Analysis and Model of Cortical Slow Waves Acquired with Optical Techniques.

Slow waves (SWs) occur both during natural sleep and anesthesia and are universal across species. Even though electrophysiological recordings have been largely used to characterize brain states, they are limited in the spatial resolution and cannot target specific neuronal population. Recently, large-scale optical imaging techniques coupled with functional indicators overcame these restrictions. Here we combined wide-field fluorescence microscopy and a transgenic mouse model expressing a calcium indicator (GCaMP6f) in excitatory neurons to study SW propagation over the meso-scale under ketamine anesthesia. We developed "de novo" a versatile analysis pipeline to quantify the spatio-temporal propagation of the SWs in the frequency band [0.5, 4] Hz. Moreover, we designed a computational simulator based on a simple theoretical model, which takes into account the statistics of neural activity, the response of fluorescence proteins and the slow waves dynamics. The simulator was capable of synthesizing artificial signals that could reliably reproduce several features of the SWs observed in vivo. Comparison of preliminary experimental and simulated data shows the robustness of the analysis tools and its potential to uncover mechanistic insights of the Slow Wave Activity (SWA).