A Dynamic Bayesian Model for Characterizing Cross-Neuronal Interactions During Decision-Making

Zhou, Bo; Moorman, David E.; Behseta, Sam; Ombao, Hernando; Shahbaba, Babak

doi:10.1080/01621459.2015.1116988

Cited by 7 publications

(4 citation statements)

References 75 publications

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“…There could also be fluctuations on an even longer time scale. There are several methods for processing such nonstationarity, including the state-space models 56,57 or the Gaussian process 58 . Such slow fluctuations may induce variation in the CC amplitude, but they would not appear in the averaged cross-correlogram in an interval of 100 ms in our framework.…”

Section: Discussionmentioning

confidence: 99%

Reconstructing neuronal circuitry from parallel spike trains

et al. 2019

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State-of-the-art techniques allow researchers to record large numbers of spike trains in parallel for many hours. With enough such data, we should be able to infer the connectivity among neurons. Here we develop a method for reconstructing neuronal circuitry by applying a generalized linear model (GLM) to spike cross-correlations. Our method estimates connections between neurons in units of postsynaptic potentials and the amount of spike recordings needed to verify connections. The performance of inference is optimized by counting the estimation errors using synthetic data. This method is superior to other established methods in correctly estimating connectivity. By applying our method to rat hippocampal data, we show that the types of estimated connections match the results inferred from other physiological cues. Thus our method provides the means to build a circuit diagram from recorded spike trains, thereby providing a basis for elucidating the differences in information processing in different brain regions.

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Section: Discussionmentioning

confidence: 99%

Reconstructing neuronal circuitry from parallel spike trains

et al. 2019

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“…Gaussian process have been widely developed in spatial-temporal modeling (Williams and Rasmussen, 2006;Banerjee et al, 2008Banerjee et al, , 2014Gelfand et al, 2005;Quick et al, 2013;Stein, 2012;Zhou et al, 2015;Vandenberg-Rodes and Shahbaba, 2015;Wang and Gelfand, 2014). It provides a framework that can capture the non-linear and stochastic components of exogenous and endogenous variables based on generalized linear models, which makes it useful for modeling binary time series and classification.…”

Section: Gaussian Process and Regression Modelsmentioning

confidence: 99%

Modeling Binary Time Series Using Gaussian Processes with Application to Predicting Sleep States

Shahbaba

Ombao

2018

J Classif

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Motivated by the problem of predicting sleep states, we develop a mixed effects model for binary time series with a stochastic component represented by a Gaussian process. The fixed component captures the effects of covariates on the binary-valued response. The Gaussian process captures the residual variations in the binary response that are not explained by covariates and past realizations. We develop a frequentist modeling framework that provides efficient inference and more accurate predictions. Results demonstrate the advantages of improved prediction rates over existing approaches such as logistic regression, generalized additive mixed model, models for ordinal data, gradient boosting, decision tree and random forest. Using our proposed model, we show that previous sleep state and heart rates are significant predictors for future sleep states. Simulation studies also show that our proposed method is promising and robust. To handle computational complexity, we utilize Laplace approximation, golden section search and successive parabolic interpolation. With this paper, we also submit an R-package (HIBITS) that implements the proposed procedure.

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“…Furthermore, the Poisson process has very limited multivariate generalizations in terms of dependence structure [12,9,4,11,6,7]. Some alternative models include Integrate-and-Fire models [3,13], GLMs [8,2,17,18], renewal processes [10], and latent variable models [16,19].…”

Section: Introductionmentioning

confidence: 99%

A Multivariate Point Process Model for Simultaneously Recorded Neural Spike Trains

Ramezan¹,

Chen²,

Lysy³

et al. 2022

Preprint

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The current state-of-the-art in neurophysiological data collection allows for simultaneous recording of tens to hundreds of neurons, for which point processes are an appropriate statistical modelling framework. However, existing point process models lack multivariate generalizations which are both flexible and computationally tractable. This paper introduces a multivariate generalization of the Skellam process with resetting (SPR), a point process tailored to model individual neural spike trains. The multivariate SPR (MSPR) is biologically justified as it mimics the process of neural integration. Its flexible dependence structure and a fast parameter estimation method make it well-suited for the analysis of simultaneously recorded spike trains from multiple neurons.The strengths and weaknesses of the MSPR are demonstrated through simulation and analysis of experimental data.

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A Dynamic Bayesian Model for Characterizing Cross-Neuronal Interactions During Decision-Making

Cited by 7 publications

References 75 publications

Reconstructing neuronal circuitry from parallel spike trains

Reconstructing neuronal circuitry from parallel spike trains

Modeling Binary Time Series Using Gaussian Processes with Application to Predicting Sleep States

A Multivariate Point Process Model for Simultaneously Recorded Neural Spike Trains

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