Litcius/Paper detail

Simulations approaching data: cortical slow waves in inferred models of the whole hemisphere of mouse

Cristiano Capone, Chiara De Luca, G. De Bonis, Robin Gutzen, Irene Bernava, Elena Pastorelli, Francesco Simula, Cosimo Lupo, Leonardo Tonielli, Francesco Resta, Anna Letizia Allegra Mascaro, Francesco S. Pavone, Michael Denker, Pier Stanislao Paolucci

2023Communications Biology13 citationsDOIOpen Access PDF

Abstract

The development of novel techniques to record wide-field brain activity enables estimation of data-driven models from thousands of recording channels and hence across large regions of cortex. These in turn improve our understanding of the modulation of brain states and the richness of traveling waves dynamics. Here, we infer data-driven models from high-resolution in-vivo recordings of mouse brain obtained from wide-field calcium imaging. We then assimilate experimental and simulated data through the characterization of the spatio-temporal features of cortical waves in experimental recordings. Inference is built in two steps: an inner loop that optimizes a mean-field model by likelihood maximization, and an outer loop that optimizes a periodic neuro-modulation via direct comparison of observables that characterize cortical slow waves. The model reproduces most of the features of the non-stationary and non-linear dynamics present in the high-resolution in-vivo recordings of the mouse brain. The proposed approach offers new methods of characterizing and understanding cortical waves for experimental and computational neuroscientists.

Topics & Concepts

Computer scienceModulation (music)Experimental dataInferenceNeurosciencePhysicsBiological systemArtificial intelligenceBiologyAcousticsMathematicsStatisticsNeural dynamics and brain functionFunctional Brain Connectivity Studiesstochastic dynamics and bifurcation
Simulations approaching data: cortical slow waves in inferred models of the whole hemisphere of mouse | Litcius