CUED Publications database

Neural field models for latent state inference: Application to large-scale neuronal recordings

Rule, ME and Schnoerr, D and Hennig, MH and Sanguinetti, G (2019) Neural field models for latent state inference: Application to large-scale neuronal recordings. PLoS Computational Biology, 15. e1007442-. ISSN 1553-734X

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Large-scale neural recording methods now allow us to observe large populations of identified single neurons simultaneously, opening a window into neural population dynamics in living organisms. However, distilling such large-scale recordings to build theories of emergent collective dynamics remains a fundamental statistical challenge. The neural field models of Wilson, Cowan, and colleagues remain the mainstay of mathematical population modeling owing to their interpretable, mechanistic parameters and amenability to mathematical analysis. Inspired by recent advances in biochemical modeling, we develop a method based on moment closure to interpret neural field models as latent state-space point-process models, making them amenable to statistical inference. With this approach we can infer the intrinsic states of neurons, such as active and refractory, solely from spiking activity in large populations. After validating this approach with synthetic data, we apply it to high-density recordings of spiking activity in the developing mouse retina. This confirms the essential role of a long lasting refractory state in shaping spatiotemporal properties of neonatal retinal waves. This conceptual and methodological advance opens up new theoretical connections between mathematical theory and point-process state-space models in neural data analysis.

Item Type: Article
Divisions: Div F > Control
Depositing User: Unnamed user with email
Date Deposited: 08 Nov 2019 21:06
Last Modified: 09 Sep 2021 02:11
DOI: 10.1371/journal.pcbi.1007442