Litcius/Paper detail

Neural Networks for Navigation: From Connections to Computations

Rachel I. Wilson

2023Annual Review of Neuroscience34 citationsDOIOpen Access PDF

Abstract

Many animals can navigate toward a goal they cannot see based on an internal representation of that goal in the brain's spatial maps. These maps are organized around networks with stable fixed-point dynamics (attractors), anchored to landmarks, and reciprocally connected to motor control. This review summarizes recent progress in understanding these networks, focusing on studies in arthropods. One factor driving recent progress is the availability of the Drosophila connectome; however, it is increasingly clear that navigation depends on ongoing synaptic plasticity in these networks. Functional synapses appear to be continually reselected from the set of anatomical potential synapses based on the interaction of Hebbian learning rules, sensory feedback, attractor dynamics, and neuromodulation. This can explain how the brain's maps of space are rapidly updated; it may also explain how the brain can initialize goals as stable fixed points for navigation.

Topics & Concepts

Hebbian theoryConnectomeNeuroscienceComputer scienceAttractorNeuromodulationSensory systemConnectomicsComputational neuroscienceRepresentation (politics)Set (abstract data type)Artificial intelligenceArtificial neural networkPsychologyFunctional connectivityPoliticsProgramming languagePolitical scienceMathematicsMathematical analysisLawStimulationNeurobiology and Insect Physiology ResearchPhotoreceptor and optogenetics researchNeural dynamics and brain function