Abstract
In networks with small-world topology, which are characterized by a high clustering coefficient and a short characteristic path length, information can be transmitted efficiently and at relatively low costs. The brain is composed of small-world networks, and evolution may have optimized brain connectivity for efficient information processing. Despite many studies on the impact of topology on information processing in neuronal networks, little is known about the development of network topology and the emergence of efficient small-world networks. We investigated how a simple growth process that favors short-range connections over long-range connections in combination with a synapse formation rule that generates homeostasis in post-synaptic firing rates shapes neuronal network topology. Interestingly, we found that small-world networks benefited from homeostasis by an increase in efficiency, defined as the averaged inverse of the shortest paths through the network. Efficiency particularly increased as small-world networks approached the desired level of electrical activity. Ultimately, homeostatic small-world networks became almost as efficient as random networks. The increase in efficiency was caused by the emergent property of the homeostatic growth process that neurons started forming more long-range connections, albeit at a low rate, when their electrical activity was close to the homeostatic set-point. Although global network topology continued to change when neuronal activities were around the homeostatic equilibrium, the small-world property of the network was maintained over the entire course of development. Our results may help understand how complex systems such as the brain could set up an efficient network topology in a self-organizing manner. Insights from our work may also lead to novel techniques for constructing large-scale neuronal networks by self-organization.
Highlights
The synaptic wiring of cortical networks is key to the functionality of the brain and a precondition for all cognitive behavior (Park and Friston, 2013)
We investigated how the topology of these selforganizing networks developed over time when neurons favor short-range connections over long-range connections, or, alternatively, when all connections are likely
Increased global efficiency was caused by the fact that homeostasis favored longer-ranged connections, which affected clustering as well as characteristic path length
Summary
The synaptic wiring of cortical networks is key to the functionality of the brain and a precondition for all cognitive behavior (Park and Friston, 2013). Network topology that combines these two properties, long-range connectivity and high clustering, is called small-world (Watts and Strogatz, 1998). Small-world networks have the advantages of local connectivity combined with a high efficiency brought about by a small number of long-range connections (Watts and Strogatz, 1998). During development and in adulthood, connectivity is not fixed (Butz et al, 2009b), and synapse formation goes along with massive synapse deletion and reorganization of connectivity (Missler et al, 1993; Siegel and Lohmann, 2013) This observation triggered the question of this study: how does network topology develop during ontogeny when synapse
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