Inferring and validating mechanistic models of neural microcircuits based on spike-train data

Ladenbauer, Josef; McKenzie, Sam; English, Daniel F.; Hagens, Olivier; Ostojic, Srdjan

doi:10.1101/261016

Cited by 14 publications

(23 citation statements)

References 113 publications

(213 reference statements)

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“…The membrane voltage can be scaled such that the remaining parameters of interest for inference are those for the input together with the membrane time constant (see Methods section 1). Moreover, a change of τ m can be well compensated for in terms of spiking dynamics by appropriate changes ofμ i and σ i [25]. Therefore, we focus on the following parameters for inference C i ,μ i , σ i for i ∈ {1, .…”

Section: Statistical Modeling With Doubly-stochastic Iandf Neuronsmentioning

confidence: 99%

“…p(s k |µ k , ϑ) is the ISI probability density of the leaky I&F neuron exposed to Gaussian white noise input (with mean µ k and standard deviation σ), evaluated at ISI s k . This density can be accurately computed by solving a Fokker-Planck partial differential equation, which can be achieved numerically in efficient ways [25]. p(x k |x k−1 , τ ) is the transition probability density for x(t), from state x k−1 to state x k , which depends on the time constant τ and on the time duration between states x k−1 and x k .…”

Section: Outline Of Inference Approachmentioning

confidence: 99%

“…Setting τ m instead to a wrong value within a biologically plausible range affects the maximal likelihood only very little (see Fig S1), because a change of τ m can be well compensated for in terms of spiking dynamics by suitable changes of the input parameters (cf. [25]). We, therefore, keep τ m fixed for the rest of this study.…”

Section: Evaluation On Synthetic Datamentioning

confidence: 99%

“…At the core of our methodology we exploit efficient numerical schemes to compute the ISI probability density of an I&F neuron exposed to Gaussian white noise input with high precision. The ability to rapidly compute this density allows to evaluate the likelihood of observed spike trains, which has been previously used for inference purposes using single stochastic I&F neurons [25,38] and networks [25]. The nonstationarity considered here (doubly-stochastic population model) constitutes a relevant and highly nontrivial extension.…”

Section: Related Workmentioning

confidence: 99%

“…We present a statistically principled approach based on derived likelihood functions to fit this type of model to single-trial spike trains and quantitatively compare different model variants, including simpler phenomenological models. Specifically, we efficiently compute the likelihood of a given spike train by exploiting analytical methods for stochastic I&F neuron models [25] combined with inference techniques for hidden Markov models [26]. This allows us to infer the model parameters by likelihood maximization, classify the latent dynamics via likelihood-based model selection, and estimate hidden time series from the time-varying probability density over the latent state.…”

Section: Introductionmentioning

confidence: 99%

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Inferring the collective dynamics of neuronal populations from single-trial spike trains using mechanistic models

Donner

Opper

Ladenbauer

2019

Preprint

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Multi-neuronal spike-train data recorded in vivo often exhibit rich dynamics as well as considerable variability across cells and repetitions of identical experimental conditions (trials). Efforts to characterize and predict the population dynamics and the contributions of individual neurons require model-based tools. Abstract statistical models allow for principled parameter estimation and model selection, but possess only limited interpretive power because they typically do not incorporate prior biophysical constraints. Here we present a statistically principled approach based on a population of doubly-stochastic integrate-and-fire neurons, taking into account basic biophysics. This model class comprises an idealized description for the dynamics of the neuronal membrane voltage in response to fast independent and slower shared input fluctuations. To efficiently estimate the model parameters and compare different model variants we compute the likelihood of observed single-trail spike trains by leveraging analytical methods for spiking neuron models combined with inference techniques for hidden Markov models. This allows us to reconstruct the shared input variations, classify their dynamics, obtain precise spike rate estimates, and quantify how individual neurons couple to the low-dimensional overall population dynamics, all from a single trial. Extensive evaluations based on simulated data show that our method correctly identifies the dynamics of the shared input process and accurately estimates the model parameters. Validations on ground truth recordings of neurons in vitro demonstrate that our approach successfully reconstructs the dynamics of hidden inputs and yields improved fits compared to a typical phenomenological model. Finally, we apply the method to a neuronal population recorded in vivo, for which we assess the contributions of individual neurons to the overall spiking dynamics. Altogether, our work provides statistical inference tools for a class of reasonably constrained, mechanistic models and demonstrates the benefits of this approach to analyze measured spike train data.

