Abstract
In neural systems, synaptic plasticity is usually driven by spike trains. Due to the inherent noises of neurons and synapses as well as the randomness of connection details, spike trains typically exhibit variability such as spatial randomness and temporal stochasticity, resulting in variability of synaptic changes under plasticity, which we call efficacy variability. How the variability of spike trains influences the efficacy variability of synapses remains unclear. In this paper, we try to understand this influence under pair-wise additive spike-timing dependent plasticity (STDP) when the mean strength of plastic synapses into a neuron is bounded (synaptic homeostasis). Specifically, we systematically study, analytically and numerically, how four aspects of statistical features, i.e., synchronous firing, burstiness/regularity, heterogeneity of rates and heterogeneity of cross-correlations, as well as their interactions influence the efficacy variability in converging motifs (simple networks in which one neuron receives from many other neurons). Neurons (including the post-synaptic neuron) in a converging motif generate spikes according to statistical models with tunable parameters. In this way, we can explicitly control the statistics of the spike patterns, and investigate their influence onto the efficacy variability, without worrying about the feedback from synaptic changes onto the dynamics of the post-synaptic neuron. We separate efficacy variability into two parts: the drift part (DriftV) induced by the heterogeneity of change rates of different synapses, and the diffusion part (DiffV) induced by weight diffusion caused by stochasticity of spike trains. Our main findings are: (1) synchronous firing and burstiness tend to increase DiffV, (2) heterogeneity of rates induces DriftV when potentiation and depression in STDP are not balanced, and (3) heterogeneity of cross-correlations induces DriftV together with heterogeneity of rates. We anticipate our work important for understanding functional processes of neuronal networks (such as memory) and neural development.
Highlights
Neuronal spike trains typically exhibit spatial randomness and temporal stochasticity
We systematically study how the four aspects of spike pattern structures, i.e., synchronous firing, autocorrelation structure, heterogeneity of rates and heterogeneity of cross-correlations as well as their interactions, influence efficacy variability under spike-timing dependent plasticity (STDP) and synaptic homeostasis using converging motifs
We systematically studied the influences of four aspects of pattern structures onto efficacy variability under STDP, using spike generating models on converging motifs
Summary
Neuronal spike trains typically exhibit spatial randomness and temporal stochasticity. The spatial randomness may emerge from the randomness of the connection details (Ostojic et al, 2009; Roxin et al, 2011), and the temporal stochasticity may be due to the inner stochasticity of neurons and synapses (Allen and Stevens, 1994; Mainen and Sejnowski, 1995; Shadlen and Newsome, 1998), both of which are inherent properties of neurons, synapses or networks so that the exact spike patterns of the network cannot be fully determined by its inputs. When the synapses are fixed, downstream neurons may work under the variability of spike trains by reading out the coded information through spatial and temporal averaging; how the variability of the spike trains influences the ability of the neuronal population to facilitate information processing under synaptic plasticity remains poorly understood
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