Significance:

In mesoscopic imaging research in neuroscience, achieving high spatial resolution optical imaging across the entire field of view (FOV) remains critical. This directly determines whether researchers can precisely analyze the large- scale dynamic activities of neural circuits at the single-cell or even subcellular level. Consistent optical quality throughout the entire imaging FOV is essential to accu- rately capture the spatiotemporal patterns of neural activity across brain regions, thereby providing a powerful tool for understanding the circuit mechanisms underlying cognition, behavior, and disease at cellular and subcellular resolution in vivo.

Aim:

This study aims to develop a technology that extends the imaging FOV in a two-photon mesoscope while enhancing the optical quality across the entire FOV in vivo. The key point is to establish a robust method that can significantly extend the FOV beyond what the micro/mesoscope objective had been originally designed for, yet maintain the original resolution specifications. As such, the value of the method also extends beyond improving just one mesoscope, which we use as a demo in this study.

Approach:

This study introduces an innovative approach that combines block scan- ning with adaptive optical (AO) correction through a bioinspired honeycomb-based cellular multipoint adaptive technology (CMAT) to achieve mesoscopic two-photon imaging. This system enables unprecedented large-FOV, high-resolution imaging by dividing an 8 × 8 mm 2 imaging area into subregions, each pre-optimized with deformable mirror (DM) compensation while applying real-time dynamic wavefront correction during scanning. Furthermore, we have designed multiple user-defined sub-region scanning functions. Each sub-region automatically loads the aberration correction compensation values from the nearest reference point relative to its center, thereby ensuring optimal optical performance for every individual sub-region. The robustness of this technology has been systematically verified across multiple neural circuit observation scenarios using transgenic mouse models, demonstrating its capability for reliable single-cell resolution imaging across extensive brain regions.

Results:

Comprehensive evaluation using standard samples and transgenic mouse models demonstrated that the CMAT significantly enhances the imaging perfor- mance of the two-photon mesoscope. This technique extends the effective two- photon imaging FOV from 6 × 6 mm 2 to 8 × 8 mm 2 while markedly improving the optical quality in the peripheral regions. High resolution was maintained at ∼1 μm (lateral) and ∼10 μm (axial) in the central area, with edge regions achieving improved resolutions of ∼1.3 μm (lateral) and ∼14 μm (axial). Quantitative analysis confirmed that multipoint AO not only enhances image contrast and optical resolu- tion but also substantially increases the signal-to-noise ratio (SNR) in Ca 2þ imaging. This work delivers a pivotal technical advance for large-scale functional imaging of neural circuits.

Conclusion: CMAT significantly extends the effective FOV and enhances the optical quality of the two-photon mesoscope system.