Stochastic computations in cortical microcircuit models

Experimental data from neuroscience suggest that a substantial amount of knowledge is stored in the brain in the form of probability distributions over network states and trajectories of network states. We provide a theoretical foundation for this hypothesis by showing that even very detailed models...

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Bibliographic Details
Published in:PLoS computational biology 2013-11, Vol.9 (11), p.e1003311-e1003311
Main Authors: Habenschuss, Stefan, Jonke, Zeno, Maass, Wolfgang
Format: Article
Language:English
Subjects:
Behavior
Computational Biology
Humans
Markov Chains
Models, Neurological
Models, Statistical
Nerve Net - physiology
Neurons
Neurons - physiology
Neurophysiology
Neurosciences
Problem Solving
Social exclusion
Stochastic analysis
Stochastic Processes
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Summary:Experimental data from neuroscience suggest that a substantial amount of knowledge is stored in the brain in the form of probability distributions over network states and trajectories of network states. We provide a theoretical foundation for this hypothesis by showing that even very detailed models for cortical microcircuits, with data-based diverse nonlinear neurons and synapses, have a stationary distribution of network states and trajectories of network states to which they converge exponentially fast from any initial state. We demonstrate that this convergence holds in spite of the non-reversibility of the stochastic dynamics of cortical microcircuits. We further show that, in the presence of background network oscillations, separate stationary distributions emerge for different phases of the oscillation, in accordance with experimentally reported phase-specific codes. We complement these theoretical results by computer simulations that investigate resulting computation times for typical probabilistic inference tasks on these internally stored distributions, such as marginalization or marginal maximum-a-posteriori estimation. Furthermore, we show that the inherent stochastic dynamics of generic cortical microcircuits enables them to quickly generate approximate solutions to difficult constraint satisfaction problems, where stored knowledge and current inputs jointly constrain possible solutions. This provides a powerful new computing paradigm for networks of spiking neurons, that also throws new light on how networks of neurons in the brain could carry out complex computational tasks such as prediction, imagination, memory recall and problem solving.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1003311