Abstract

A series of experiments is proposed that will use various non-linearities revealed by time-varying visual stimuli to analyze the human visual pathway. When an input signal passes through a non-linear site, new signal components are produced that were not present at its input. By carefully manipulating the visual stimuli that provide the input signal to the non-linearity, it is possible to distinguish the temporal properties of the visual pathways before and after each non-linear site. Three non-linearities will be studied. Each causes a burst of flicker to be perceived differently from a steady light of the same time-averaged intensity and chromaticity. The first, a compressive non-linearity, causes S-cone detected flicker to change in color; the second, also a compressive non-linearity, causes bursts of M- of L-cone detected flicker to change in color and saturation; and the third, an expansive non- linearity, causes bursts of M- or L-cone detected flicker to increase in apparent brightness. The primary aim of the proposed experiments is to use each non-linearity to dissect the early visual pathway. In some experiments, the non-linearity will be used as a recording electrode -- to measure the temporal frequency response of the visual system before the non-linearity; and in others it will be used as a stimulating electrode -- to measure the temporal frequency response of the visual system after the non-linearity. Preliminary evidence suggests that the temporal frequency response after each compressive non-linearity is characteristic of a chromatic pathway, while the response before each compressive non-linearity may more closely reflect the temporal frequency response of the receptors that the results of conventional temporal sensitivity measurements. It is proposed that the expansive non- linearity that affects M- and L-cone flicker is in a separate luminance pathway. The results of the proposed experiments will provide new insights into the postreceptoral organization of the visual system. Each non-linear site can provide a landmark at which psychophysical and physiological results can be compared. In the long-term, these experiments also may have important clinical implications, since it will be possible to use each non-linear site to localize and damage or deterioration that results from degenerative disease.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Research Project (R01)
Project #
5R01EY010206-03
Application #
2163918
Study Section
Visual Sciences B Study Section (VISB)
Project Start
1993-07-01
Project End
1998-06-30
Budget Start
1995-07-01
Budget End
1996-06-30
Support Year
3
Fiscal Year
1995
Total Cost
Indirect Cost

  Institution

Name
University of California San Diego
Department
Miscellaneous
Type
Schools of Arts and Sciences
DUNS #
077758407
City
La Jolla
State
CA
Country
United States
Zip Code
92093

  Publications

Stockman, Andrew; Langendorfer, Micha; Sharpe, Lindsay T (2007) Human short-wavelength-sensitive cone light adaptation. J Vis 7:4
Stockman, Andrew; Montag, Ethan D; Plummer, Daniel J (2006) Paradoxical shifts in human color sensitivity caused by constructive and destructive interference between signals from the same cone class. Vis Neurosci 23:471-8
Stockman, Andrew; Plummer, Daniel J (2005) Spectrally opponent inputs to the human luminance pathway: slow +L and -M cone inputs revealed by low to moderate long-wavelength adaptation. J Physiol 566:77-91
Stockman, Andrew; Plummer, Daniel J (2005) Long-wavelength adaptation reveals slow, spectrally opponent inputs to the human luminance pathway. J Vis 5:702-16
Stockman, Andrew; Plummer, Daniel J; Montag, Ethan D (2005) Spectrally opponent inputs to the human luminance pathway: slow +M and -L cone inputs revealed by intense long-wavelength adaptation. J Physiol 566:61-76
Stockman, A; Sharpe, L T (2000) The spectral sensitivities of the middle- and long-wavelength-sensitive cones derived from measurements in observers of known genotype. Vision Res 40:1711-37
Stockman, A; Sharpe, L T (2000) Tritanopic color matches and the middle- and long-wavelength-sensitive cone spectral sensitivities. Vision Res 40:1739-50
Sharpe, L T; Stockman, A; Jagle, H et al. (1999) L, M and L-M hybrid cone photopigments in man: deriving lambda max from flicker photometric spectral sensitivities. Vision Res 39:3513-25
Stockman, A; Sharpe, L T; Fach, C (1999) The spectral sensitivity of the human short-wavelength sensitive cones derived from thresholds and color matches. Vision Res 39:2901-27
Stockman, A; Plummer, D J (1998) Color from invisible flicker: a failure of the Talbot-Plateau law caused by an early 'hard' saturating nonlinearity used to partition the human short-wave cone pathway. Vision Res 38:3703-28

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