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Mean-Field Approximations With Adaptive Coupling for Networks With Spike-Timing-Dependent Plasticity

Benoit Duchet, Christian Bick, Áine Byrne

2023Neural Computation18 citationsDOIOpen Access PDF

Abstract

Understanding the effect of spike-timing-dependent plasticity (STDP) is key to elucidating how neural networks change over long timescales and to design interventions aimed at modulating such networks in neurological disorders. However, progress is restricted by the significant computational cost associated with simulating neural network models with STDP and by the lack of low-dimensional description that could provide analytical insights. Phase-difference-dependent plasticity (PDDP) rules approximate STDP in phase oscillator networks, which prescribe synaptic changes based on phase differences of neuron pairs rather than differences in spike timing. Here we construct mean-field approximations for phase oscillator networks with STDP to describe part of the phase space for this very high-dimensional system. We first show that single-harmonic PDDP rules can approximate a simple form of symmetric STDP, while multiharmonic rules are required to accurately approximate causal STDP. We then derive exact expressions for the evolution of the average PDDP coupling weight in terms of network synchrony. For adaptive networks of Kuramoto oscillators that form clusters, we formulate a family of low-dimensional descriptions based on the mean-field dynamics of each cluster and average coupling weights between and within clusters. Finally, we show that such a two-cluster mean-field model can be fitted to synthetic data to provide a low-dimensional approximation of a full adaptive network with symmetric STDP. Our framework represents a step toward a low-dimensional description of adaptive networks with STDP, and could for example inform the development of new therapies aimed at maximizing the long-lasting effects of brain stimulation.

Topics & Concepts

Spike-timing-dependent plasticitySpike (software development)Coupling (piping)Computer scienceArtificial neural networkMean field theoryBiological neural networkMathematicsTopology (electrical circuits)Synaptic plasticityArtificial intelligencePhysicsMachine learningChemistryBiochemistryCombinatoricsQuantum mechanicsSoftware engineeringEngineeringMechanical engineeringReceptorNeural dynamics and brain functionAdvanced Memory and Neural ComputingNonlinear Dynamics and Pattern Formation
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