Deep-learning two-photon fiberscopy for video-rate brain imaging in freely-behaving mice.
Honghua GuanDawei LiHyeon-Cheol ParkAng LiYuanlei YueYung-Tian A GauMing-Jun LiDwight E BerglesHui LuXingde LiPublished in: Nature communications (2022)
Scanning two-photon (2P) fiberscopes (also termed endomicroscopes) have the potential to transform our understanding of how discrete neural activity patterns result in distinct behaviors, as they are capable of high resolution, sub cellular imaging yet small and light enough to allow free movement of mice. However, their acquisition speed is currently suboptimal, due to opto-mechanical size and weight constraints. Here we demonstrate significant advances in 2P fiberscopy that allow high resolution imaging at high speeds (26 fps) in freely-behaving mice. A high-speed scanner and a down-sampling scheme are developed to boost imaging speed, and a deep learning (DL) algorithm is introduced to recover image quality. For the DL algorithm, a two-stage learning transfer strategy is established to generate proper training datasets for enhancing the quality of in vivo images. Implementation enables video-rate imaging at ~26 fps, representing 10-fold improvement in imaging speed over the previous 2P fiberscopy technology while maintaining a high signal-to-noise ratio and imaging resolution. This DL-assisted 2P fiberscope is capable of imaging the arousal-induced activity changes in populations of layer2/3 pyramidal neurons in the primary motor cortex of freely-behaving mice, providing opportunities to define the neural basis of behavior.
Keyphrases
- high resolution
- deep learning
- high speed
- machine learning
- healthcare
- image quality
- computed tomography
- primary care
- risk assessment
- white matter
- type diabetes
- metabolic syndrome
- body mass index
- blood brain barrier
- fluorescence imaging
- quality improvement
- subarachnoid hemorrhage
- insulin resistance
- single cell
- rna seq
- human health
- body weight