A Point Process Framework for Relating Neural Spiking Activity to Spiking History, Neural Ensemble, and Extrinsic Covariate Effects

2005 ◽  
Vol 93 (2) ◽  
pp. 1074-1089 ◽  
Author(s):  
Wilson Truccolo ◽  
Uri T. Eden ◽  
Matthew R. Fellows ◽  
John P. Donoghue ◽  
Emery N. Brown
Keyword(s):  
Point Process ◽  
Discrete Time ◽  
Likelihood Function ◽  
Intensity Function ◽  
Relative Importance ◽  
Conditional Intensity ◽  
Process Framework ◽  
Neural Spiking ◽  
Conditional Intensity Function ◽  
Spiking Activity

Multiple factors simultaneously affect the spiking activity of individual neurons. Determining the effects and relative importance of these factors is a challenging problem in neurophysiology. We propose a statistical framework based on the point process likelihood function to relate a neuron's spiking probability to three typical covariates: the neuron's own spiking history, concurrent ensemble activity, and extrinsic covariates such as stimuli or behavior. The framework uses parametric models of the conditional intensity function to define a neuron's spiking probability in terms of the covariates. The discrete time likelihood function for point processes is used to carry out model fitting and model analysis. We show that, by modeling the logarithm of the conditional intensity function as a linear combination of functions of the covariates, the discrete time point process likelihood function is readily analyzed in the generalized linear model (GLM) framework. We illustrate our approach for both GLM and non-GLM likelihood functions using simulated data and multivariate single-unit activity data simultaneously recorded from the motor cortex of a monkey performing a visuomotor pursuit-tracking task. The point process framework provides a flexible, computationally efficient approach for maximum likelihood estimation, goodness-of-fit assessment, residual analysis, model selection, and neural decoding. The framework thus allows for the formulation and analysis of point process models of neural spiking activity that readily capture the simultaneous effects of multiple covariates and enables the assessment of their relative importance.

Estimating a State-Space Model from Point Process Observations

2003 ◽  
Vol 15 (5) ◽  
pp. 965-991 ◽  
Author(s):  
Anne C. Smith ◽  
Emery N. Brown
Keyword(s):  
State Space ◽  
Point Process ◽  
State Space Model ◽  
The State ◽  
Conditional Intensity ◽  
Space Model ◽  
Neural Spiking ◽  
Latent Process ◽  
Conditional Intensity Function ◽  
Spiking Activity

A widely used signal processing paradigm is the state-space model. The state-space model is defined by two equations: an observation equation that describes how the hidden state or latent process is observed and a state equation that defines the evolution of the process through time. Inspired by neurophysiology experiments in which neural spiking activity is induced by an implicit (latent) stimulus, we develop an algorithm to estimate a state-space model observed through point process measurements. We represent the latent process modulating the neural spiking activity as a gaussian autoregressive model driven by an external stimulus. Given the latent process, neural spiking activity is characterized as a general point process defined by its conditional intensity function. We develop an approximate expectation-maximization (EM) algorithm to estimate the unobservable state-space process, its parameters, and the parameters of the point process. The EM algorithm combines a point process recursive nonlinear filter algorithm, the fixed interval smoothing algorithm, and the state-space covariance algorithm to compute the complete data log likelihood efficiently. We use a Kolmogorov-Smirnov test based on the time-rescaling theorem to evaluate agreement between the model and point process data. We illustrate the model with two simulated data examples: an ensemble of Poisson neurons driven by a common stimulus and a single neuron whose conditional intensity function is approximated as a local Bernoulli process.

A Computationally Efficient Method for Nonparametric Modeling of Neural Spiking Activity with Point Processes

2010 ◽  
Vol 22 (8) ◽  
pp. 2002-2030 ◽  
Author(s):  
Todd P. Coleman ◽  
Sridevi S. Sarma
Keyword(s):  
Point Process ◽  
Point Processes ◽  
Intensity Function ◽  
Process Models ◽  
Conditional Intensity ◽  
Computationally Efficient ◽  
Neural Data ◽  
Neural Spiking ◽  
Point Process Models ◽  
Conditional Intensity Function

Point-process models have been shown to be useful in characterizing neural spiking activity as a function of extrinsic and intrinsic factors. Most point-process models of neural activity are parametric, as they are often efficiently computable. However, if the actual point process does not lie in the assumed parametric class of functions, misleading inferences can arise. Nonparametric methods are attractive due to fewer assumptions, but computation in general grows with the size of the data. We propose a computationally efficient method for nonparametric maximum likelihood estimation when the conditional intensity function, which characterizes the point process in its entirety, is assumed to be a Lipschitz continuous function but otherwise arbitrary. We show that by exploiting much structure, the problem becomes efficiently solvable. We next demonstrate a model selection procedure to estimate the Lipshitz parameter from data, akin to the minimum description length principle and demonstrate consistency of our estimator under appropriate assumptions. Finally, we illustrate the effectiveness of our method with simulated neural spiking data, goldfish retinal ganglion neural data, and activity recorded in CA1 hippocampal neurons from an awake behaving rat. For the simulated data set, our method uncovers a more compact representation of the conditional intensity function when it exists. For the goldfish and rat neural data sets, we show that our nonparametric method gives a superior absolute goodness-of-fit measure used for point processes than the most common parametric and splines-based approaches.

