Abstract
How spiking activity reverberates through neuronal networks, how evoked and spontaneous activity interacts and blends, and how the combined activities represent external stimulation are pivotal questions in neuroscience. We simulated minimal models of unstructured spiking networks in silico, asking whether and how gentle external stimulation might be subsequently reflected in spontaneous activity fluctuations. Consistent with earlier findings in silico and in vitro, we observe a privileged subpopulation of ‘pioneer neurons’ that, by their firing order, reliably encode previous external stimulation. We also confirm that pioneer neurons are ‘sensitive’ in that they are recruited by small fluctuations of population activity. We show that order-based representations rely on a ‘chain’ of pioneer neurons with different degrees of sensitivity and thus constitute an emergent property of collective dynamics. The forming of such representations is greatly favoured by a broadly heterogeneous connection topology—a broad ‘middle class’ in degree of connectedness. In conclusion, we offer a minimal model for the representational role of pioneer neurons, as observed experimentally in vitro. In addition, we show that broadly heterogeneous connectivity enhances the representational capacity of unstructured networks.
Highlights
An important question in theoretical neuroscience is how externally evoked activity interacts with the spontaneous activity reverberating through neural networks
We show that the gradual build-up of activity towards a synchronization event proceeds in a reproducible manner, recruiting identifiable pioneer neurons in a particular order, consistent with experimental findings (Eytan and Marom 2006)
We begin by describing macroscopic dynamics of networks of spiking neurons and synapses with short-term plasticity, focusing on spontaneous fluctuations of activity and on the effect of gentle external stimulation (Sect. 2.1)
Summary
An important question in theoretical neuroscience is how externally evoked activity interacts with the spontaneous activity reverberating through neural networks. Related questions are how network topology shapes this interaction (touching on structure–function relationships) and how the blending of evoked and spontaneous activity represents external stimulation (touching on the ‘neural code’) (Rieke 2008; Decharms and Zador 2000; Thorpe et al 2001; Ponulak and Kasinski 2011) We address these issues by simulating in silico spiking neural networks (SNNs) with synaptic depression and different types of unstructured (random) connectivity. Representing a drastic oversimplification of cortical networks in vivo, randomly connected SNNs have contributed considerably to our understanding of neural function (Shepherd 2003) They provide generic models for experimentally observed dynamics of cortical activity associated with phenomena such as short-term memory, attentional biasing, or decision-making (Rolls 2008; Rolls and Deco 2010). SNNs deepen our understanding of such phenomena because their activity dynamics can often be described analytically in terms of mean-field theory (Feng 2003; Gerstner et al 2014)
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