Hierarchical Bayesian modeling of multiregion brain cell count data

Sydney Dimmock; Benjamin MS Exley; Gerald Moore; Lucy Menage; Alessio Delogu; Simon R Schultz; E Clea Warburton; Conor J Houghton; Cian O'Donnell; Gordon J Berman; Panayiota Poirazi

doi:10.7554/elife.102391

Hierarchical Bayesian modeling of multiregion brain cell count data

Sydney Dimmock, Benjamin MS Exley, Gerald Moore, Lucy Menage, Alessio Delogu, Simon R Schultz, E Clea Warburton, Conor J Houghton, Cian O'Donnell, Gordon J Berman (Editor), Panayiota Poirazi

Research output: Contribution to journal › Article › peer-review

Abstract

We can now collect cell-count data across whole animal brains quantifying recent neuronal activity, gene expression, or anatomical connectivity. This is a powerful approach since it is a multiregion measurement, but because the imaging is done postmortem, each animal only provides one set of counts. Experiments are expensive, and since cells are counted by imaging and aligning a large number of brain sections, they are time-intensive. The resulting datasets tend to be undersampled with fewer animals than brain regions. As a consequence, these data are a challenge for traditional statistical approaches. We present a ‘standard’ partially pooled Bayesian model for multiregion cell-count data and apply it to two example datasets. These examples demonstrate that hierarchical Bayesian methods are well suited to these data. In both cases, the Bayesian model outperformed standard parallel t-tests. Overall, inference for cell-count data is substantially improved by the ability of the Bayesian approach to capture nested data and by its rigorous handling of uncertainty in undersampled data.

Original language	English
Pages (from-to)	1-27
Number of pages	27
Journal	eLife
Volume	13
Early online date	21 Nov 2025
DOIs	https://doi.org/10.7554/elife.102391
Publication status	Published online - 21 Nov 2025

Data Access Statement

The code necessary to run the models presented in this manuscript can be found at Dimmock et al., 2025 and on our Github https://BayesianCellCounts.github.io. The data for case study one on nucleus reuniens lesion are available from https://doi.org/10.5281/zenodo.12787211 (Exley et al., 2024). The data from case study two on Sox14 expressing neurons are available from https://doi.org/10.5281/zenodo.12787287 (Gerald and Sydney, 2024).

Funding

Engineering and Physical Sciences Research Council (EP/R513179/1) Sydney Dimmock Engineering and Physical Sciences Research Council (EP/W024020/1) Simon R Schultz Biotechnology and Biological Sciences Research Council (BB/L02134X/1) E Clea Warburton Biotechnology and Biological Sciences Research Council (BB/R007020/1) Alessio Delogu Wellcome Trust (206401/Z/17/Z) E Clea Warburton Leverhulme Trust (RF-2021-533) Conor J Houghton Medical Research Council (MR/S026630/1) Cian O'Donnell The funders had no role in study design, data collection and interpretation, or the decision to submit the work for publication. For the purpose of Open Access, the authors have applied a CC BY public copyright license to any Author Accepted Manuscript version arising from this submission.

Keywords

cell-count data
Rat
Bayesian analysis
hierarchical modeling
Mouse

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10.7554/elife.102391

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title = "Hierarchical Bayesian modeling of multiregion brain cell count data",

abstract = "We can now collect cell-count data across whole animal brains quantifying recent neuronal activity, gene expression, or anatomical connectivity. This is a powerful approach since it is a multiregion measurement, but because the imaging is done postmortem, each animal only provides one set of counts. Experiments are expensive, and since cells are counted by imaging and aligning a large number of brain sections, they are time-intensive. The resulting datasets tend to be undersampled with fewer animals than brain regions. As a consequence, these data are a challenge for traditional statistical approaches. We present a {\textquoteleft}standard{\textquoteright} partially pooled Bayesian model for multiregion cell-count data and apply it to two example datasets. These examples demonstrate that hierarchical Bayesian methods are well suited to these data. In both cases, the Bayesian model outperformed standard parallel t-tests. Overall, inference for cell-count data is substantially improved by the ability of the Bayesian approach to capture nested data and by its rigorous handling of uncertainty in undersampled data.",

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AU - Dimmock, Sydney

AU - Exley, Benjamin MS

AU - Moore, Gerald

AU - Menage, Lucy

AU - Delogu, Alessio

AU - Schultz, Simon R

AU - Warburton, E Clea

AU - Houghton, Conor J

AU - O'Donnell, Cian

AU - Poirazi, Panayiota

A2 - Berman, Gordon J

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AB - We can now collect cell-count data across whole animal brains quantifying recent neuronal activity, gene expression, or anatomical connectivity. This is a powerful approach since it is a multiregion measurement, but because the imaging is done postmortem, each animal only provides one set of counts. Experiments are expensive, and since cells are counted by imaging and aligning a large number of brain sections, they are time-intensive. The resulting datasets tend to be undersampled with fewer animals than brain regions. As a consequence, these data are a challenge for traditional statistical approaches. We present a ‘standard’ partially pooled Bayesian model for multiregion cell-count data and apply it to two example datasets. These examples demonstrate that hierarchical Bayesian methods are well suited to these data. In both cases, the Bayesian model outperformed standard parallel t-tests. Overall, inference for cell-count data is substantially improved by the ability of the Bayesian approach to capture nested data and by its rigorous handling of uncertainty in undersampled data.

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KW - Bayesian analysis

KW - hierarchical modeling

KW - Mouse

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ER -

Hierarchical Bayesian modeling of multiregion brain cell count data

Abstract

Data Access Statement

Funding

Keywords

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