Modeling the response to external stimuli of the zebrafish’s optic tectum neurons with avalanche-like spontaneous activity

Mateo Amortegui Cifuentes

Modeling the response to external stimuli of the zebrafish’s optic tectum neurons with avalanche-like spontaneous activity.

Rel. Alessandro Pelizzola. Politecnico di Torino, Corso di laurea magistrale in Physics Of Complex Systems (Fisica Dei Sistemi Complessi), 2024

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Abstract

Previous studies found that the zebrafish spontaneous whole-brain neuronal dynamics, obtained with Ca2+ imaging, is avalanche-like, i.e., it has alternating periods of silence and collective cascading activity bursts, where both the duration of the bursts and the number of neurons that spiked during those bursts follow power law distributions with exponents close to the random field Ising universality class, but which deviate from their critical values for avalanches occurring when there is an unbalance between excitatory (E) and inhibitory (I) activity. Here, we model the response of the zebrafish neurons in the optic tectum, displaying avalanche dynamics in spontaneous activity, to an external stimulus, aiming to see whether the power law exponents change or if the dynamics is no longer avalanche-like, and how this is related to E/I unbalances.

For this, we simulated the avalanche dynamics of a network of excitatory and inhibitory stochastic neurons with the stochastic Wilson-Cowan model, taking the connectivity matrix as function of data of the position of neurons in the optic tectum, and we found values of the parameters of the model that reproduce the experimental power law exponents