Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-27T11:00:24.917Z Has data issue: false hasContentIssue false

When S-cones contribute to chromatic global motion processing

Published online by Cambridge University Press:  11 April 2007

ALEXA I. RUPPERTSBERG
Affiliation:
Department of Psychology, University of Liverpool, Eleanor Rathbone Building, Liverpool, United Kingdom
SOPHIE M. WUERGER
Affiliation:
Department of Psychology, University of Liverpool, Eleanor Rathbone Building, Liverpool, United Kingdom
MARCO BERTAMINI
Affiliation:
Department of Psychology, University of Liverpool, Eleanor Rathbone Building, Liverpool, United Kingdom

Abstract

There is common consensus now that color-defined motion can be perceived by the human visual system. For global motion integration tasks based on isoluminant random dot kinematograms conflicting evidence exists, whether observers can (Ruppertsberg et al., 2003) or cannot (Bilodeau & Faubert, 1999) extract a common motion direction for stimuli modulated along the isoluminant red-green axis. Here we report conditions, in which S-cones contribute to chromatic global motion processing. When the display included extra-foveal regions, the individual elements were large (∼0.3°) and the displacement was large (∼1°), stimuli modulated along the yellowish-violet axis proved to be effective in a global motion task. The color contrast thresholds for detection for both color axes were well below the contrasts required for global motion integration, and therefore the discrimination-to-detection ratio was >1. We conclude that there is significant S-cone input to chromatic global motion processing and the extraction of global motion is not mediated by the same mechanism as simple detection. Whether the koniocellular or the magnocellular pathway is involved in transmitting S-cone signals is a topic of current debate (Chatterjee & Callaway, 2002).

