Abstract
One of the paramount challenges in neuroscience is to understand the dynamics of individual neurons and how they give rise to network dynamics when interconnected. Historically, researchers have resorted to graph theory, statistics, and statistical mechanics to describe the spatiotemporal structure of such network dynamics. Our novel approach employs tools from algebraic topology to characterize the global properties of network structure and dynamics.We propose a method based on persistent homology to automatically classify network dynamics using topological features of spaces built from various spike train distances. We investigate the efficacy of our method by simulating activity in three small artificial neural networks with different sets of parameters, giving rise to dynamics that can be classified into four regimes. We then compute three measures of spike train similarity and use persistent homology to extract topological features that are fundamentally different from those used in traditional methods. Our results show that a machine learning classifier trained on these features can accurately predict the regime of the network it was trained on and also generalize to other networks that were not presented during training. Moreover, we demonstrate that using features extracted from multiple spike train distances systematically improves the performance of our method.
Highlights
A major objective in neuroscience is to understand how populations of interconnected neurons perform computations and process information
As we demonstrate in this paper, the appropriate notion of spike train distance to use depends on context, and it can be beneficial to combine several of them
The Brunel network consists of two homogeneous subpopulations of excitatory and inhibitory neurons modeled by a currentbased leaky integrate-and-fire (LIF) model
Summary
A major objective in neuroscience is to understand how populations of interconnected neurons perform computations and process information. Its dynamics are affected by how the neurons are physically connected and by the activity history of the neurons. Understanding this spatiotemporal organization of network dynamics is essential for developing a comprehensive view of brain information-processing mechanisms, the functional connectome. Two neurons can be considered “functionally connected” if their dynamics are similar or if one appears highly likely to spike causally after the other. The same notion of functional connectivity can be considered on a macroscopic level, where one can study the causal relationships between brain regions. Techniques like the one we present in this paper have broad applicability
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