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Section: Statistical Modeling With Doubly-stochastic Iandf Neuronsmentioning

confidence: 99%

Section: Outline Of Inference Approachmentioning

confidence: 99%

Section: Evaluation On Synthetic Datamentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Inferring the collective dynamics of neuronal populations from single-trial spike trains using mechanistic models

Donner

Opper

Ladenbauer

2019

Preprint

Self Cite

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Recurrent neural networks with explicit representation of dynamic latent variables can mimic behavioral patterns in a physical inference task

2022

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Primates can richly parse sensory inputs to infer latent information. This ability is hypothesized to rely on establishing mental models of the external world and running mental simulations of those models. However, evidence supporting this hypothesis is limited to behavioral models that do not emulate neural computations. Here, we test this hypothesis by directly comparing the behavior of primates (humans and monkeys) in a ball interception task to that of a large set of recurrent neural network (RNN) models with or without the capacity to dynamically track the underlying latent variables. Humans and monkeys exhibit similar behavioral patterns. This primate behavioral pattern is best captured by RNNs endowed with dynamic inference, consistent with the hypothesis that the primate brain uses dynamic inferences to support flexible physical predictions. Moreover, our work highlights a general strategy for using model neural systems to test computational hypotheses of higher brain function.

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Model-based detection of putative synaptic connections from spike recordings with latency and type constraints

Ren

Ito

Hafizi

et al. 2020

Preprint

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8Detecting synaptic connections using large-scale extracellular spike recordings presents a statistical challenge. 9While previous methods often treat the detection of each putative connection as a separate hypothesis test, here 10 we develop a modeling approach that infers synaptic connections while incorporating circuit properties learned 11 from the whole network. We use an extension of the Generalized Linear Model framework to describe the cross-12 correlograms between pairs of neurons and separate correlograms into two parts: a slowly varying effect due to 13 background fluctuations and a fast, transient effect due to the synapse. We then use the observations from all 14 putative connections in the recording to estimate two network properties: the presynaptic neuron type (excitatory 15 or inhibitory) and the relationship between synaptic latency and distance between neurons. Constraining the 16 presynaptic neuron's type, synaptic latencies, and time constants improves synapse detection. In data from 17 simulated networks, this model outperforms two previously developed synapse detection methods, especially on 18 the weak connections. We also apply our model to in vitro multielectrode array recordings from mouse 19 somatosensory cortex. Here our model automatically recovers plausible connections from hundreds of neurons, 20 and the properties of the putative connections are largely consistent with previous research. 21 22 Using in vivo or in vitro multielectrode arrays, the extracellular spiking of hundreds of neurons can be recorded 24 simultaneously. These recordings are allowing new, large-scale studies of neuronal networks (Hahn et al. 2019; 25 Harris et al. 2003; Levenstein et al. 2019; Okun et al. 2015; Tingley and Buzsáki 2018), and the number of 26 neurons that can be simultaneously recorded is increasing approximately exponentially (Stevenson and Kording 27 2011). Depending on the species, brain area, and electrode configuration, these simultaneously recorded 28 neurons can have tens of thousands of potential synapses between them. Detecting and characterizing these 29 synapses represents a major challenge for neural data analysis. Here, we develop a model-based method 30 incorporating network-level constraints on 1) the presynaptic neuron type and 2) the synaptic latencies between 31 pre-and postsynaptic neurons. We examine whether these constraints can improve synapse detection using 32 simulated data and large-scale in vitro multielectrode array recordings. 33 34Detecting synaptic connections from extracellular spike observations is a difficult statistical problem. Since both 35 spiking and synapses themselves are sparse, it is often difficult to distinguish between changes in spike 36 probability that are due to a specific synaptic input, changes that are due other (typically unobserved) inputs, or 37 due to chance. Using extracellular spike data, researchers often identify putative monosynaptic connections by 38 examining cross-correlograms between the spiking of two neurons. If two neu...

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Inferring and validating mechanistic models of neural microcircuits based on spike-train data

Cited by 14 publications

References 113 publications

Inferring the collective dynamics of neuronal populations from single-trial spike trains using mechanistic models

Inferring the collective dynamics of neuronal populations from single-trial spike trains using mechanistic models

Recurrent neural networks with explicit representation of dynamic latent variables can mimic behavioral patterns in a physical inference task

Model-based detection of putative synaptic connections from spike recordings with latency and type constraints

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