Litcius/Paper detail

Linear-nonlinear cascades capture synaptic dynamics

Julian Rossbroich, Daniel Trotter, John Beninger, Katalin Tóth, Richard Naud

2021PLoS Computational Biology26 citationsDOIOpen Access PDF

Abstract

Short-term synaptic dynamics differ markedly across connections and strongly regulate how action potentials communicate information. To model the range of synaptic dynamics observed in experiments, we have developed a flexible mathematical framework based on a linear-nonlinear operation. This model can capture various experimentally observed features of synaptic dynamics and different types of heteroskedasticity. Despite its conceptual simplicity, we show that it is more adaptable than previous models. Combined with a standard maximum likelihood approach, synaptic dynamics can be accurately and efficiently characterized using naturalistic stimulation patterns. These results make explicit that synaptic processing bears algorithmic similarities with information processing in convolutional neural networks.

Topics & Concepts

Computer scienceNonlinear systemDynamics (music)Biological systemArtificial intelligenceNeurosciencePhysicsBiologyQuantum mechanicsAcousticsNeural dynamics and brain functionAdvanced Memory and Neural ComputingNeural Networks and Applications
Linear-nonlinear cascades capture synaptic dynamics | Litcius