Understanding the retina : a review of computational models of the retina from the single cell to the network level

Tianruo Guo; David Tsai; Siwei Bai; John W. Morley; Gregg J. Suaning; Nigel H. Lovell; Socrates Dokos

doi:10.1615/CritRevBiomedEng.2014011732

Understanding the retina : a review of computational models of the retina from the single cell to the network level

Tianruo Guo
, David Tsai
, Siwei Bai
, John W. Morley
, Gregg J. Suaning
, Nigel H. Lovell
, Socrates Dokos

School of Medicine

Research output: Contribution to journal › Article › peer-review

29 Citations (Scopus)

Abstract

The vertebrate retina is a clearly organized signal-processing system. It contains more than 60 different types of neurons, arranged in three distinct neural layers. Each cell type is believed to serve unique role(s) in encoding visual information. While we now have a relatively good understanding of the constituent cell types in the retina and some general ideas of their connectivity, with few exceptions, how the retinal circuitry performs computation remains poorly understood. Computational modeling has been commonly used to study the retina from the single cell to the network level. In this article, we begin by reviewing retinal modeling strategies and existing models. We then discuss in detail the significance and limitations of these models, and finally, we provide suggestions for the future development of retinal neural modeling.

Original language	English
Pages (from-to)	419-436
Number of pages	18
Journal	Critical Reviews in Biomedical Engineering
Volume	42
Issue number	5
DOIs	https://doi.org/10.1615/CritRevBiomedEng.2014011732
Publication status	Published - 2014

Keywords

cell types
neuron
retina

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10.1615/CritRevBiomedEng.2014011732

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title = "Understanding the retina : a review of computational models of the retina from the single cell to the network level",

abstract = "The vertebrate retina is a clearly organized signal-processing system. It contains more than 60 different types of neurons, arranged in three distinct neural layers. Each cell type is believed to serve unique role(s) in encoding visual information. While we now have a relatively good understanding of the constituent cell types in the retina and some general ideas of their connectivity, with few exceptions, how the retinal circuitry performs computation remains poorly understood. Computational modeling has been commonly used to study the retina from the single cell to the network level. In this article, we begin by reviewing retinal modeling strategies and existing models. We then discuss in detail the significance and limitations of these models, and finally, we provide suggestions for the future development of retinal neural modeling.",

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AU - Morley, John W.

AU - Suaning, Gregg J.

AU - Lovell, Nigel H.

AU - Dokos, Socrates

PY - 2014

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JO - Critical Reviews in Biomedical Engineering

JF - Critical Reviews in Biomedical Engineering

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ER -

Understanding the retina : a review of computational models of the retina from the single cell to the network level

Abstract

Keywords

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