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Main Authors: Duan, Yu, Chaudhry, Hamza Tahir, Ahrens, Misha B., Harvey, Christopher D, Perich, Matthew G, Deisseroth, Karl, Rajan, Kanaka
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.14957
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author Duan, Yu
Chaudhry, Hamza Tahir
Ahrens, Misha B.
Harvey, Christopher D
Perich, Matthew G
Deisseroth, Karl
Rajan, Kanaka
author_facet Duan, Yu
Chaudhry, Hamza Tahir
Ahrens, Misha B.
Harvey, Christopher D
Perich, Matthew G
Deisseroth, Karl
Rajan, Kanaka
contents Predicting future neural activity is a core challenge in modeling brain dynamics, with applications ranging from scientific investigation to closed-loop neurotechnology. While recent models of population activity emphasize interpretability and behavioral decoding, neural forecasting-particularly across multi-session, spontaneous recordings-remains underexplored. We introduce POCO, a unified forecasting model that combines a lightweight univariate forecaster with a population-level encoder to capture both neuron-specific and brain-wide dynamics. Trained across five calcium imaging datasets spanning zebrafish, mice, and C. elegans, POCO achieves state-of-the-art accuracy at cellular resolution in spontaneous behaviors. After pre-training, POCO rapidly adapts to new recordings with minimal fine-tuning. Notably, POCO's learned unit embeddings recover biologically meaningful structure-such as brain region clustering-without any anatomical labels. Our comprehensive analysis reveals several key factors influencing performance, including context length, session diversity, and preprocessing. Together, these results position POCO as a scalable and adaptable approach for cross-session neural forecasting and offer actionable insights for future model design. By enabling accurate, generalizable forecasting models of neural dynamics across individuals and species, POCO lays the groundwork for adaptive neurotechnologies and large-scale efforts for neural foundation models. Code is available at https://github.com/yuvenduan/POCO.
format Preprint
id arxiv_https___arxiv_org_abs_2506_14957
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle POCO: Scalable Neural Forecasting through Population Conditioning
Duan, Yu
Chaudhry, Hamza Tahir
Ahrens, Misha B.
Harvey, Christopher D
Perich, Matthew G
Deisseroth, Karl
Rajan, Kanaka
Neurons and Cognition
Machine Learning
Predicting future neural activity is a core challenge in modeling brain dynamics, with applications ranging from scientific investigation to closed-loop neurotechnology. While recent models of population activity emphasize interpretability and behavioral decoding, neural forecasting-particularly across multi-session, spontaneous recordings-remains underexplored. We introduce POCO, a unified forecasting model that combines a lightweight univariate forecaster with a population-level encoder to capture both neuron-specific and brain-wide dynamics. Trained across five calcium imaging datasets spanning zebrafish, mice, and C. elegans, POCO achieves state-of-the-art accuracy at cellular resolution in spontaneous behaviors. After pre-training, POCO rapidly adapts to new recordings with minimal fine-tuning. Notably, POCO's learned unit embeddings recover biologically meaningful structure-such as brain region clustering-without any anatomical labels. Our comprehensive analysis reveals several key factors influencing performance, including context length, session diversity, and preprocessing. Together, these results position POCO as a scalable and adaptable approach for cross-session neural forecasting and offer actionable insights for future model design. By enabling accurate, generalizable forecasting models of neural dynamics across individuals and species, POCO lays the groundwork for adaptive neurotechnologies and large-scale efforts for neural foundation models. Code is available at https://github.com/yuvenduan/POCO.
title POCO: Scalable Neural Forecasting through Population Conditioning
topic Neurons and Cognition
Machine Learning
url https://arxiv.org/abs/2506.14957