Optoacoustic Calcium Imaging of Deep Brain Activity in an Intracardially Perfused Mouse Brain Model

Optoacoustic Calcium Imaging of Deep Brain Activity in an Intracardially Perfused Mouse Brain Model

One main limitation of established neuroimaging methods is the inability to directly visualize large-scale neural dynamics in whole mammalian brains at subsecond speeds. Optoacoustic imaging has advanced in recent years to provide unique advantages for real-time deep-tissue observations, which have...

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Bibliographic Details
Published in:Photonics Vol. 6; no. 2; p. 67
Main Authors: Degtyaruk, Oleksiy, Mc Larney, Benedict, Deán-Ben, Xosé, Shoham, Shy, Razansky, Daniel
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-06-2019
Subjects:
Absorption
Brain
Calcium
calcium dynamics
Calcium imaging
Calcium signalling
Electroencephalography
Electromagnetic absorption
functional neuroimaging
GCaMP6f
Genetic code
Hemodynamics
Hemoglobin
Infrared imaging
Infrared windows
Mammals
Medical imaging
Medical research
Microscopy
Neuroimaging
optoacoustic neuroimaging
Physiology
Pressure transducers
Temporal resolution
Visualization
United States > US
Germany
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Summary:One main limitation of established neuroimaging methods is the inability to directly visualize large-scale neural dynamics in whole mammalian brains at subsecond speeds. Optoacoustic imaging has advanced in recent years to provide unique advantages for real-time deep-tissue observations, which have been exploited for three-dimensional imaging of both cerebral hemodynamic parameters and direct calcium activity in rodents. Due to a lack of suitable calcium indicators excitable in the near-infrared window, optoacoustic imaging of neuronal activity at deep-seated areas of the mammalian brain has been impeded by the strong absorption of blood in the visible range of the light spectrum. To overcome this, we have developed and validated an intracardially perfused mouse brain preparation labelled with genetically encoded calcium indicator GCaMP6f that closely resembles in vivo conditions. By overcoming the limitations of hemoglobin-based light absorption, this new technique was used to observe stimulus-evoked calcium dynamics in the brain at penetration depths and spatio-temporal resolution scales not attainable with existing neuroimaging techniques.
ISSN:2304-6732
2304-6732
DOI:10.3390/photonics6020067