Cao, Z.; Jiapeng, Z.; Zhang, C.; Wang, Q.; Huang, Y.; Liu, W.; Shen, B.; Chai, Y.; Zhong, Z.; Li, H.; Wen, Q.; Wang, H.; Liang, W.

Investigating structural and functional dynamics across large spatial scales in living organisms calls for volumetric microscopy that combines a wide field of view (FOV), high spatial resolution, and sufficient temporal resolution. Swept confocally-aligned planar excitation (SCAPE) microscopy offers a compelling balance of optical sectioning, cellular resolution, and high-speed volumetric imaging. However, extending SCAPE to mesoscopic scales has been hindered by the limited tilting angle of the oblique illumination light sheet achievable with commercial low-magnification objectives. Here, we present a mesoscopic SCAPE microscope that overcomes this constraint by implementing a super-oblique light sheet--tilted up to ~60{degrees} relative to the optical axis of a 0.5-NA primary objective--enabled by an air-to-water bridging reflector. In addition, we introduce a single-galvanometer, self-conjugating rescanning strategy that allows arbitrary customization of the optical-to-mechanical angle ratio. This innovation accommodates the reversed and modulated scan displacement of the reflected light sheet and preserves descanned epi-fluorescence detection. Together, these advancements enable our mesoscopic SCAPE microscope to achieve a lateral FOV of 5.0 mm x 2.9 mm, cellular-level spatial resolution (~9.4 m x ~5.9 m lateral, and ~6.0 m axial), and a volumetric imaging rate of 9 volumes per second.