AI Article Synopsis
- Recent studies reveal that orofacial behaviors in mice significantly influence neural activity throughout the brain, necessitating better computational models for understanding these connections.
- Facemap is a new framework that uses a keypoint tracker and a deep neural network to accurately predict mouse neural activity linked to these behaviors, outperforming existing tools in speed and precision.
- The model enhances our understanding of brain function by demonstrating that certain neuronal activity patterns are spatially distributed and exhibit unique, sequential dynamics, paving the way for further insights into behavior and brain signals.
Article Abstract
Recent studies in mice have shown that orofacial behaviors drive a large fraction of neural activity across the brain. To understand the nature and function of these signals, we need better computational models to characterize the behaviors and relate them to neural activity. Here we developed Facemap, a framework consisting of a keypoint tracker and a deep neural network encoder for predicting neural activity. Our algorithm for tracking mouse orofacial behaviors was more accurate than existing pose estimation tools, while the processing speed was several times faster, making it a powerful tool for real-time experimental interventions. The Facemap tracker was easy to adapt to data from new labs, requiring as few as 10 annotated frames for near-optimal performance. We used the keypoints as inputs to a deep neural network which predicts the activity of ~50,000 simultaneously-recorded neurons and, in visual cortex, we doubled the amount of explained variance compared to previous methods. Using this model, we found that the neuronal activity clusters that were well predicted from behavior were more spatially spread out across cortex. We also found that the deep behavioral features from the model had stereotypical, sequential dynamics that were not reversible in time. In summary, Facemap provides a stepping stone toward understanding the function of the brain-wide neural signals and their relation to behavior.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10774130 | PMC |
| http://dx.doi.org/10.1038/s41593-023-01490-6 | DOI Listing |
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