Measuring the association of a time series and a point process

1982 ◽  
Vol 19 (3) ◽  
pp. 597-608 ◽  
Author(s):  
J. S. Willie
Keyword(s):  
Time Series ◽  
Point Process ◽  
Intensity Function ◽  
Asymptotic Distributions ◽  
The Other ◽  
Stationary Case ◽  
Conditional Intensity ◽  
A Value ◽  
Conditional Intensity Function ◽  
Ordinary Time

We consider a bivariate stochastic process where one component is an ordinary time series and the other is a point process. In the stationary case, a useful measure of the association of the time series and the point process is provided by a conditional intensity function, ṙ11(x;u), which gives the intensity with which events occur near time t given that the time series takes on a value x at time t + u. In this paper we consider the estimation of the function ṙ11(x;u) and certain related functions that are also useful in partially characterizing the degree of interdependence of the time series and the point process. Histogram and smoothed histogram-type estimates are proposed and asymptotic distributions of these estimates are derived. We also discuss an application of the estimation theory to the analysis of some data from a neurophysiological study.

Exploratory analysis of earthquake clusters by likelihood-based trigger models

2001 ◽  
Vol 38 (A) ◽  
pp. 202-212 ◽  
Author(s):  
Yosihiko Ogata
Keyword(s):  
Maximum Likelihood ◽  
Point Process ◽  
Process Model ◽  
Intensity Function ◽  
Exploratory Analysis ◽  
Maximum Likelihood Estimates ◽  
Conditional Intensity ◽  
Point Process Model ◽  
Conditional Intensity Function ◽  
Earthquake Clusters

The paper considers the superposition of modified Omori functions as a conditional intensity function for a point process model used in the exploratory analysis of earthquake clusters. For the examples discussed, the maximum likelihood estimates converge well starting from appropriate initial values even though the number of parameters estimated can be large (though never larger than the number of observations). Three datasets are subjected to different analyses, showing the use of the model to discover and study individual clustering features.

Measuring the association of a time series and a point process

1982 ◽  
Vol 19 (03) ◽  
pp. 597-608
Author(s):  
J. S. Willie
Keyword(s):  
Time Series ◽  
Point Process ◽  
Intensity Function ◽  
Asymptotic Distributions ◽  
The Other ◽  
Stationary Case ◽  
Conditional Intensity ◽  
A Value ◽  
Conditional Intensity Function ◽  
Ordinary Time

We consider a bivariate stochastic process where one component is an ordinary time series and the other is a point process. In the stationary case, a useful measure of the association of the time series and the point process is provided by a conditional intensity function, ṙ 11(x;u), which gives the intensity with which events occur near time t given that the time series takes on a value x at time t + u. In this paper we consider the estimation of the function ṙ 11(x;u) and certain related functions that are also useful in partially characterizing the degree of interdependence of the time series and the point process. Histogram and smoothed histogram-type estimates are proposed and asymptotic distributions of these estimates are derived. We also discuss an application of the estimation theory to the analysis of some data from a neurophysiological study.

Exploratory analysis of earthquake clusters by likelihood-based trigger models

2001 ◽  
Vol 38 (A) ◽  
pp. 202-212 ◽  
Author(s):  
Yosihiko Ogata
Keyword(s):  
Maximum Likelihood ◽  
Point Process ◽  
Process Model ◽  
Intensity Function ◽  
Exploratory Analysis ◽  
Maximum Likelihood Estimates ◽  
Conditional Intensity ◽  
Point Process Model ◽  
Conditional Intensity Function ◽  
Earthquake Clusters

The paper considers the superposition of modified Omori functions as a conditional intensity function for a point process model used in the exploratory analysis of earthquake clusters. For the examples discussed, the maximum likelihood estimates converge well starting from appropriate initial values even though the number of parameters estimated can be large (though never larger than the number of observations). Three datasets are subjected to different analyses, showing the use of the model to discover and study individual clustering features.

scholarly journals Estimating a Separably Markov Random Field from Binary Observations

2018 ◽  
Vol 30 (4) ◽  
pp. 1046-1079 ◽  
Author(s):  
Yingzhuo Zhang ◽  
Noa Malem-Shinitski ◽  
Stephen A. Allsop ◽  
Kay M. Tye ◽  
Demba Ba
Keyword(s):  
Random Field ◽  
Fundamental Problem ◽  
Conditional Intensity ◽  
Computational Tools ◽  
Markov Random ◽  
Neural Spiking ◽  
Conditional Intensity Function ◽  
Neural Underpinnings ◽  
Over Time

A fundamental problem in neuroscience is to characterize the dynamics of spiking from the neurons in a circuit that is involved in learning about a stimulus or a contingency. A key limitation of current methods to analyze neural spiking data is the need to collapse neural activity over time or trials, which may cause the loss of information pertinent to understanding the function of a neuron or circuit. We introduce a new method that can determine not only the trial-to-trial dynamics that accompany the learning of a contingency by a neuron, but also the latency of this learning with respect to the onset of a conditioned stimulus. The backbone of the method is a separable two-dimensional (2D) random field (RF) model of neural spike rasters, in which the joint conditional intensity function of a neuron over time and trials depends on two latent Markovian state sequences that evolve separately but in parallel. Classical tools to estimate state-space models cannot be applied readily to our 2D separable RF model. We develop efficient statistical and computational tools to estimate the parameters of the separable 2D RF model. We apply these to data collected from neurons in the prefrontal cortex in an experiment designed to characterize the neural underpinnings of the associative learning of fear in mice. Overall, the separable 2D RF model provides a detailed, interpretable characterization of the dynamics of neural spiking that accompany the learning of a contingency.

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