Persistence in a large network of locally interacting neurons

This article presents a biological neural network model driven by inhomogeneous Poisson processes accounting for the intrinsic randomness of synapses. The main novelty is the introduction of local interactions: each firing neuron triggers an instantaneous increase in electric potential to a fixed number of randomly chosen neurons. We prove that, as the number of neurons approaches infinity, the finite network converges to a nonlinear meanfield process characterised by a jump-type stochastic differential equation. We show that this process displays a phase transition: the activity of a typical neuron in the infinite network either rapidly dies out, or persists forever, depending on the global parameters describing the intensity of interconnection. This provides a way to understand the emergence of persistent activity triggered by weak input signals in large neural networks.

[1]  J. Touboul Spatially Extended Networks with Singular Multi-scale Connectivity Patterns , 2013, Journal of Statistical Physics.

[2]  J. Touboul Propagation of chaos in neural fields , 2011, 1108.2414.

[3]  A. Guillin,et al.  On the rate of convergence in Wasserstein distance of the empirical measure , 2013, 1312.2128.

[4]  J. Touboul,et al.  Mean-field description and propagation of chaos in networks of Hodgkin-Huxley and FitzHugh-Nagumo neurons , 2012, The Journal of Mathematical Neuroscience.

[5]  N. Woo,et al.  Persistent neural activity in the prefrontal cortex: a mechanism by which BDNF regulates working memory? , 2008, Progress in brain research.

[6]  C. Villani,et al.  Quantitative Concentration Inequalities for Empirical Measures on Non-compact Spaces , 2005, math/0503123.

[7]  E J Chichilnisky,et al.  A simple white noise analysis of neuronal light responses , 2001, Network.

[8]  Anthony N. Burkitt,et al.  A review of the integrate-and-fire neuron model: II. Inhomogeneous synaptic input and network properties , 2006, Biological Cybernetics.

[9]  María J. Cáceres,et al.  Analysis of nonlinear noisy integrate & fire neuron models: blow-up and steady states , 2010, Journal of mathematical neuroscience.

[10]  S. Mischler,et al.  Kac’s program in kinetic theory , 2011, Inventiones mathematicae.

[11]  F. Delarue,et al.  Global solvability of a networked integrate-and-fire model of McKean–Vlasov type , 2012, 1211.0299.

[12]  J. Fontbona,et al.  Quantitative propagation of chaos for generalized Kac particle systems , 2014, 1406.2115.

[13]  M. Kac Foundations of Kinetic Theory , 1956 .

[14]  D. Tank,et al.  Persistent neural activity: prevalence and mechanisms , 2004, Current Opinion in Neurobiology.

[15]  Marian Stamp Dawkins,et al.  The Noisy Brain: Stochastic Dynamics as a Principle of Brain Function The Noisy Brain: Stochastic Dynamics as a Principle of Brain Function. By Edmund T. Rolls & Gustavo Deco. Oxford: Oxford University Press (2010). Pp. 310. Price £37.95 hardback. , 2010, Animal Behaviour.

[16]  Jonathan D. Touboul,et al.  On the Dynamics of Random Neuronal Networks , 2014, Journal of Statistical Physics.

[17]  J. Zylberberg,et al.  Mechanisms of Persistent Activity in Cortical Circuits: Possible Neural Substrates for Working Memory. , 2017, Annual review of neuroscience.

[18]  D. Talay,et al.  Nonlinear self-stabilizing processes – I Existence, invariant probability, propagation of chaos , 1998 .

[19]  E J Chichilnisky,et al.  Prediction and Decoding of Retinal Ganglion Cell Responses with a Probabilistic Spiking Model , 2005, The Journal of Neuroscience.

[20]  A. Hodgkin,et al.  A quantitative description of membrane current and its application to conduction and excitation in nerve , 1952, The Journal of physiology.

[21]  J. Touboul Mean-field equations for stochastic firing-rate neural fields with delays: Derivation and noise-induced transitions , 2012 .

[22]  Eero P. Simoncelli,et al.  Spatio-temporal correlations and visual signalling in a complete neuronal population , 2008, Nature.

[23]  Mark H. A. Davis Piecewise‐Deterministic Markov Processes: A General Class of Non‐Diffusion Stochastic Models , 1984 .

[24]  G. A. Pavliotis,et al.  Long-Time Behaviour and Phase Transitions for the Mckean–Vlasov Equation on the Torus , 2018, Archive for Rational Mechanics and Analysis.

[25]  Julian Tugaut,et al.  Phase transitions of McKean–Vlasov processes in double-wells landscape , 2014 .

[26]  Florent Malrieu,et al.  Logarithmic Sobolev Inequalities for Some Nonlinear Pde's , 2001 .

[27]  Anthony N. Burkitt,et al.  A Review of the Integrate-and-fire Neuron Model: I. Homogeneous Synaptic Input , 2006, Biological Cybernetics.

[28]  A. Sznitman Topics in propagation of chaos , 1991 .