# Optimal interplay between synaptic strengths and network structure   enhances activity fluctuations and information propagation in hierarchical   modular networks

**Authors:** Rodrigo F.O. Pena, Vinicius Lima, Renan O. Shimoura, Jo\~ao P. Novato,, Antonio C. Roque

arXiv: 1905.01181 · 2020-04-14

## TL;DR

This study investigates how the combination of network structure and synaptic strength influences activity propagation in hierarchical modular spiking neuron networks, revealing optimal conditions for information flow.

## Contribution

It demonstrates that increasing either synaptic strength or the number of modules enhances information propagation, identifying an optimal interplay between these parameters.

## Key findings

- Optimal information propagation occurs with increased synaptic strength or modules.
- Population-level information flow peaks at an intermediate number of modules.
- Enhanced cross-correlations among neurons improve information transmission.

## Abstract

In network models of spiking neurons, the joint impact of network structure and synaptic parameters on activity propagation is still an open problem. Here we use an information-theoretical approach to investigate activity propagation in spiking networks with hierarchical modular topology. We observe that optimized pairwise information propagation emerges due to the increase of either (i) the global synaptic strength parameter or (ii) the number of modules in the network, while the network size remains constant. At the population level, information propagation of activity among adjacent modules is enhanced as the number of modules increases until a maximum value is reached and then decreases, showing that there is an optimal interplay between synaptic strength and modularity for population information flow. This is in contrast to information propagation evaluated among pairs of neurons, which attains maximum value at the maximum values of these two parameter ranges. By examining the network behavior under increase of synaptic strength and number of modules we find that these increases are associated with two different effects: (i) increase of autocorrelations among individual neurons, and (ii) increase of cross-correlations among pairs of neurons. The second effect is associated with better information propagation in the network. Our results suggest roles that link topological features and synaptic strength levels to the transmission of information in cortical networks.v

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1905.01181/full.md

## References

58 references — full list in the complete paper: https://tomesphere.com/paper/1905.01181/full.md

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Source: https://tomesphere.com/paper/1905.01181