Type
Research Article
Copyright
© 2007 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Barberini, C.L., Cohen, M.R., Wandell, B. & Newsome, W.T. (2005). Cone signal interactions in direction-selective neurons in the middle temporal visual area (MT). Journal of Vision 5, 603621.Google Scholar
Bilodeau, L. & Faubert, J. (1999). Global motion cues and the chromatic motion system. Journal of the Optical Society of America A 16, 15.Google Scholar
Bilodeau, L. & Faubert, J. (1997). Isoluminance and chromatic motion perception throughout the visual field. Vision Research 37, 20732081.Google Scholar
Braddick, O.J. (1980). Low-level and high-level processes in apparent motion. Philosophical Transactions of the Royal Society London B 290, 137151.Google Scholar
Brainard, D. (1996). Cone contrast and opponent modulation color spaces. In Human Color Vision, eds. Kaiser, P.K. & Boynton, R.M., pp. 563579. Washington, DC: Optical Society of America.
Britten, K.H. (1999). Motion perception: How are moving images segmented? Current Biology 9, R728R730.Google Scholar
Bumsted, K. & Hendrickson, A. (1999). Distribution and development of short-wavelength cones differ between Macaca monkey and human fovea. Journal of Comparative Neurology 403, 502516.Google Scholar
Calkins, D.J. (2001). Seeing with S cones. Progress in Retinal and Eye Research 3, 255287.Google Scholar
Calkins, D.J., Tsukamoto, Y. & Sterling, P. (1998). Microcircuitry and mosaic of a blue/yellow ganglion cell in the primate retina. Journal of Neuroscience 18, 33733385.Google Scholar
Cavanagh, P. & Anstis, S. (1991). The contribution of color to motion in normal and color-deficient observers. Vision Research 31, 21092148.Google Scholar
Cavanagh, P., Boeglin, J. & Favreau, O.E. (1985). Perception of motion in equiluminous kinematograms. Perception (OZD) 14, 151162.Google Scholar
Chatterjee, S. & Callaway, E.M. (2002). S cone contributions to the magnocellular visual pathway in macaque monkey. Neuron 35, 11351146.Google Scholar
Chichilnisky, E.J. & Baylor, D.A. (1999). Receptive-field microstructure of blue-yellow ganglion cells in primate retina. Nature Neuroscience 2, 889893.Google Scholar
Croner, L.J. & Albright, T.D. (1997). Image segmentation enhances discrimination of motion in visual noise. Vision Research 37, 14151427.Google Scholar
Cropper, S.J. & Derrington, A.M. (1994). Motion of chromatic stimuli: First-order or second-order? Vision Research 34, 4958.Google Scholar
Cropper, S.J. & Derrington, A.M. (1996). Rapid color-specific detection of motion in human vision. Nature 379, 7274.Google Scholar
Cropper, S.J., Mullen, K.T. & Badcock, D.R. (1996). Motion coherence across cardinal axes. Vision Research 36, 24752488.Google Scholar
Cropper, S.J. & Wuerger, S.M. (2005). The perception of motion in chromatic stimuli. Behavioral and Cognitive Neuroscience Reviews 4, 192217.Google Scholar
Curcio, C.A., Allen, K.A., Sloan, K.R., Lerea, C.L., Hurley, J.B., Klock, I.B. & Milam, A.H. (1991). Distribution and morphology of human cone photoreceptors stained with anti-blue opsin. Journal of Comparative Neurology 312, 610624.Google Scholar
Dacey, D.M. & Lee, B.B. (1994). The ‘blue-on’ opponent pathway in primate retina originates from a distinct bistratified ganglion cell type. Nature 367, 731735.Google Scholar
Derrington, A.M. & Badcock, D.R. (1985). The low-level motion system has both chromatic and luminance inputs. Vision Research 25, 18691878.Google Scholar
Derrington, A.M. & Henning, G.B. (1993). Detecting and discriminating the direction of motion of luminance and color gratings. Vision Research 33, 799811.Google Scholar
Derrington, A.M., Krauskopf, J. & Lennie, P. (1984). Chromatic mechanisms in lateral geniculate nucleus of macaque. Journal of Physiology 357, 241265.Google Scholar
De Valois, R.L., Cottaris, N.P., Elfar, S.D., Mahon, L.E. & Wilson, J.A. (2000). Some transformations of color information from lateral geniculate nucleus to striate cortex. Proceedings of the National Academy of Sciences of the United States of America 97, 49975002.Google Scholar
Dougherty, R.F., Press, W.A. & Wandell, B.A. (1999). Perceived speed of colored stimuli. Neuron 24, 893899.Google Scholar
Edwards, M. & Badcock, D.R. (1996). Global-motion perception: Interaction of chromatic and luminance signals. Vision Research 36, 24232431.Google Scholar
Hendry, S.H. & Reid, R.C. (2000). The koniocellular pathway in primate vision. Annual Review of Neuroscience 23, 127153.Google Scholar
Kooi, F.L. & De Valois, K.K. (1992). The role of color in the motion system. Vision Research 32, 657668.Google Scholar
Krauskopf, J. & Farell, B. (1990). Influence of color on the perception of coherent motion. Nature 348(22 November), 328331.Google Scholar
Levinson, E.S.R. (1975). The independence of channels in human vision selective for direction of motion. Journal of Physiology (London) 250, 347366.Google Scholar
Li, H.-C.O. & Kingdom, F.A.A. (2001). Segregation by color/luminance does not necessarily facilitate motion discrimination in the presence of motion distractors. Perception & Psychophysics 63, 660675.Google Scholar
