Peeking into the Sleeping Brain: Using in Vivo Imaging in Rodents to Understand the Relationship Between Sleep and Cognition

Overview

Journal J Neurosci Methods

Specialty Neurology

Date 2018 Sep 13

PMID 30208306

Citations 5

Authors

Johanna Sigl-Glockner

Julie Seibt

Affiliations

Soon will be listed here.

Abstract

Sleep is well known to benefit cognitive function. In particular, sleep has been shown to enhance learning and memory in both humans and animals. While the underlying mechanisms are not fully understood, it has been suggested that brain activity during sleep modulates neuronal communication through synaptic plasticity. These insights were mostly gained using electrophysiology to monitor ongoing large scale and single cell activity. While these efforts were instrumental in the characterisation of important network and cellular activity during sleep, several aspects underlying cognition are beyond the reach of this technology. Neuronal circuit activity is dynamically regulated via the precise interaction of different neuronal and non-neuronal cell types and relies on subtle modifications of individual synapses. In contrast to established electrophysiological approaches, recent advances in imaging techniques, mainly applied in rodents, provide unprecedented access to these aspects of neuronal function in vivo. In this review, we describe various techniques currently available for in vivo brain imaging, from single synapse to large scale network activity. We discuss the advantages and limitations of these approaches in the context of sleep research and describe which particular aspects related to cognition lend themselves to this kind of investigation. Finally, we review the few studies that used in vivo imaging in rodents to investigate the sleeping brain and discuss how the results have already significantly contributed to a better understanding on the complex relation between sleep and plasticity across development and adulthood.

Citing Articles

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Dihydropyridine calcium blockers do not interfere with non-rapid eye movement sleep.

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Molecular Mechanisms of Memory Consolidation That Operate During Sleep.

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A mechanism for learning with sleep spindles.

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Primed to Sleep: The Dynamics of Synaptic Plasticity Across Brain States.

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