Abstract
The relative timing of action potentials in neurons recorded from local cortical networks often shows a non-trivial dependence, which is then quantified by cross-correlation functions. Theoretical models emphasize that such spike train correlations are an inevitable consequence of two neurons being part of the same network and sharing some synaptic input. For non-linear neuron models, however, explicit correlation functions are difficult to compute analytically, and perturbative methods work only for weak shared input. In order to treat strong correlations, we suggest here an alternative non-perturbative method. Specifically, we study the case of two leaky integrate-and-fire neurons with strong shared input. Correlation functions derived from simulated spike trains fit our theoretical predictions very accurately. Using our method, we computed the non-linear correlation transfer as well as correlation functions that are asymmetric due to inhomogeneous intrinsic parameters or unequal input.
Highlights
Electric activity generated by different neurons in the brain is often strongly correlated [1,2,3,4]
We look at the full range of input correlations and provide an example of a non-linear correlation transfer function
In order to study correlations between the spike trains of two neurons we look at two coupled stochastic equations, describing the membrane potentials of two neurons that share a certain fraction of their excitatory and inhibitory input spikes
Summary
Electric activity generated by different neurons in the brain is often strongly correlated [1,2,3,4]. These correlations arise as a result of shared input, or input components that are themselves correlated. Correlated activity can be a consequence of shared background fluctuations [5], but strong correlations might indicate synchronous action potentials at the input indicating temporal coding. Recent high-precision measurements reported very low average correlations suggesting a mechanism of active decorrelation in cortical networks [9,10,11,12]. At the same time it was observed by intracellular measurements that nearby neurons receive very similar input [2,3,4]
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