Abstract
Accurately describing synaptic interactions between neurons and how interactions change over time are key challenges for systems neuroscience. Although intracellular electrophysiology is a powerful tool for studying synaptic integration and plasticity, it is limited by the small number of neurons that can be recorded simultaneously in vitro and by the technical difficulty of intracellular recording in vivo. One way around these difficulties may be to use large-scale extracellular recording of spike trains and apply statistical methods to model and infer functional connections between neurons. These techniques have the potential to reveal large-scale connectivity structure based on the spike timing alone. However, the interpretation of functional connectivity is often approximate, since only a small fraction of presynaptic inputs are typically observed. Here we use in vitro current injection in layer 2/3 pyramidal neurons to validate methods for inferring functional connectivity in a setting where input to the neuron is controlled. In experiments with partially-defined input, we inject a single simulated input with known amplitude on a background of fluctuating noise. In a fully-defined input paradigm, we then control the synaptic weights and timing of many simulated presynaptic neurons. By analyzing the firing of neurons in response to these artificial inputs, we ask 1) How does functional connectivity inferred from spikes relate to simulated synaptic input? and 2) What are the limitations of connectivity inference? We find that individual current-based synaptic inputs are detectable over a broad range of amplitudes and conditions. Detectability depends on input amplitude and output firing rate, and excitatory inputs are detected more readily than inhibitory. Moreover, as we model increasing numbers of presynaptic inputs, we are able to estimate connection strengths more accurately and detect the presence of connections more quickly. These results illustrate the possibilities and outline the limits of inferring synaptic input from spikes.
Highlights
Neural computation requires fast, structured transformations from presynaptic input to postsynaptic spiking [1,2,3]
Synapses play a central role in neural information processing – weighting individual inputs in different ways allows neurons to perform a range of computations, and the changing of PLOS Computational Biology | DOI:10.1371/journal.pcbi
With a sufficient amount of data, accurate inference is often possible, and can become more accurate as more of the presynaptic inputs are observed
Summary
Neural computation requires fast, structured transformations from presynaptic input to postsynaptic spiking [1,2,3]. Changes in these transformations underlie learning, memory, and recovery from injury [4,5]. Synaptic integration and plasticity are studied using intracellular recordings in vitro, where synaptic weights can be directly measured as the amplitude of postsynaptic potentials or currents. Estimation of synaptic interactions from extracellularly recorded spike trains requires development of sensitive data analysis tools. We provide empirical tests of statistical tools for such analysis using in vitro current injection where the true synaptic input is known
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