Lindsey, D.T. & Teller, D.Y. (1990). Motion at isoluminance: discrimination/detection ratios for moving isoluminant gratings. Vision Research 30, 17511761.Google Scholar
Metha, A.B. & Mullen, K.T. (1998). Failure of direction discrimination at detection threshold for both fast and slow chromatic motion. Journal of the Optical Society of America A 15, 29452950.Google Scholar
Metha, A.B., Vingrys, A.J. & Badcock, D.R. (1994). Detection and discrimination of moving stimuli: the effects of color, luminance and eccentricity. Journal of the Optical Society of America A 11, 16971709.Google Scholar
Møller, P. & Hurlbert, A.C. (1997a). Interactions between color and motion in image segmentation. Current Biology 7, 105111.Google Scholar
Møller, P. & Hurlbert, A.C. (1997b). Motion edges and regions guide image segmentation by color. Proceedings of the Royal Society London Series B 264, 15711577.Google Scholar
Morand, S., Thut, G., Grave de Peralta, R., Clarke, S., Khateb, A., Landis, T. & Michel, C.M. (2000). Electrophysiological evidence for fast visual processing through the human koniocellular pathway when stimuli move. Cerebral Cortex 10, 817825.Google Scholar
Mullen, K.T. (1985). The contrast sensitivity of human color vision to red-green and yellow-blue chromatic gratings. Journal of Physiology 359, 381400.Google Scholar
Mullen, K.T. (1991). Color vision as a post-receptoral specialization of the central visual field. Vision Research 31, 119130.Google Scholar
Mullen, K.T. & Baker, C.L. (1985). A motion after-effect from an isoluminant stimulus. Vision Research 25, 685688.Google Scholar
Mullen, K.T. & Boulton, J.C. (1992). Interactions between color and luminance contrast in the perception of motion. Ophthalmic and Physiological Optics 12, 201205.Google Scholar
Mullen, K.T. & Kingdom, F.A.A. (2002). Differential distributions of red-green and blue-yellow cone opponency across the visual field. Visual Neuroscience 19, 109118.Google Scholar
Newsome, W.T. & Pare, E.B. (1988). A selective impairment of motion perception following lesions of the middle temporal visual area (MT). Journal of Neuroscience 8, 22012211.Google Scholar
Palmer, J., Mobley, L.A. & Teller, D.Y. (1993). Motion at isoluminance: discrimination/detection ratios and the summation of luminance and chromatic signals. Journal of the Optical Society of America, A 10, 13531362.Google Scholar
Ramachandran, V.S. (1987). Interaction between color and motion in human vision. Nature 328, 645647.Google Scholar
Ramachandran, V.S. & Gregory, R.L. (1978). Does color provide an input to human motion perception? Nature 275, 5556.Google Scholar
Regan, B.C., Reffin, J.P. & Mollon, J.D. (1994). Luminance noise and the rapid determination of discrimination ellipses in color deficiency. Vision Research 34, 12791299.Google Scholar
Ruppertsberg, A.I., Wuerger, S.M. & Bertamini, M. (2003). The chromatic selectivity of global motion processing. Visual Neuroscience 20, 421428.Google Scholar
Seidemann, E., Poirson, A.B., Wandell, B.A. & Newsome, W.T. (1999). Color signals in area MT of the macaque monkey. Neuron 24, 911917.Google Scholar
Sincich, L.C. & Horton, J.C. (2005). The circuitry of V1 and V2: Integration of color, form and motion. Annual Review of Neuroscience 28, 303326.Google Scholar
Sincich, L.C., Park, K.F., Wohlgemuth, M.J. & Horton, J.C. (2004). Bypassing V1: a direct geniculate input to area MT. Nature Neuroscience 7, 1123.Google Scholar
Snowden, R.J. & Edmunds, R. (1999). Color and polarity contributions to global motion perception. Vision Research 39, 18131822.Google Scholar
Stromeyer III, C.F., Chaparro, A., Rodriguez, C., Chen, D., Hu, E. & Kronauer, R.E. (1998). Short-wave cone signal in the red-green detection mechanism. Vision Research 38, 813826.Google Scholar
Stromeyer III, C.F., Kronauer, R.E., Ryu, A., Chaparro, A. & Eskew Jr., R.T. (1995). Contribution of human long-wave and middle-wave cones to motion. Journal of Physiology 485, 221243.Google Scholar
Walsh, J.W.T. (1958). Photometry, 3rd ed. London: Constable & Co. Ltd.
Wandell, B. (1993). Foundations of Vision. Sunderland, MA: Sinauer Associates, Inc.
Wandell, B.A., Poirson, A.B., Newsome, W.T., Baseler, H.A., Boynton, G.M., Huk, A., Gandhi, S. & Sharpe, L.T. (1999). Color signals in human motion-selective cortex. Neuron 24, 900909.Google Scholar
Watson, A.B. & Pelli, D. (1983). QUEST: A Bayesian adaptive psychometric method. Perception & Psychophysics 33, 113120.Google Scholar
Watson, A.B., Thompson, P.G., Murphy, B.J. & Nachmias, J. (1980). Summation and discrimination of gratings moving in opposite directions. Vision Research 20, 341347.Google Scholar
Wuerger, S.M. (1996). Color appearance changes resulting from isoluminant chromatic adaptation. Vision Research 36, 31073118.Google Scholar
Wuerger, S.M. & Landy, M.S. (1993). Structure from motion for chromatic and luminance stimuli. Journal of the Optical Society of America A 10, 13631372.Google Scholar
Wuerger, S.M., Atkinson, P. & Cropper, S.J. (2005). The cone inputs to the unique-hue mechanisms. Vision Research 45, 32103223.Google Scholar