Magnocellular channel subserves the human contrast-sensitivity function

Sotiris Plainis; Ian J. Murray

doi:10.1068/p5451

Magnocellular channel subserves the human contrast-sensitivity function

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

There is evidence that the human contrast-sensitivity function (CSF) is mediated by the spatiotemporal characteristics of magno and parvo neurons early in the visual pathway. In this study we use a measure of contrast gain derived from simple reaction times, to investigate the neural substrates of suprathreshold performance. The results reveal the activity of two mechanisms having distinctly different contrast-gain characteristics. Comparing these to neurophysiological data, we find that the magnocellular system dominates close-to-threshold detection and probably forms the basis of the achromatic CSF, whereas the parvocellular system dominates detection at higher contrasts, when the magnocellular system saturates. © 2005 a Pion publication.

Original language	English
Title of host publication	Perception\|Perception
Pages	933-940
Number of pages	7
Volume	34
DOIs	https://doi.org/10.1068/p5451
Publication status	Published - 2005

Keywords

adult
comparative study
conference paper
contrast sensitivity
human
perceptive threshold
physiology
psychophysics
reaction time
retina ganglion cell
visual system
Adult
Contrast Sensitivity
Humans
Psychophysics
Reaction Time
Retinal Ganglion Cells
Sensory Thresholds
Visual Pathways

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10.1068/p5451

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@inproceedings{15e86f8d2022424f912c915d84594277,

title = "Magnocellular channel subserves the human contrast-sensitivity function",

abstract = "There is evidence that the human contrast-sensitivity function (CSF) is mediated by the spatiotemporal characteristics of magno and parvo neurons early in the visual pathway. In this study we use a measure of contrast gain derived from simple reaction times, to investigate the neural substrates of suprathreshold performance. The results reveal the activity of two mechanisms having distinctly different contrast-gain characteristics. Comparing these to neurophysiological data, we find that the magnocellular system dominates close-to-threshold detection and probably forms the basis of the achromatic CSF, whereas the parvocellular system dominates detection at higher contrasts, when the magnocellular system saturates. {\textcopyright} 2005 a Pion publication.",

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author = "Sotiris Plainis and Murray, {Ian J.}",

note = "cited By (since 1996) 9",

year = "2005",

doi = "10.1068/p5451",

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volume = "34",

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booktitle = "Perception|Perception",

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T1 - Magnocellular channel subserves the human contrast-sensitivity function

AU - Plainis, Sotiris

AU - Murray, Ian J.

N1 - cited By (since 1996) 9

PY - 2005

Y1 - 2005

N2 - There is evidence that the human contrast-sensitivity function (CSF) is mediated by the spatiotemporal characteristics of magno and parvo neurons early in the visual pathway. In this study we use a measure of contrast gain derived from simple reaction times, to investigate the neural substrates of suprathreshold performance. The results reveal the activity of two mechanisms having distinctly different contrast-gain characteristics. Comparing these to neurophysiological data, we find that the magnocellular system dominates close-to-threshold detection and probably forms the basis of the achromatic CSF, whereas the parvocellular system dominates detection at higher contrasts, when the magnocellular system saturates. © 2005 a Pion publication.

AB - There is evidence that the human contrast-sensitivity function (CSF) is mediated by the spatiotemporal characteristics of magno and parvo neurons early in the visual pathway. In this study we use a measure of contrast gain derived from simple reaction times, to investigate the neural substrates of suprathreshold performance. The results reveal the activity of two mechanisms having distinctly different contrast-gain characteristics. Comparing these to neurophysiological data, we find that the magnocellular system dominates close-to-threshold detection and probably forms the basis of the achromatic CSF, whereas the parvocellular system dominates detection at higher contrasts, when the magnocellular system saturates. © 2005 a Pion publication.

KW - adult

KW - comparative study

KW - conference paper

KW - contrast sensitivity

KW - human

KW - perceptive threshold

KW - physiology

KW - psychophysics

KW - reaction time

KW - retina ganglion cell

KW - visual system

KW - Adult

KW - Contrast Sensitivity

KW - Humans

KW - Psychophysics

KW - Reaction Time

KW - Retinal Ganglion Cells

KW - Sensory Thresholds

KW - Visual Pathways

U2 - 10.1068/p5451

DO - 10.1068/p5451

M3 - Conference contribution

VL - 34

SP - 933

EP - 940

BT - Perception|Perception

ER -

Magnocellular channel subserves the human contrast-sensitivity function

Abstract

Keywords

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