Closed-loop measurements of iso-response stimuli reveal dynamic nonlinear 
stimulus integration in the retina

Bölinger, Daniel; Gollisch, Tim

doi:10.1016/j.neuron.2011.10.039

Datensatz

DATENSATZ AKTIONENEXPORT

Zur Ablage hinzufügen

Lokale TagsFreigabegeschichteDetailsÜbersicht

Freigegeben

Zeitschriftenartikel

Closed-loop measurements of iso-response stimuli reveal dynamic nonlinear stimulus integration in the retina

MPG-Autoren

/persons/resource/persons49474

Bölinger, Daniel
Max Planck Research Group: Visual Coding / Gollisch, MPI of Neurobiology, Max Planck Society;

/persons/resource/persons38858

Gollisch, Tim
Max Planck Research Group: Visual Coding / Gollisch, MPI of Neurobiology, Max Planck Society;

Externe Ressourcen

Es sind keine externen Ressourcen hinterlegt

Volltexte (beschränkter Zugriff)

Für Ihren IP-Bereich sind aktuell keine Volltexte freigegeben.

Volltexte (frei zugänglich)

Es sind keine frei zugänglichen Volltexte in PuRe verfügbar

Ergänzendes Material (frei zugänglich)

Es sind keine frei zugänglichen Ergänzenden Materialien verfügbar

Zitation

Bölinger, D., & Gollisch, T. (2012). Closed-loop measurements of iso-response stimuli reveal dynamic nonlinear stimulus integration in the retina. Neuron, 73(2), 333-346. doi:10.1016/j.neuron.2011.10.039.

Zitierlink: https://hdl.handle.net/11858/00-001M-0000-000F-50C4-9

Zusammenfassung

Neurons often integrate information from multiple parallel signaling
streams. How a neuron combines these inputs largely determines its
computational role in signal processing. Experimental assessment of
neuronal signal integration, however, is often confounded by
cell-intrinsic nonlinear processes that arise after signal integration
has taken place. To overcome this problem and determine how ganglion
cells in the salamander retina integrate visual contrast over space, we
used automated online analysis of recorded spike trains and closed-loop
control of the visual stimuli to identify different stimulus patterns
that give the same neuronal response. These iso-response stimuli
revealed a threshold-quadratic transformation as a fundamental
nonlinearity within the receptive field center. Moreover, for a subset
of ganglion cells, the method revealed an additional dynamic
nonlinearity that renders these cells particularly sensitive to
spatially homogeneous stimuli. This function is shown to arise from a
local inhibition-mediated dynamic gain control mechanism.