Spatial navigation signals in rodent visual cortex

•V1 activity is modulated by locomotion, distance travelled, spatial context and head-movements.•Top-down cortical and subcortical inputs convey self-motion signals to V1 neurons.•Key role of SST inhibitory neurons in the integration of visual and self-motion signals.•Potential functions of navigati...

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Veröffentlicht in:	Current opinion in neurobiology 2021-04, Vol.67, p.163-173
Hauptverfasser:	Flossmann, Tom, Rochefort, Nathalie L
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creator	Flossmann, Tom Rochefort, Nathalie L
description	•V1 activity is modulated by locomotion, distance travelled, spatial context and head-movements.•Top-down cortical and subcortical inputs convey self-motion signals to V1 neurons.•Key role of SST inhibitory neurons in the integration of visual and self-motion signals.•Potential functions of navigation-related signals in V1 include gain control, reafference cancellation and predictive coding. During navigation, animals integrate sensory information with body movements to guide actions. The impact of both navigational and movement-related signals on cortical visual information processing remains largely unknown. We review recent studies in awake rodents that have revealed navigation-related signals in the primary visual cortex (V1) including speed, distance travelled and head-orienting movements. Both cortical and subcortical inputs convey self-motion related information to V1 neurons: for example, top-down inputs from secondary motor and retrosplenial cortices convey information about head movements and spatial expectations. Within V1, subtypes of inhibitory neurons are critical for the integration of navigation-related and visual signals. We conclude with potential functional roles of navigation-related signals in V1 including gain control, motor error signals and predictive coding.
doi_str_mv	10.1016/j.conb.2020.11.004
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title	Spatial navigation signals in rodent visual cortex
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