMed]

Fourcaud-Trocmé N, Hansel D, van Vreeswijk C, Brunel N. (2003). How spike generation mechanisms determine the neuronal response to fluctuating inputs. The Journal of neuroscience : the official journal of the Society for Neuroscience. 23 [PubMed]

Guo D. (2011). Inhibition of rhythmic spiking by colored noise in neural systems. Cognitive neurodynamics. 5 [PubMed]

Gutkin B, Jost J, Tuckwell HC. (2008). Random perturbations of spiking activity in a pair of coupled neurons. Theory in biosciences = Theorie in den Biowissenschaften. 127 [PubMed]

Gutkin BS, Jost J, Tuckwell HC. (2009). Inhibition of rhythmic neural spiking by noise: the occurrence of a minimum in activity with increasing noise. Die Naturwissenschaften. 96 [PubMed]

Hudspeth AJ. (2014). Integrating the active process of hair cells with cochlear function. Nature reviews. Neuroscience. 15 [PubMed]

Johansson F, Jirenhed DA, Rasmussen A, Zucca R, Hesslow G. (2014). Memory trace and timing mechanism localized to cerebellar Purkinje cells. Proceedings of the National Academy of Sciences of the United States of America. 111 [PubMed]

Libster AM, Title B, Yarom Y. (2015). Corticotropin-releasing factor increases Purkinje neuron excitability by modulating sodium, potassium, and Ih currents. Journal of neurophysiology. 114 [PubMed]

Loewenstein Y et al. (2005). Bistability of cerebellar Purkinje cells modulated by sensory stimulation. Nature neuroscience. 8 [PubMed]

London M, Schreibman A, Häusser M, Larkum ME, Segev I. (2002). The information efficacy of a synapse. Nature neuroscience. 5 [PubMed]

Mainen ZF, Sejnowski TJ. (1995). Reliability of spike timing in neocortical neurons. Science (New York, N.Y.). 268 [PubMed]

McDonnell MD, Ward LM. (2011). The benefits of noise in neural systems: bridging theory and experiment. Nature reviews. Neuroscience. 12 [PubMed]

Norris SA, Greger B, Hathaway EN, Thach WT. (2004). Purkinje cell spike firing in the posterolateral cerebellum: correlation with visual stimulus, oculomotor response, and error feedback. Journal of neurophysiology. 92 [PubMed]

Oldfield CS, Marty A, Stell BM. (2010). Interneurons of the cerebellar cortex toggle Purkinje cells between up and down states. Proceedings of the National Academy of Sciences of the United States of America. 107 [PubMed]

Ospeck M, Eguíluz VM, Magnasco MO. (2001). Evidence of a Hopf bifurcation in frog hair cells. Biophysical journal. 80 [PubMed]

Ostojic S et al. (2015). Neuronal morphology generates high-frequency firing resonance. The Journal of neuroscience : the official journal of the Society for Neuroscience. 35 [PubMed]

Paydarfar D, Forger DB, Clay JR. (2006). Noisy inputs and the induction of on-off switching behavior in a neuronal pacemaker. Journal of neurophysiology. 96 [PubMed]

Penner MJ, Zhang T. (1997). Prevalence of spontaneous otoacoustic emissions in adults revisited. Hearing research. 103 [PubMed]

Phoka E, Cuntz H, Roth A, Häusser M. (2010). A new approach for determining phase response curves reveals that Purkinje cells can act as perfect integrators. PLoS computational biology. 6 [PubMed]

Rinzel J, Ermentrout B. (1998). Analysis of neural excitability and oscillations. Methods In Neuronal Modeling 2nd Edition.

Roitman AV, Pasalar S, Ebner TJ. (2009). Single trial coupling of Purkinje cell activity to speed and error signals during circular manual tracking. Experimental brain research. 192 [PubMed]

Rokni D, Tal Z, Byk H, Yarom Y. (2009). Regularity, variability and bi-stability in the activity of cerebellar purkinje cells. Frontiers in cellular neuroscience. 3 [PubMed]

Roth A, Häusser M. (2001). Compartmental models of rat cerebellar Purkinje cells based on simultaneous somatic and dendritic patch-clamp recordings. The Journal of physiology. 535 [PubMed]

Schonewille M et al. (2006). Purkinje cells in awake behaving animals operate at the upstate membrane potential. Nature neuroscience. 9 [PubMed]

Shin SL et al. (2007). Regular patterns in cerebellar Purkinje cell simple spike trains. PloS one. 2 [PubMed]

Stiefel KM, Gutkin BS, Sejnowski TJ. (2008). Cholinergic neuromodulation changes phase response curve shape and type in cortical pyramidal neurons. PloS one. 3 [PubMed]

Tateno T, Harsch A, Robinson HP. (2004). Threshold firing frequency-current relationships of neurons in rat somatosensory cortex: type 1 and type 2 dynamics. Journal of neurophysiology. 92 [PubMed]

Touboul J, Brette R. (2008). Dynamics and bifurcations of the adaptive exponential integrate-and-fire model. Biological cybernetics. 99 [PubMed]

Tuckwell HC, Jost J. (2010). Weak noise in neurons may powerfully inhibit the generation of repetitive spiking but not its propagation. PLoS computational biology. 6 [PubMed]

Tuckwell HC, Jost J, Gutkin BS. (2009). Inhibition and modulation of rhythmic neuronal spiking by noise. Physical review. E, Statistical, nonlinear, and soft matter physics. 80 [PubMed]

Walter JT, Khodakhah K. (2006). The linear computational algorithm of cerebellar Purkinje cells. The Journal of neuroscience : the official journal of the Society for Neuroscience. 26 [PubMed]

Wang F, Xu Q, Wang W, Takano T, Nedergaard M. (2012). Bergmann glia modulate cerebellar Purkinje cell bistability via Ca2+-dependent K+ uptake. Proceedings of the National Academy of Sciences of the United States of America. 109 [PubMed]

Wilms CD, Häusser M. (2015). Reading out a spatiotemporal population code by imaging neighbouring parallel fibre axons in vivo. Nature communications. 6 [PubMed]

Witter L, De Zeeuw CI. (2015). Regional functionality of the cerebellum. Current opinion in neurobiology. 33 [PubMed]

Yartsev MM, Givon-Mayo R, Maller M, Donchin O. (2009). Pausing purkinje cells in the cerebellum of the awake cat. Frontiers in systems neuroscience. 3 [PubMed]

Zhou H, Voges K, Lin Z, Ju C, Schonewille M. (2015). Differential Purkinje cell simple spike activity and pausing behavior related to cerebellar modules. Journal of neurophysiology. 113 [PubMed]

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Geminiani A, Casellato C, D'Angelo E, Pedrocchi A. (2019). Complex Electroresponsive Dynamics in Olivocerebellar Neurons Represented With Extended-Generalized Leaky Integrate and Fire Models. Frontiers in computational neuroscience. 13 [PubMed]

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