Nature Neuroscience homepage
Advanced search
 Journal home > Archive > Table of Contents > Article > Abstract
Journal home
Advance online publication
Current issue
Archive
Press releases
Supplements
Focuses
Guide to authors
Online submissionOnline submission
Permissions
For referees
Free online issue
Contact the journal
Subscribe
Advertising
work@npg
naturereprints
About this site
For librarians
 
NPG Resources
Nature
Nature Reviews Neuroscience
Nature Cell Biology
Nature Medicine
Neuroscience Gateway
UCSD-Nature Signaling Gateway
NPG Subject areas
Biotechnology
Cancer
Chemistry
Clinical Medicine
Dentistry
Development
Drug Discovery
Earth Sciences
Evolution & Ecology
Genetics
Immunology
Materials Science
Medical Research
Microbiology
Molecular Cell Biology
Neuroscience
Pharmacology
Physics
Browse all publications
Article
Nature Neuroscience  5, 341 - 347 (2002)
Published online: 4 March 2002; | doi:10.1038/nn821

Retinal ganglion cell synchronization by fixational eye movements improves feature estimation

Martin Greschner1, Markus Bongard1, Pal Rujan2 & Josef Ammermüller1

1  Department of Biology, Neurobiology Group, University of Oldenburg, 26111-Oldenburg, Germany

2  Department of Physics, Complex Systems Group, University of Oldenburg, 26111-Oldenburg, Germany

Correspondence should be addressed to Josef Ammermüller josef.ammermueller@uni-oldenburg.de
Image movements relative to the retina are essential for the visual perception of stationary objects during fixation. Here we have measured fixational eye and head movements of the turtle, and determined their effects on the activity of retinal ganglion cells by simulating the movements on the isolated retina. We show that ganglion cells respond mainly to components of periodic eye movement that have amplitudes of roughly the diameter of a photoreceptor. Drift or small head movements have little effect. Driven cells that are located along contrast borders are synchronized, which reliably signals a preceding movement. In an artificial neural network, the estimation of spatial frequencies for various square wave gratings improves when timelocked to this synchronization. This could potentially improve stimulus feature estimation by the brain.

MORE ARTICLES LIKE THIS
These links to content published by NPG are automatically generated

REVIEWS
The role of fixational eye movements in visual perception
Nature Reviews Neuroscience Review (01 Mar 2004)
 See all 6 matches for Reviews

RESEARCH
Segregation of object and background motion in the retina
Nature Article (22 May 2003)
Paired-spike interactions and synaptic efficacy of retinal inputs to the thalamus
Nature Letters to Editor (24 Sep 1998)
Microsaccadic eye movements and firing of single cells in the striate cortex of macaque monkeys
Nature Neuroscience Article (01 Mar 2000)
Parallel colour-opponent pathways to primary visual cortex
Nature Letters to Editor (11 Dec 2003)
 See all 27 matches for Research

 Top
Abstract
Previous | Next
Table of contents
Full textFull text
Download PDFDownload PDF
Send to a friendSend to a friend
Save this linkSave this link

Open Innovation Challenges

Figures & Tables
Supplementary info
Export citation
natureproducts

Search buyers guide:

 
ADVERTISEMENT
 
Nature Neuroscience
ISSN: 1097-6256
EISSN: 1546-1726		 Journal home | Advance online publication | Current issue | Archive | Press releases | Supplements | Focuses | For authors | Online submission | Permissions | For referees | Free online issue | About the journal | Contact the journal | Subscribe | Advertising | work@npg | naturereprints | About this site | For librarians
Nature Publishing Group, publisher of Nature, and other science journals and reference works©2002 Nature Publishing Group | Privacy policy