Casting a Wide Net to Catch Seizures

Abstract

Network Properties Revealed During Multi-Scale Calcium Imaging of Seizure Activity in Zebrafish Liu J, Baraban SC. eNeuro. 2019;6(1):ENEURO.0041-19.2019. doi:10.1523/ENEURO.0041-19.2019. eCollection 2019 Jan-Feb. PMID: 30895220. Seizures are characterized by hypersynchronization of neuronal networks. Understanding these networks could provide a critical window for therapeutic control of recurrent seizure activity, that is, epilepsy. However, imaging seizure networks have largely been limited to microcircuits in vitro or small “windows” in vivo. Here, we combine fast confocal imaging of genetically encoded calcium indicator–expressing larval zebrafish with local field potential recordings to study epileptiform events at whole-brain and single-neuron levels in vivo. Using an acute seizure model (pentylenetetrazole, PTZ), we reliably observed recurrent electrographic ictal-like events associated with generalized activation of all major brain regions and uncovered a well-preserved anterior to posterior seizure propagation pattern. We also examined brain-wide network synchronization and spatiotemporal patterns of neuronal activity in the optic tectum microcircuit. Brain-wide and single-neuronal level analysis of PTZ-exposed and 4-aminopyridine-exposed zebrafish revealed distinct network dynamics associated with seizure and nonseizure hyperexcitable states, respectively. Neuronal ensembles, comprised of coactive neurons, were also uncovered during interictal-like periods. Taken together, these results demonstrate that macro- and micro-network calcium motifs in zebrafish may provide a greater understanding of epilepsy.