Imaging dendritic spines in the hippocampus of a living mouse by 3D-STED microscopy
PrePrint bioRxiv. 2023-02-01; :
DOI: 10.1101/2023.02.01.526326
STED microscopy has been used to address a wide range of neurobiological questions in optically well-accessible samples like cell culture or brain slices. However, the application of STED to deeply embedded structures in the brain of living animals remains technically challenging. In previous work, we established chronic STED imaging in the hippocampusin vivobut the gain in spatial resolution was restricted to the lateral plane. In this study, we report on extending the gain in STED resolution into the optical axis to visualize dendritic spines in the hippocampusin vivo. The approach is based on a spatial light modulator to shape the focal STED light intensity in all three dimensions and a conically shaped window that is compatible with an objective that has a long working distance and a high numerical aperture. Moreover, we corrected distortions of the laser wavefront to optimize the shape of the bottle beam of the STED laser, which is required for 3D-STED microscopy. In summary, we present a methodology to improve the axial resolution for STED microscopy in the deeply embedded hippocampusin vivo, facilitating longitudinal studies of neuroanatomical plasticity at the nanoscale in a wide range of (patho-)physiological contexts.