Gaussian Process Approach to Spiking Neurons for Inhomogeneous Poisson Inputs

This article presents a new theoretical framework to consider the dynamics of a stochastic spiking neuron model with general membrane response to input spike. We assume that the input spikes obey an inhomogeneous Poisson process. The stochastic process of the membrane potential then becomes a gaussian process. When a general type of the membrane response is assumed, the stochastic process becomes a Markov-gaussian process. We present a calculation method for the membrane potential density and the firing probability density. Our new formulation is the extension of the existing formulation based on diffusion approximation. Although the single Markov assumption of the diffusion approximation simplifies the stochastic process analysis, the calculation is inaccurate when the stochastic process involves a multiple Markov property. We find that the variation of the shape of the membrane response, which has often been ignored in existing stochastic process studies, significantly affects the firing probability. Our approach can consider the reset effect, which has been difficult to deal with by analysis based on the first passage time density.

[1]  S. Rice Mathematical analysis of random noise , 1944 .

[2]  B. Mandelbrot,et al.  RANDOM WALK MODELS FOR THE SPIKE ACTIVITY OF A SINGLE NEURON. , 1964, Biophysical journal.

[3]  R. Stein Some models of neuronal variability. , 1967, Biophysical journal.

[4]  H. Tuckwell,et al.  Accuracy of neuronal interspike times calculated from a diffusion approximation. , 1980, Journal of theoretical biology.

[5]  D. Sherrington Stochastic Processes in Physics and Chemistry , 1983 .

[6]  C. W. Gardiner,et al.  Handbook of stochastic methods - for physics, chemistry and the natural sciences, Second Edition , 1986, Springer series in synergetics.

[7]  John G. Proakis,et al.  Probability, random variables and stochastic processes , 1985, IEEE Trans. Acoust. Speech Signal Process..

[8]  William H. Press,et al.  Numerical Recipes in FORTRAN - The Art of Scientific Computing, 2nd Edition , 1987 .

[9]  Shunsuke Sato,et al.  First-passage-time density and moments of the Ornstein-Uhlenbeck process , 1988 .

[10]  Henry C. Tuckwell,et al.  Introduction to theoretical neurobiology , 1988 .

[11]  Henry C. Tuckwell,et al.  Stochastic processes in the neurosciences , 1989 .

[12]  William H. Press,et al.  Numerical Recipes in C, 2nd Edition , 1992 .

[13]  C. Cepeda,et al.  Differential modulation by dopamine of responses evoked by excitatory amino acids in human cortex , 1992, Synapse.

[14]  William H. Press,et al.  Numerical recipes in C (2nd ed.): the art of scientific computing , 1992 .

[15]  M. Kawato,et al.  Inverse-dynamics model eye movement control by Purkinje cells in the cerebellum , 1993, Nature.

[16]  Abbott,et al.  Asynchronous states in networks of pulse-coupled oscillators. , 1993, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[17]  William R. Softky,et al.  The highly irregular firing of cortical cells is inconsistent with temporal integration of random EPSPs , 1993, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[18]  Michael N. Shadlen,et al.  Noise, neural codes and cortical organization , 1994, Current Opinion in Neurobiology.

[19]  Terrence J. Sejnowski,et al.  RAPID STATE SWITCHING IN BALANCED CORTICAL NETWORK MODELS , 1995 .

[20]  W. Ebeling Stochastic Processes in Physics and Chemistry , 1995 .

[21]  Christof Koch,et al.  Temporal Precision of Spike Trains in Extrastriate Cortex of the Behaving Macaque Monkey , 1999, Neural Computation.

[22]  A. Grinvald,et al.  Dynamics of Ongoing Activity: Explanation of the Large Variability in Evoked Cortical Responses , 1996, Science.

[23]  H. Sompolinsky,et al.  Chaos in Neuronal Networks with Balanced Excitatory and Inhibitory Activity , 1996, Science.

[24]  S. Thorpe,et al.  Speed of processing in the human visual system , 1996, Nature.

[25]  Kenneth D. Miller,et al.  Physiological Gain Leads to High ISI Variability in a Simple Model of a Cortical Regular Spiking Cell , 1997, Neural Computation.

[26]  Shigeru Tanaka,et al.  Stochastic resonance in a model neuron with reset , 1996, physics/9611014.

[27]  H. Markram,et al.  The neural code between neocortical pyramidal neurons depends on neurotransmitter release probability. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[28]  Nicolas Brunel,et al.  Dynamics of a recurrent network of spiking neurons before and following learning , 1997 .

[29]  Wulfram Gerstner,et al.  Reduction of the Hodgkin-Huxley Equations to a Single-Variable Threshold Model , 1997, Neural Computation.

[30]  A. Aertsen,et al.  Spike synchronization and rate modulation differentially involved in motor cortical function. , 1997, Science.

[31]  D. Amit,et al.  Model of global spontaneous activity and local structured activity during delay periods in the cerebral cortex. , 1997, Cerebral cortex.

[32]  Haim Sompolinsky,et al.  Chaotic Balanced State in a Model of Cortical Circuits , 1998, Neural Computation.

[33]  W. Newsome,et al.  The Variable Discharge of Cortical Neurons: Implications for Connectivity, Computation, and Information Coding , 1998, The Journal of Neuroscience.

[34]  M. Kawato,et al.  Temporal firing patterns of Purkinje cells in the cerebellar ventral paraflocculus during ocular following responses in monkeys I. Simple spikes. , 1998, Journal of neurophysiology.

[35]  M. Kawato,et al.  Temporal firing patterns of Purkinje cells in the cerebellar ventral paraflocculus during ocular following responses in monkeys II. Complex spikes. , 1998, Journal of neurophysiology.

[36]  H. Kita,et al.  Effects of dopamine agonists and antagonists on optical responses evoked in rat frontal cortex slices after stimulation of the subcortical white matter , 1999, Experimental Brain Research.

[37]  R. Kempter,et al.  Hebbian learning and spiking neurons , 1999 .

[38]  Wulfram Gerstner,et al.  Spiking neurons , 1999 .

[39]  Ad Aertsen,et al.  Stable propagation of synchronous spiking in cortical neural networks , 1999, Nature.

[40]  Nicolas Brunel,et al.  Fast Global Oscillations in Networks of Integrate-and-Fire Neurons with Low Firing Rates , 1999, Neural Computation.

[41]  Anthony N. Burkitt,et al.  Analysis of Integrate-and-Fire Neurons: Synchronization of Synaptic Input and Spike Output , 1999, Neural Computation.

[42]  T. Geisel,et al.  Markov analysis of stochastic resonance in a periodically driven integrate-and-fire neuron. , 1998, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[43]  Wulfram Gerstner,et al.  Population Dynamics of Spiking Neurons: Fast Transients, Asynchronous States, and Locking , 2000, Neural Computation.

[44]  T. Sejnowski,et al.  Dopamine-mediated stabilization of delay-period activity in a network model of prefrontal cortex. , 2000, Journal of neurophysiology.

[45]  Ken-ichi Amemori Ensemble Average and Variance of a Stochastic Spiking Neuron Model , 2000 .

[46]  Anthony N. Burkitt,et al.  Calculation of Interspike Intervals for Integrate-and-Fire Neurons with Poisson Distribution of Synaptic Inputs , 2000, Neural Computation.

[47]  Wulfram Gerstner,et al.  Noise in Integrate-and-Fire Neurons: From Stochastic Input to Escape Rates , 2000, Neural Computation.

[48]  William H. Press,et al.  Numerical recipes in C , 2002 .