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[Preprint]. 2024 Jul 29:2024.07.04.601964. Originally published 2024 Jul 6. [Version 2] doi: 10.1101/2024.07.04.601964

Pan-cortical cellular imaging in freely behaving mice using a miniaturized micro-camera array microscope (mini-MCAM)

Jia Hu, Arun Cherkkil, Daniel A Surinach, Ibrahim Oladepo, Ridwan F Hossain, Skylar Fausner, Kapil Saxena, Eunsong Ko, Ryan Peters, Michael Feldkamp, Pavan C Konda, Vinayak Pathak, Roarke Horstmeyer, Suhasa B Kodandaramaiah
PMCID: PMC11245122  PMID: 39005454

Abstract

Understanding how circuits in the brain simultaneously coordinate their activity to mediate complex ethnologically relevant behaviors requires recording neural activities from distributed populations of neurons in freely behaving animals. Current miniaturized imaging microscopes are typically limited to imaging a relatively small field of view, precluding the measurement of neural activities across multiple brain regions. Here we present a miniaturized micro-camera array microscope (mini-MCAM) that consists of four fluorescence imaging micro-cameras, each capable of capturing neural activity across a 4.5 mm x 2.55 mm field of view (FOV). Cumulatively, the mini-MCAM images over 30 mm 2 area of sparsely expressed GCaMP6s neurons distributed throughout the dorsal cortex, in regions including the primary and secondary motor, somatosensory, visual, retrosplenial, and association cortices across both hemispheres. We demonstrate cortex-wide cellular resolution in vivo Calcium (Ca 2+ ) imaging using the mini-MCAM in both head-fixed and freely behaving mice.

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