Litcius/Paper detail

End-to-end neural system identification with neural information flow

Katja Seeliger, Luca Ambrogioni, Yağmur Güçlütürk, Leonieke M. van den Bulk, U. Güçlü, Marcel van Gerven

2021PLoS Computational Biology43 citationsDOIOpen Access PDF

Abstract

Neural information flow (NIF) provides a novel approach for system identification in neuroscience. It models the neural computations in multiple brain regions and can be trained end-to-end via stochastic gradient descent from noninvasive data. NIF models represent neural information processing via a network of coupled tensors, each encoding the representation of the sensory input contained in a brain region. The elements of these tensors can be interpreted as cortical columns whose activity encodes the presence of a specific feature in a spatiotemporal location. Each tensor is coupled to the measured data specific to a brain region via low-rank observation models that can be decomposed into the spatial, temporal and feature receptive fields of a localized neuronal population. Both these observation models and the convolutional weights defining the information processing within regions are learned end-to-end by predicting the neural signal during sensory stimulation. We trained a NIF model on the activity of early visual areas using a large-scale fMRI dataset recorded in a single participant. We show that we can recover plausible visual representations and population receptive fields that are consistent with empirical findings.

Topics & Concepts

Receptive fieldArtificial intelligenceComputer sciencePattern recognition (psychology)PopulationConvolutional neural networkSensory systemArtificial neural networkSpatial analysisNeuroscienceBiologyMathematicsStatisticsSociologyDemographyNeural dynamics and brain functionFunctional Brain Connectivity StudiesVisual perception and processing mechanisms