Abstract
The dynamics of local cortical networks are irregular, but correlated. Dynamic excitatory-inhibitory balance is a plausible mechanism that generates such irregular activity, but it remains unclear how balance is achieved and maintained in plastic neural networks. In particular, it is not fully understood how plasticity induced changes in the network affect balance, and in turn, how correlated, balanced activity impacts learning. How do the dynamics of balanced networks change under different plasticity rules? How does correlated spiking activity in recurrent networks change the evolution of weights, their eventual magnitude, and structure across the network? To address these questions, we develop a theory of spike-timing dependent plasticity in balanced networks. We show that balance can be attained and maintained under plasticity-induced weight changes. We find that correlations in the input mildly affect the evolution of synaptic weights. Under certain plasticity rules, we find an emergence of correlations between firing rates and synaptic weights. Under these rules, synaptic weights converge to a stable manifold in weight space with their final configuration dependent on the initial state of the network. Lastly, we show that our framework can also describe the dynamics of plastic balanced networks when subsets of neurons receive targeted optogenetic input.
Highlights
Cortical neuronal activity is irregular, correlated, dominated by a low dimensional component [1,2,3,4,5,6], and characterized by a balance between excitation and inhibition [7,8,9,10,11,12]
We apply the theory described in the Methods to show how synaptic weights coevolve with firing rates in balanced networks under different plasticity rules
We start with an example of excitatory plasticity which has been the main focus of experimental and theoretical studies, and show that our theory can be used to determine the stability of balanced networks under commonly used excitatory spike– time dependent plasticity (STDP) rules
Summary
Cortical neuronal activity is irregular, correlated, dominated by a low dimensional component [1,2,3,4,5,6], and characterized by a balance between excitation and inhibition [7,8,9,10,11,12]. Using linear response and motif resumming techniques [43], Ocker et al developed a theory describing the evolution of mean weights in recurrent neural networks of noisy integrate–and–fire neurons under STDP [44]. This approach relies on the assumption that the input to individual cells is dominated by white noise, local synaptic input is weak, and that the integral of the STDP function is small. Montangie et al showed that a more realistic form of STDP based on spike triplets leads to autonomous emergence of assemblies [47]
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