Eye movements in response to dichoptic motion: Evidence for a parallel-hierarchical structure of visual motion processing in primates

Journal of Neurophysiology

Volumn 99, Issue 5, 2008, Pages 2329-2346

  Hayashi, Ryusuke ^a   Miura, Kenichiro ^a   Tabata, Hiromitsu ^a   Kawano, Kenji ^a  

^a KYOTO UNIVERSITY   (Japan)

Author keywords

[No Author keywords available]

Indexed keywords

ANIMAL EXPERIMENT; ARTICLE; ASSOCIATION; BINOCULAR VISION; CONTROLLED STUDY; EVOKED MUSCLE RESPONSE; EVOKED VISUAL RESPONSE; EYE MOVEMENT; HUMAN; HUMAN EXPERIMENT; LUMINANCE; MACACA; MALE; MONOCULAR VISION; MOVEMENT PERCEPTION; NONHUMAN; NORMAL HUMAN; OCULAR FOLLOWING RESPONSE; PRIORITY JOURNAL; STIMULUS RESPONSE; VELOCITY; VISUAL CORTEX; VISUAL STIMULATION; ALGORITHM; ANIMAL; CONTRAST SENSITIVITY; DEPTH PERCEPTION; PHOTOSTIMULATION; PHYSIOLOGY; STATISTICAL ANALYSIS; VISION;

ALGORITHMS; ANIMALS; CONTRAST SENSITIVITY; DATA INTERPRETATION, STATISTICAL; EYE MOVEMENTS; HUMANS; MACACA MULATTA; MOTION PERCEPTION; PHOTIC STIMULATION; VISION DISPARITY; VISION, MONOCULAR; VISUAL PERCEPTION;

EID: 47549095887     PISSN: 00223077     EISSN: 15221598     Source Type: Journal    
DOI: 10.1152/jn.01316.2007     Document Type: Article

References (73)

