Studying Brain Circuit Function with Dynamic Causal Modeling for Optogenetic FMRI

Overview

Journal Neuron

Publisher Cell Press

Specialty Neurology

Date 2017 Jan 31

PMID 28132829

Citations 34

Authors

David Bernal-Casas

Hyun Joo Lee

Andrew J Weitz

Jin Hyung Lee

Affiliations

Soon will be listed here.

Abstract

Defining the large-scale behavior of brain circuits with cell type specificity is a major goal of neuroscience. However, neuronal circuit diagrams typically draw upon anatomical and electrophysiological measurements acquired in isolation. Consequently, a dynamic and cell-type-specific connectivity map has never been constructed from simultaneous measurements across the brain. Here, we introduce dynamic causal modeling (DCM) for optogenetic fMRI experiments-which uniquely allow cell-type-specific, brain-wide functional measurements-to parameterize the causal relationships among regions of a distributed brain network with cell type specificity. Strikingly, when applied to the brain-wide basal ganglia-thalamocortical network, DCM accurately reproduced the empirically observed time series, and the strongest connections were key connections of optogenetically stimulated pathways. We predict that quantitative and cell-type-specific descriptions of dynamic connectivity, as illustrated here, will empower novel systems-level understanding of neuronal circuit dynamics and facilitate the design of more effective neuromodulation therapies.

Citing Articles

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