On the distribution of firing rates in networks of cortical neurons.

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2011-11

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Abstract

The distribution of in vivo average firing rates within local cortical networks has been reported to be highly skewed and long tailed. The distribution of average single-cell inputs, conversely, is expected to be Gaussian by the central limit theorem. This raises the issue of how a skewed distribution of firing rates might result from a symmetric distribution of inputs. We argue that skewed rate distributions are a signature of the nonlinearity of the in vivo f-I curve. During in vivo conditions, ongoing synaptic activity produces significant fluctuations in the membrane potential of neurons, resulting in an expansive nonlinearity of the f-I curve for low and moderate inputs. Here, we investigate the effects of single-cell and network parameters on the shape of the f-I curve and, by extension, on the distribution of firing rates in randomly connected networks.

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Cerebral Cortex, Nerve Net, Neurons, Animals, Normal Distribution, Action Potentials, Neural Inhibition, Nonlinear Dynamics, Models, Neurological, Time Factors, Computer Simulation

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https://hdl.handle.net/10161/23361

Published Version (Please cite this version)

10.1523/jneurosci.1677-11.2011

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Roxin, Alex, Nicolas Brunel, David Hansel, Gianluigi Mongillo and Carl van Vreeswijk (2011). On the distribution of firing rates in networks of cortical neurons. The Journal of neuroscience : the official journal of the Society for Neuroscience, 31(45). pp. 16217–16226. 10.1523/jneurosci.1677-11.2011 Retrieved from https://hdl.handle.net/10161/23361.

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Brunel

Nicolas Brunel

Adjunct Professor of Neurobiology

We use theoretical models of brain systems to investigate how they process and learn information from their inputs. Our current work focuses on the mechanisms of learning and memory, from the synapse to the network level, in collaboration with various experimental groups. Using methods from
statistical physics, we have shown recently that the synaptic
connectivity of a network that maximizes storage capacity reproduces
two key experimentally observed features: low connection probability
and strong overrepresentation of bidirectionnally connected pairs of
neurons. We have also inferred `synaptic plasticity rules' (a
mathematical description of how synaptic strength depends on the
activity of pre and post-synaptic neurons) from data, and shown that
networks endowed with a plasticity rule inferred from data have a
storage capacity that is close to the optimal bound.


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