# Simple model of complex dynamics of activity patterns in developing   networks of neuronal cultures

**Authors:** I.Y. Tyukin, D. Iudin, F. Iudin, T. Tyukina, V. Kazantsev, I. Mukhina,, A.N. Gorban

arXiv: 1812.09611 · 2022-05-17

## TL;DR

This paper introduces a simple, biologically meaningful model of neuronal network activity that explains complex patterns like avalanches and bursts, supported by empirical data and capturing the balance of energy and activity in developing cultures.

## Contribution

The paper presents a minimal two-variable model that accounts for complex neuronal activity patterns and self-organized criticality in developing neuronal networks.

## Key findings

- Model explains emergence of network spikes and bursts.
- Supports empirical observations of energy-dependent activity.
- Networks balance on the edge of percolation transition.

## Abstract

Living neuronal networks in dissociated neuronal cultures are widely known for their ability to generate highly robust spatiotemporal activity patterns in various experimental conditions. These include neuronal avalanches satisfying the power scaling law and thereby exemplifying self-organized criticality in living systems. A crucial question is how these patterns can be explained and modeled in a way that is biologically meaningful, mathematically tractable and yet broad enough to account for neuronal heterogeneity and complexity. Here we propose a simple model which may offer an answer to this question. Our derivations are based on just few phenomenological observations concerning input-output behavior of an isolated neuron. A distinctive feature of the model is that at the simplest level of description it comprises of only two variables, a network activity variable and an exogenous variable corresponding to energy needed to sustain the activity and modulate the efficacy of signal transmission. Strikingly, this simple model is already capable of explaining emergence of network spikes and bursts in developing neuronal cultures. The model behavior and predictions are supported by empirical observations and published experimental evidence on cultured neurons behavior exposed to oxygen and energy deprivation. At the larger, network scale, introduction of the energy-dependent regulatory mechanism enables the network to balance on the edge of the network percolation transition. Network activity in this state shows population bursts satisfying the scaling avalanche conditions. This network state is self-sustainable and represents a balance between global network-wide processes and spontaneous activity of individual elements.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1812.09611/full.md

## Figures

24 figures with captions in the complete paper: https://tomesphere.com/paper/1812.09611/full.md

## References

43 references — full list in the complete paper: https://tomesphere.com/paper/1812.09611/full.md

---
Source: https://tomesphere.com/paper/1812.09611