How
#fish #navigate: boundary vector cells in the central
#telencephalon of
#goldfish enable a unique encoding of position, documented here by Lear Cohen, @ronen_segev &co for the first time in
#teleosts, the largest group of vertebrates
#PLOSBiology https://plos.io/3V7aLBH
Boundary vector cells in the goldfish central telencephalon encode spatial information
This study identifies a new building block in the navigation system of fish: boundary vector cells in the central telencephalon of goldfish enable a unique encoding of position, documented here for the first time in the largest group of vertebrates.
How
#fish #navigate: boundary vector cells in the central
#telencephalon of
#goldfish enable a unique encoding of position, documented here by Lear Cohen, @ronen_segev &co for the first time in
#teleosts, the largest group of vertebrates
#PLOSBiology https://plos.io/3V7aLBHBoundary vector cells in the goldfish central telencephalon encode spatial information
This study identifies a new building block in the navigation system of fish: boundary vector cells in the central telencephalon of goldfish enable a unique encoding of position, documented here for the first time in the largest group of vertebrates.
How
#fish #navigate: boundary vector cells in the central
#telencephalon of
#goldfish enable a unique encoding of position, documented here by Lear Cohen, @ronen_segev &co for the first time in
#teleosts, the largest group of vertebrates
#PLOSBiology https://plos.io/3V7aLBHBoundary vector cells in the goldfish central telencephalon encode spatial information
This study identifies a new building block in the navigation system of fish: boundary vector cells in the central telencephalon of goldfish enable a unique encoding of position, documented here for the first time in the largest group of vertebrates.
PLOS Biology
