Abstract
Multiphoton microscopy has emerged as the primary imaging tool for studying the structural and functional dynamics of neural circuits in brain tissue, which is highly scattering to light. Recently, three-photon microscopy has enabled high-resolution fluorescence imaging of neurons in deeper brain areas that lie beyond the reach of conventional two-photon microscopy, which is typically limited to ~ 450 µm. Three-photon imaging of neuronal calcium signals, through the genetically-encoded calcium indicator GCaMP6, has been used to successfully record neuronal activity in deeper neocortical layers and parts of the hippocampus in rodents. Bulk-loading cells in deeper cortical layers with synthetic calcium indicators could provide an alternative strategy for labelling that obviates dependence on viral tropism and promoter penetration, particularly in non-rodent species. Here we report a strategy for visualized injection of a calcium dye, Oregon Green BAPTA-1 AM (OGB-1 AM), at 500–600 µm below the surface of the mouse visual cortex in vivo. We demonstrate successful OGB-1 AM loading of cells in cortical layers 5–6 and subsequent three-photon imaging of orientation- and direction- selective visual responses from these cells.
Highlights
Multiphoton microscopy has emerged as the primary imaging tool for studying the structural and functional dynamics of neural circuits in brain tissue, which is highly scattering to light
We developed a non-genetic strategy for localizing calcium indicators in deeper cortical layers, to be subsequently utilized for recording neuronal activity via three-photon imaging
Before we could use OGB-1 AM and other fluorophores for three-photon imaging, we needed to determine the best three-photon excitation wavelengths for these fluorophores
Summary
Multiphoton microscopy has emerged as the primary imaging tool for studying the structural and functional dynamics of neural circuits in brain tissue, which is highly scattering to light. Bulk-loading cells in deeper cortical layers with synthetic calcium indicators could provide an alternative strategy for labelling that obviates dependence on viral tropism and promoter penetration, in non-rodent species. An alternative strategy to introduce calcium indicators into a desired brain area without dependence on transfection/expression systems is offered by bulk-loaded synthetic calcium indicators such as Oregon Green 488 BAPTA-1 AM (OGB-1 AM) Such dyes have been successfully used in the past to label and record activity from layers 2/3 neurons in the neocortex through two-photon imaging. To extend the use of bulk-loaded calcium indicators to deeptissue three-photon imaging of calcium signals, we standardized a method to inject OGB-1 AM into the deeper cortical layers in the mouse visual cortex and optically recorded visual responses using three-photon calcium imaging.
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