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Journal of Computational Neuroscience

Erschienen in:

01.06.2013

Dynamics of spiking neurons: between homogeneity and synchrony

verfasst von: Aaditya V. Rangan, Lai-Sang Young

Erschienen in: Journal of Computational Neuroscience | Ausgabe 3/2013

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Abstract

Randomly connected networks of neurons driven by Poisson inputs are often assumed to produce “homogeneous” dynamics, characterized by largely independent firing and approximable by diffusion processes. At the same time, it is well known that such networks can fire synchronously. Between these two much studied scenarios lies a vastly complex dynamical landscape that is relatively unexplored. In this paper, we discuss a phenomenon which commonly manifests in these intermediate regimes, namely brief spurts of spiking activity which we call multiple firing events (MFE). These events do not depend on structured network architecture nor on structured input; they are an emergent property of the system. We came upon them in an earlier modeling paper, in which we discovered, through a careful benchmarking process, that MFEs are the single most important dynamical mechanism behind many of the V1 phenomena we were able to replicate. In this paper we explain in a simpler setting how MFEs come about, as well as their potential dynamic consequences. Although the mechanism underlying MFEs cannot easily be captured by current population dynamics models, this phenomena should not be ignored during analysis; there is a growing body of evidence that such collaborative activity may be a key towards unlocking the possible functional properties of many neuronal networks.

Vorheriger Artikel Testing for significance of phase synchronisation dynamics in the EEG

Nächster Artikel Reciprocal inhibition and slow calcium decay in perigeniculate interneurons explain changes of spontaneous firing of thalamic cells caused by cortical inactivation

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The solutions ρ _E(V _E, t) and ρ _I(V _I, t) of the FPE are ensemble-averaged distributions which tend to steady states as t → ∞. Pathwise solutions are more representative of what is observed in individual trials

The term “gain” is often used to describe the slope of a system’s steady-state output firing-rate as a function of its constant input firing-rate (Amit and Tsodyks 1991; Murphy and Miller 2009). In this context “high gain” implies the sensitivity of a particular low-order statistical measure of system activity (i.e., firing-rate) as a function of a particular low-order measure of a system’s input (again, firing-rate). In this paper we use “high gain” to refer to the general notion of dynamic sensitivity, including firing-rates as well as higher-order statistics. Thus, with this broader definition, we expect the collaborative activity in a high gain regime to be sensitive to changes in the temporal correlation of input spikes, even if the time-averaged firing rate of the feedforward input is held fixed.

As a working definition, we take M to be the 95th-percentile for the Poisson distribution of firing-counts in any given timebin, given a firing-rate of N _I v _I, where v _I is the time-averaged firing-rate of I-cells. For example, if N _I = 128 and v _I = 35 Hz, as shown in panel (A) of Fig. 8, then the average number of spikes per 2 ms bin is (35 × 128)/1000 = 4.5 and M = 12.

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Titel: Dynamics of spiking neurons: between homogeneity and synchrony
verfasst von: Aaditya V. Rangan
Lai-Sang Young
Publikationsdatum: 01.06.2013
Verlag: Springer US
Erschienen in: Journal of Computational Neuroscience / Ausgabe 3/2013
Print ISSN: 0929-5313
Elektronische ISSN: 1573-6873
DOI: https://doi.org/10.1007/s10827-012-0429-1

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