Intact skull chronic windows for mesoscopic wide-field imaging in awake mice
Background Craniotomy-based window implants are commonly used for microscopic
imaging, in head-fixed rodents, however their field of view is typically small and incompatible
with mesoscopic functional mapping of cortex. New method We describe a reproducible and
simple procedure for chronic through-bone wide-field imaging in awake head-fixed mice
providing stable optical access for chronic imaging over large areas of the cortex for months.
Results The preparation is produced by applying clear-drying dental cement to the intact …
imaging, in head-fixed rodents, however their field of view is typically small and incompatible
with mesoscopic functional mapping of cortex. New method We describe a reproducible and
simple procedure for chronic through-bone wide-field imaging in awake head-fixed mice
providing stable optical access for chronic imaging over large areas of the cortex for months.
Results The preparation is produced by applying clear-drying dental cement to the intact …
Background
Craniotomy-based window implants are commonly used for microscopic imaging, in head-fixed rodents, however their field of view is typically small and incompatible with mesoscopic functional mapping of cortex.
New method
We describe a reproducible and simple procedure for chronic through-bone wide-field imaging in awake head-fixed mice providing stable optical access for chronic imaging over large areas of the cortex for months.
Results
The preparation is produced by applying clear-drying dental cement to the intact mouse skull, followed by a glass coverslip to create a partially transparent imaging surface. Surgery time takes about 30 min. A single set-screw provides a stable means of attachment (in relation to the measured lateral and axial resolution) for mesoscale assessment without obscuring the cortical field of view.
Comparison with existing methods
We demonstrate the utility of this method by showing seed-pixel functional connectivity maps generated from spontaneous cortical activity of GCAMP6 signals in both awake and anesthetized mice in longitudinal studies of up to 2 months in duration.
Conclusions
We propose that the intact skull preparation described here may be used for most longitudinal studies that do not require micron scale resolution and where cortical neural or vascular signals are recorded with intrinsic sensors or in transgenic mice expressing genetically encoded sensors of activity.
Elsevier