1. Albright TD. Form-cue invariant motion processing in primate visual cortex. Science 255: 1141-1143, 1992.
2. Anzai A, Ohzawa I, Freeman RD. Joint-encoding of motion and depth by visual cortical neurons: neural basis of the Pulfrich effect. Nat Neurosci 4: 513-518, 2001.
3. Baker CL Jr. Central neural mechanisms for detecting second-order motion. Curr Opin Neurobiol 9: 461-466, 1999.
4. Barthelemy FV, Masson GS. Spatial integration of motion for human and monkey ocular following: effect of spatial frequency and eccentricity. Soc Neurosci Abstr 735.735/L733, 2006.
5. Benson PJ, Guo K. Stages in motion processing revealed by the ocular following response. Neuroreport 10: 3803-3807, 1999.
6. Braddick O. A short-range process in apparent motion. Vision Res 14: 519-527, 1974.
7. Brainard DH. The Psychophysics Toolbox. Spat Vis 10: 433-436, 1997.
8. Busettini C, Masson GS, Miles FA. A role for stereoscopic depth cues in the rapid visual stabilization of the eyes. Nature 380: 342-345, 1996.
9. Busettini C, Miles FA, Schwarz U. Ocular responses to translation and their dependence on viewing distance. II. Motion of the scene. J Neurophysiol 66: 865-878, 1991.
10. Butzer F, Ilg UJ, Zanker JM. Smooth-pursuit eye movements elicited by first-order and second-order motion. Exp Brain Res 115: 61-70, 1997.
11. Carney T. Evidence for an early motion system which integrates information from the two eyes. Vision Res 37: 2361-2368, 1997.
12. Carney T, Paradiso MA, Freeman RD. A physiological correlate of the Pulfrich effect in cortical neurons of the cat. Vision Res 29: 155-165, 1989.
13. Carney T, Shadlen MN. Dichoptic activation of the early motion system. Vision Res 33: 1977-1995, 1993.
14. Cavanagh P, Mather G. Motion: the long and short of it. Spat Vis 4: 103-129, 1989.
15. Chaudhuri A, Albright TD. Neuronal responses to edges defined by luminance vs. temporal texture in macaque area V1. Vis Neurosci 14: 949-962, 1997.
16. Chubb C, Sperling G. Drift-balanced random stimuli: a general basis for studying non-Fourier motion perception. J Opt Soc Am A Opt Image Sci Vis 5: 1986-2007, 1988.
17. Derrington AM, Badcock DR. Separate detectors for simple and complex grating patterns? Vision Res 25: 1869-1878, 1985.
18. Dumoulin SO, Baker CL Jr, Hess RF, Evans AC. Cortical specialization for processing first- and second-order motion. Cereb Cortex 13: 1375-1385, 2003.
19. Fuchs AF, Robinson DA. A method for measuring horizontal and vertical eye movement chronically in the monkey. J Appl Physiol 21: 1068-1070, 1966.
20. Gellman RS, Carl JR, Miles FA. Short latency ocular-following responses in man. Vis Neurosci 5: 107-122, 1990.
21. Georgeson MA, Shackleton TM. Monocular motion sensing, binocular motion perception. Vision Res 29: 1511-1523, 1989.
22. Georgeson MA, Shackleton TM. No evidence for dichoptic motion sensing: a reply to Carney and Shadlen. Vision Res 32: 193-198, 1992.
23. Harris LR, Smith AT. Motion defined exclusively by second-order characteristics does not evoke optokinetic nystagmus. Vis Neurosci 9: 565-570, 1992.
24. Harris LR, Smith AT. Interactions between first- and second-order motion revealed by optokinetic nystagmus. Exp Brain Res 130: 67-72, 2000.
25. Hawken MJ, Gegenfurtner KR. Pursuit eye movements to second-order motion targets. J Opt Soc Am A Opt Image Sci Vis 18: 2282-2296, 2001.
26. Hayashi R, Maeda T, Shimojo S, Tachi S. An integrative model of binocular vision: a stereo model utilizing interocularly unpaired points produces both depth and binocular rivalry. Vision Res 44: 2367-2380, 2004.
27. Hayashi R, Miyawaki Y, Maeda T, Tachi S. Unconscious adaptation: a new illusion of depth induced by stimulus features without depth. Vision Res 43: 2773-2782, 2003.
28. Hayashi R, Nishida S, Tolias A, Logothetis NK. A method for generating a "purely first-order" dichoptic motion stimulus. J Vis 7: 1-10, 2007.
29. Hays AV, Richmond BJ, Optican LM. A UNIX-based multiple process system for real-time data acquisition and control. WESCON Conf Proc Session 2: 1-10, 1982.
30. Hubel DH, Wiesel TN. Receptive fields and functional architecture of monkey striate cortex. J Physiol 195: 215-243, 1968.
31. Ilg UJ, Churan J. Motion perception without explicit activity in areas MT and MST. J Neurophysiol 92: 1512-1523, 2004.
32. Johnston A, McOwan PW, Buxton H. A computational model of the analysis of some first-order and second-order motion patterns by simple and complex cells. Proc Biol Sci 250: 297-306, 1992.
33. Judge SJ, Richmond BJ, Chu FC. Implantation of magnetic search coils for measurement of eye position: an improved method. Vision Res 20: 535-538, 1980.
34. Kawano K, Shidara M, Watanabe Y, Yamane S. Neural activity in cortical area MST of alert monkey during ocular following responses. J Neurophysiol 71: 2305-2324, 1994.
35. Kelly DH, Boynton RM, Baron WS. Primate flicker sensitivity: psychophysics and electrophysiology. Science 194: 1077-1079, 1976.
36. Ledgeway T, Hutchinson CV. Is the direction of second-order, contrast-defined motion patterns visible to standard motion-energy detectors: a model answer? Vision Res 46: 556-567, 2006.
37. Ledgeway T, Smith AT. Evidence for separate motion-detecting mechanisms for first- and second-order motion in human vision. Vision Res 34: 2727-2740, 1994.
38. Lindner A, Ilg UJ. Initiation of smooth-pursuit eye movements to first-order and second-order motion stimuli. Exp Brain Res 133: 450-456, 2000.
