In vivo Two-Photon Imaging of Energy Metabolism at Single Cell Level using Genetically Encoded Sensors

Philipp Maechler; Philipp Maechler; Philipp Maechler; Matthias T. Wyss; Matthias T. Wyss; Matthias T. Wyss; Jillian Stobart; Jillian Stobart; Jillian Stobart; Marc Zuend; Marc Zuend; Marc Zuend; Felipe Barros; Felipe Barros; Felipe Barros; Bruno Weber; Bruno Weber; Bruno Weber

doi:10.1364/NTM.2015.JT1B.4

Optics in the Life Sciences
OSA Technical Digest (online) (Optica Publishing Group, 2015),
paper JT1B.4
•https://doi.org/10.1364/NTM.2015.JT1B.4

In vivo Two-Photon Imaging of Energy Metabolism at Single Cell Level using Genetically Encoded Sensors

Philipp Maechler, Matthias T. Wyss, Jillian Stobart, Marc Zuend, Felipe Barros, and Bruno Weber

Optics and the Brain 2015

Vancouver Canada
12–15 April 2015
ISBN: 978-1-55752-954-1

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Functional Brain Two-photon Microscopy (JT1B)

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P. Maechler, M. T. Wyss, J. Stobart, M. Zuend, F. Barros, and B. Weber, "In vivo Two-Photon Imaging of Energy Metabolism at Single Cell Level using Genetically Encoded Sensors," in Optics in the Life Sciences, OSA Technical Digest (online) (Optica Publishing Group, 2015), paper JT1B.4.

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Abstract

Genetically encoded fluorescent sensors specific for energy metabolites are starting to become key tools for studying brain energy metabolism at the single cell level. Sensors for glucose, glutamate, ATP, NADH, lactate, and pyruvate have been successfully used in brain cells and brain slices. Providing high spatiotemporal resolution, these sensors report cell-specific metabolite levels, absolute concentrations, and even metabolic fluxes, and are being instrumental for the discovery of new phenomena and their molecular underpinnings. Here, we report the methodology and first results from in vivo applications of sensors for glucose, lactate and pyruvate. Furthermore, we provide example applications for investigating cell-specific metabolic processes in the cerebral cortex of mice.

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