期刊
JOURNAL OF COMPUTATIONAL NEUROSCIENCE
卷 49, 期 2, 页码 131-157出版社
SPRINGER
DOI: 10.1007/s10827-020-00770-5
关键词
Integrate-and-fire neuron; Spike correlogram; Noise models; Synchrony; Synaptic connectivity; Nonstationarity
资金
- NIMH [R01-MH102840, K99 MH118423]
- DOD ARO [W911NF-15-1-0426]
- PSC-CUNY [68521-00 46]
This study focuses on constructing biophysical models to replicate observed phenomena of in vivo monosynaptic interactions, with a particular emphasis on estimating the causal effect of monosynapses and implementing synaptic inference using statistical techniques. By analyzing pairwise spiking features in a large-scale in vivo dataset, the study aims to accurately identify the monosynaptic effect and explore neurostatistical assumptions related to biophysical mechanisms, especially in terms of fast, unobservable nonstationarities in background dynamics.
Observations of finely-timed spike relationships in population recordings have been used to support partial reconstruction of neural microcircuit diagrams. In this approach, fine-timescale components of paired spike train interactions are isolated and subsequently attributed to synaptic parameters. Recent perturbation studies strengthen the case for such an inference, yet the complete set of measurements needed to calibrate statistical models is unavailable. To address this gap, we study features of pairwise spiking in a large-scale in vivo dataset where presynaptic neurons were explicitly decoupled from network activity by juxtacellular stimulation. We then construct biophysical models of paired spike trains to reproduce the observed phenomenology of in vivo monosynaptic interactions, including both fine-timescale spike-spike correlations and firing irregularity. A key characteristic of these models is that the paired neurons are coupled by rapidly-fluctuating background inputs. We quantify a monosynapse's causal effect by comparing the postsynaptic train with its counterfactual, when the monosynapse is removed. Subsequently, we develop statistical techniques for estimating this causal effect from the pre- and post-synaptic spike trains. A particular focus is the justification and application of a nonparametric separation of timescale principle to implement synaptic inference. Using simulated data generated from the biophysical models, we characterize the regimes in which the estimators accurately identify the monosynaptic effect. A secondary goal is to initiate a critical exploration of neurostatistical assumptions in terms of biophysical mechanisms, particularly with regards to the challenging but arguably fundamental issue of fast, unobservable nonstationarities in background dynamics.
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