Abstract
Synaptic plasticity is believed to be the biological substrate underlying learning and memory. One of the most widespread forms of synaptic plasticity, spike-timing-dependent plasticity (STDP), uses the spike timing information of presynaptic and postsynaptic neurons to induce synaptic potentiation or depression. An open question is how STDP organizes the connectivity patterns in neuronal circuits. Previous studies have placed much emphasis on the role of firing rate in shaping connectivity patterns. Here, we go beyond the firing rate description to develop a self-consistent linear response theory that incorporates the information of both firing rate and firing variability. By decomposing the pairwise spike correlation into one component associated with local direct connections and the other associated with indirect connections, we identify two distinct regimes regarding the network structures learned through STDP. In one regime, the contribution of the direct-connection correlations dominates over that of the indirect-connection correlations in the learning dynamics; this gives rise to a network structure consistent with the firing rate description. In the other regime, the contribution of the indirect-connection correlations dominates in the learning dynamics, leading to a network structure different from the firing rate description. We demonstrate that the heterogeneity of firing variability across neuronal populations induces a temporally asymmetric structure of indirect-connection correlations. This temporally asymmetric structure underlies the emergence of the second regime. Our study provides a new perspective that emphasizes the role of high-order statistics of spiking activity in the spike-correlation-sensitive learning dynamics.
Highlights
Spike-timing-dependent plasticity (STDP) (Markram et al, 1997; Bi and Poo, 1998; Caporale and Dan, 2008) is one of the major forms of Hebbian learning
We first present the numerical evidence of the complexity of mutual interactions between plastic network structures and spiking activity, as it relates to the effect of high-order statistical structures implied in the STDP learning dynamics
We develop a selfconsistent linear response theory to account for the effects of both firing rate and firing variability on learning dynamics and explain the role observed in our numerical study of high-order statistics in learning dynamics
Summary
Spike-timing-dependent plasticity (STDP) (Markram et al, 1997; Bi and Poo, 1998; Caporale and Dan, 2008) is one of the major forms of Hebbian learning. The local direct connections dominate over the indirect connections in determining the learned network structure This regime corresponds to those studied in Babadi and Abbott (2013), Kozloski and Cecchi (2010), and Morrison et al (2007), where the connections from neurons of higher firing rate to those of lower firing rate are strengthened whereas the connections with the opposite situation are weakened. Using this framework, we demonstrate how the introduction of heterogeneity of firing variability across different neuronal populations can give rise to counterintuitive network connectivity structures in a plastic neuronal network
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