39. Lu ZL, Sperling G. The functional architecture of human visual motion perception. Vision Res 35: 2697-2722, 1995.
40. Lu ZL, Sperling G. Three-systems theory of human visual motion perception: review and update. J Opt Soc Am A Opt Image Sci Vis 18: 2331-2370, 2001a.
41. Lu ZL, Sperling G. Sensitive calibration and measurement procedures based on the amplification principle in motion perception. Vision Res 41: 2355-2374, 2001b.
42. Mareschal I, Baker CL Jr. Temporal and spatial response to second-order stimuli in cat area 18. J Neurophysiol 80: 2811-2823, 1998a.
43. Mareschal I, Baker CL Jr. A cortical locus for the processing of contrast-defined contours. Nat Neurosci 1: 150-154, 1998b.
44. Masson GS, Busettini C, Yang DS, Miles FA. Short-latency ocular following in humans: sensitivity to binocular disparity. Vision Res 41: 3371-3387, 2001.
45. Masson GS, Yang DS, Miles FA. Reversed short-latency ocular following. Vision Res 42: 2081-2087, 2002.
46. Miles FA, Kawano K, Optican LM. Short-latency ocular following responses of monkey. I. Dependence on temporospatial properties of visual input. J Neurophysiol 56: 1321-1354, 1986.
47. Miura K, Matsuura K, Taki M, Tabata H, Inaba N, Kawano K, Miles FA. The visual motion detectors underlying ocular following responses in monkeys. Vision Res 46: 869-878, 2006.
48. Nienborg H, Bridge H, Parker AJ, Cumming BG. Neuronal computation of disparity in V1 limits temporal resolution for detecting disparity modulation. J Neurosci 25: 10207-10219, 2005.
49. Nishida S, Ashida H. A hierarchical structure of motion system revealed by interocular transfer of flicker motion aftereffects. Vision Res 40: 265-278, 2000.
50. Nishida S, Ledgeway T, Edwards M. Dual multiple-scale processing for motion in the human visual system. Vision Res 37: 2685-2698, 1997.
51. Norcia AM, Tyler CW. Temporal frequency limits for stereoscopic apparent motion processes. Vision Res 24: 395-401, 1984.
52. O'Keefe LP, Movshon JA. Processing of first- and second-order motion signals by neurons in area MT of the macaque monkey. Vis Neurosci 15: 305-317, 1998.
53. Patterson R. Stereoscopic (cyclopean) motion sensing. Vision Res 39: 3329-3345, 1999.
54. Plant GT, Laxer KD, Barbaro NM, Schiffman JS, Nakayama K. Impaired visual motion perception in the contralateral hemifield following unilateral posterior cerebral lesions in humans. Brain 116: 1303-1335, 1993.
55. Qian N, Andersen RA. A physiological model for motion-stereo integration and a unified explanation of Pulfrich-like phenomena. Vision Res 37: 1683-1698, 1997.
56. Shadlen M, Carney T. Mechanisms of human motion perception revealed by a new cyclopean illusion. Science 232: 95-97, 1986.
57. Sheliga BM, Chen KJ, Fitzgibbon EJ, Miles FA. Initial ocular following in humans: a response to first-order motion energy. Vision Res 45: 3307-3321, 2005.
58. Sheliga BM, Kodaka Y, FitzGibbon EJ, Miles FA. Human ocular following initiated by competing image motions: evidence for a winner-take-all mechanism. Vision Res 46: 2041-2060, 2006.
59. Smith AT, Greenlee MW, Singh KD, Kraemer FM, Hennig J. The processing of first- and second-order motion in human visual cortex assessed by functional magnetic resonance imaging (fMRI). J Neurosci 18: 3816-3830, 1998.
60. Smith AT, Ledgeway T. Separate detection of moving luminance and contrast modulations: fact or artifact? Vision Res 37: 45-62, 1997.
61. Smith AT, Scott-Samuel NE. First-order and second-order signals combine to improve perceptual accuracy. J Opt Soc Am A Opt Image Sci Vis 18: 2267-2272, 2001.
62. Takemura A, Inoue Y, Kawano K. The effect of disparity on the very earliest ocular following responses and the initial neuronal activity in monkey cortical area MST. Neurosci Res 38: 93-101, 2000.
63. Takemura A, Murata Y, Kawano K, Miles FA. Deficits in short-latency tracking eye movements after chemical lesions in monkey cortical areas MT and MST. J Neurosci 27: 529-541, 2007.
64. Taub E, Victor JD, Conte MM. Nonlinear preprocessing in short-range motion. Vision Res 37: 1459-1477, 1997.
65. Vaina LM, Cowey A. Impairment of the perception of second order motion but not first order motion in a patient with unilateral focal brain damage. Proc Biol Sci 263: 1225-1232, 1996.
66. Vaina LM, Cowey A, Kennedy D. Perception of first- and second-order motion: separable neurological mechanisms? Hum Brain Mapp 7: 67-77, 1999.
67. Van Der Steen J, Kanai R. Binocular eye movement responses to dichoptically presented horizontal and/or vertical stimulus steps. Ann NY Acad Sci 956: 487-491, 2002.
68. Victor JD, Conte MM. Evoked potential and psychophysical analysis of Fourier and non-Fourier motion mechanisms. Vis Neurosci 9: 105-123, 1992.
69. Wilson HR, Ferrera VP, Yo C. A psychophysically motivated model for two-dimensional motion perception. Vis Neurosci 9: 79-97, 1992.
70. Wilson HR, Kim J. A model for motion coherence and transparency. Vis Neurosci 11: 1205-1220, 1994.
71. Zanker JM, Hupgens IS. Interaction between primary and secondary mechanisms in human motion perception. Vision Res 34: 1255-1266, 1994.
72. Zhou YX, Baker CL Jr. A processing stream in mammalian visual cortex neurons for non-Fourier responses. Science 261: 98-101, 1993.
73. Zhou YX, Baker CL Jr. Envelope-responsive neurons in areas 17 and 18 of cat. J Neurophysiol 72: 2134-2150, 1994.