Sunlight is attenuated rapidly in the ocean, resulting in little visually useful light reaching deeper than w1000 m in even the clearest water. To maximize sensitivity to the relatively brighter downwelling sunlight, to view the silhouette of animals above them, and to increase the binocular overlap of their eyes, many mesopelagic animals have developed upward-pointing tubular eyes. However, these sacrifice the ability to detect bioluminescent and reflective objects in other directions. Thus, some mesopelagic fish with tubular eyes extend their visual fields laterally and/or ventrally by lensless ocular diverticula, which are thought to provide unfocused images, allowing only simple detection of objects, with little spatial resolution. Here, we show that a medial mirror within the ventrally facing ocular diverticulum of the spookfish, Dolichopteryx longipes, consisting of a multilayer stack derived from a retinal tapetum, is used to reflect light onto a lateral retina.
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Contributors
Publisher
Elsevier B.V.
Date Issued
2009-01-27
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Type
Genre
Extent
9 p.
Subject (Topical)
Identifier
1779078
Additional Information
Sunlight is attenuated rapidly in the ocean, resulting in little visually useful light reaching deeper than w1000 m in even the clearest water. To maximize sensitivity to the relatively brighter downwelling sunlight, to view the silhouette of animals above them, and to increase the binocular overlap of their eyes, many mesopelagic animals have developed upward-pointing tubular eyes. However, these sacrifice the ability to detect bioluminescent and reflective objects in other directions. Thus, some mesopelagic fish with tubular eyes extend their visual fields laterally and/or ventrally by lensless ocular diverticula, which are thought to provide unfocused images, allowing only simple detection of objects, with little spatial resolution. Here, we show that a medial mirror within the ventrally facing ocular diverticulum of the spookfish, Dolichopteryx longipes, consisting of a multilayer stack derived from a retinal tapetum, is used to reflect light onto a lateral retina.
This manuscript is a version of an article published by Elsevier www.cell.com/current‐biology/home and may be cited as Wagner, Hans-Joachim, Ron H. Douglas, Tamara M. Frank, Nicholas W. Roberts, and Julian C. Partridge. A Novel Vertebrate Eye Using Both Refractive and Reflective Optics (2009). Current Biology, 19(2) 108‐114, doi:10.1016/j.cub.2008.11.061 and is available at www.sciencedirect.com
Florida Atlantic University. Harbor Branch Oceanographic Institute contribution #1774.
Date Backup
2009-01-27
Date Text
2009-01-27
DOI
10.1016/j.cub.2008.11.061
Date Issued (EDTF)
2009-01-27
Extension
FAU
FAU
admin_unit="FAU01", ingest_id="ing5502", creator="creator:SPATEL", creation_date="2010-03-31 10:10:32", modified_by="super:FAUDIG", modification_date="2014-02-10 08:29:43"
IID
FADT1779078
Issuance
single unit
Organizations
Attributed name: Harbor Branch Oceanographic Institute
Person Preferred Name
Wagner, Hans-Joachim
creator
Physical Description
9 p.
Title Plain
A novel vertebrate eye using both refractive and reflective optics
Origin Information
Elsevier B.V.
2009-01-27
single unit
Title
A novel vertebrate eye using both refractive and reflective optics
Other Title Info
A novel vertebrate eye using both refractive and reflective optics