Characterization of Retinal Functionality at Different Eccentricities in a Diurnal Rodent.

María-José Escobar,Joaquin Araya,Mónica Otero,Cristóbal Ibaceta,Rubén Herzog,Adrián G Palacios,César Reyes

doi:10.3389/fncel.2018.00444

María-José Escobar, Joaquin Araya + Show 5 more

Open Access

https://doi.org/10.3389/fncel.2018.00444

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Abstract

Although the properties of the neurons of the visual system that process central and peripheral regions of the visual field have been widely researched in the visual cortex and the LGN, they have scarcely been documented for the retina. The retina is the first step in integrating optical signals, and despite considerable efforts to functionally characterize the different types of retinal ganglion cells (RGCs), a clear account of the particular functionality of cells with central vs. peripheral fields is still wanting. Here, we use electrophysiological recordings, gathered from retinas of the diurnal rodent Octodon degus, to show that RGCs with peripheral receptive fields (RF) are larger, faster, and have shorter transient responses. This translates into higher sensitivity at high temporal frequencies and a full frequency bandwidth when compared to RGCs with more central RF. We also observed that imbalances between ON and OFF cell populations are preserved with eccentricity. Finally, the high diversity of functional types of RGCs highlights the complexity of the computational strategies implemented in the early stages of visual processing, which could inspire the development of bio-inspired artificial systems.

Highlights

The visual system integrates optical signals to create specific features of the images such as movement, contrast, and color (Van Essen et al, 1992; Masland, 2012)
We showed the general behavior of the entire population of recorded retinal ganglion cells (RGCs), which may contain a variety of different functional types
To characterize different cell populations of RGCs present in the degus retina, we collected a series of data coming from in-vitro extracellular multi-electrode recording array (MEA) recordings stimulated with white-noise checkerboards

Summary

Introduction

The visual system integrates optical signals to create specific features of the images such as movement, contrast, and color (Van Essen et al, 1992; Masland, 2012). Studies have described that any point of a visual scene is anatomically covered through a variety of different RGC types (for example, parasol and midget RGCs in primates or alpha cell RGCs in rodents) that form potential visual channels (e.g., ON / OFF) acting as functional filters for the physical world (Field and Chichilnisky, 2007). Polyak (1957) raised what is still an unresolved problem how the diversity of RGCs contributes to forming a variety of visual channels as a function of retinal eccentricity, which is vital for many species (Boycott and Wässle, 1974; Gollisch and Meister, 2010). OFF-bipolar cells (BCs) hyperpolarized as light intensity increased through AMPA or Kainate receptors (Devries, 2000). Axons of BCs project into the inner plexiform sublayer and pass their ON / OFF signature to different types of RGCs

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