In vivo aberration measurement and correction for ultrafast FACED two-photon fluorescence microscopy of the brain

Ultrafast two-photon fluorescence microscopy (2PFM) based on free-space angular-chirp-enhanced delay (FACED) enables megahertz line scanning and kilohertz frame rates for in vivo brain imaging. However, optical aberrations from the imaging system and brain tissue degrade spatial resolution, signal, and contrast at depth. Here we integrate adaptive optics (AO) with FACED 2PFM to achieve synapse-resolving ultrafast imaging in the living mouse brain. Because FACED generates a one-dimensional array of temporally delayed, spatially separated excitation foci at 1 gigahertz, we developed a focus-averaging, frequency-multiplexed aberration measurement method that simultaneously measures and corrects the average aberration across all FACED foci using a segmented deformable mirror. We validated the accuracy of our method in correcting both system and artificial aberrations. When applied to in vivo morphological imaging of the mouse brain, AO enhances resolution, signal, contrast of dendritic shafts, spines, and boutons. Functionally, AO improves cerebral blood flow imaging by increasing plasma signal and kymograph contrast over large fields of view; when used for glutamate imaging, it amplifies transient amplitudes and reveals visually evoked glutamate release that were undetectable without correction. Together, these results establish AO-FACED 2PFM as a powerful approach that combines ultrafast imaging with high spatial resolution for structural and functional imaging in the living mouse brain.