Note to users. If you're seeing this message, it means that your browser cannot find this page's style/presentation instructions -- or possibly that you are using a browser that does not support current Web standards. Find out more about why this message is appearing, and what you can do to make your experience of our site the best it can be.

Science 14 May 1993:
Vol. 260. no. 5110, pp. 995 - 997
DOI: 10.1126/science.8493538
Prev | Table of Contents | Next

Articles

Science, Vol 260, Issue 5110, 995-997
Copyright © 1993 by American Association for the Advancement of Science

articles

Cue-invariant shape selectivity of macaque inferior temporal neurons

G Sary, R Vogels, and GA Orban

Laboratorium voor Neuro- en Psychofysiologie, Faculteit der Geneeskunde, Katholieke Universiteit Leuven, Belgium.

The perception of shape is independent of the size and position of the shape and also of the visual cue that defines it. The same shape can be recognized whether defined by a difference in luminance, by motion, or by texture. Experiments showed that the shape selectivity of individual cells in the macaque inferior temporal cortex did not vary with the size and position of a shape and also did not vary with the visual cue used to define the shape. This cue invariance was true for static luminance and texture cues as well as for relative motion cues--that is, for cues that are processed in ventral and dorsal visual pathways. The properties of these inferior temporal cells meet the demands of cue-invariant shape coding.


THIS ARTICLE HAS BEEN CITED BY OTHER ARTICLES:
The Role of Background Statistics in Face Adaptation.
J. Wu, H. Xu, P. Dayan, and N. Qian (2009)
J. Neurosci. 29, 12035-12044
   Abstract »    Full Text »    PDF »
A Distinct Representation of Three-Dimensional Shape in Macaque Anterior Intraparietal Area: Fast, Metric, and Coarse.
S. Srivastava, G. A. Orban, P. A. De Maziere, and P. Janssen (2009)
J. Neurosci. 29, 10613-10626
   Abstract »    Full Text »    PDF »
What Response Properties Do Individual Neurons Need to Underlie Position and Clutter "Invariant" Object Recognition?.
N. Li, D. D. Cox, D. Zoccolan, and J. J. DiCarlo (2009)
J Neurophysiol 102, 360-376
   Abstract »    Full Text »    PDF »
Representing the Forest before the Trees: A Global Advantage Effect in Monkey Inferotemporal Cortex.
A. P. Sripati and C. R. Olson (2009)
J. Neurosci. 29, 7788-7796
   Abstract »    Full Text »    PDF »
Distinguishing Conjoint and Independent Neural Tuning for Stimulus Features With fMRI Adaptation.
D. M. Drucker, W. T. Kerr, and G. K. Aguirre (2009)
J Neurophysiol 101, 3310-3324
   Abstract »    Full Text »    PDF »
Timescale-Invariant Representation of Acoustic Communication Signals by a Bursting Neuron.
F. Creutzig, S. Wohlgemuth, A. Stumpner, J. Benda, B. Ronacher, and A. V. M. Herz (2009)
J. Neurosci. 29, 2575-2580
   Abstract »    Full Text »    PDF »
Cortical mechanisms of sensory learning and object recognition.
K.L Hoffman and N.K Logothetis (2009)
Phil Trans R Soc B 364, 321-329
   Abstract »    Full Text »    PDF »
Coding of Shape and Position in Macaque Lateral Intraparietal Area.
P. Janssen, S. Srivastava, S. Ombelet, and G. A. Orban (2008)
J. Neurosci. 28, 6679-6690
   Abstract »    Full Text »    PDF »
Shape Selectivity for Camouflage-Breaking Dynamic Stimuli in Dorsal V4 Neurons.
S. G. Mysore, R. Vogels, S. E. Raiguel, and G. A. Orban (2008)
Cereb Cortex 18, 1429-1443
   Abstract »    Full Text »    PDF »
Representation of Shapes, Edges, and Surfaces Across Multiple Cues in the Human Visual Cortex.
J. Vinberg and K. Grill-Spector (2008)
J Neurophysiol 99, 1380-1393
   Abstract »    Full Text »    PDF »
Higher Order Visual Processing in Macaque Extrastriate Cortex.
G. A. Orban (2008)
Physiol Rev 88, 59-89
   Abstract »    Full Text »    PDF »
Cue-invariant detection of centre surround discontinuity by V1 neurons in awake macaque monkey.
Z.-M. Shen, W.-F. Xu, and C.-Y. Li (2007)
J. Physiol. 583, 581-592
   Abstract »    Full Text »    PDF »
Receptive Field Properties of the Macaque Second Somatosensory Cortex: Nonlinear Mechanisms Underlying the Representation of Orientation Within a Finger Pad.
P. H. Thakur, P. J. Fitzgerald, J. W. Lane, and S. S. Hsiao (2006)
J. Neurosci. 26, 13567-13575
   Abstract »    Full Text »    PDF »
Time Representations Can Be Made from Nontemporal Information in the Brain: An MEG Study.
Y. Noguchi and R. Kakigi (2006)
Cereb Cortex 16, 1797-1808
   Abstract »    Full Text »    PDF »
Cue-invariant networks for figure and background processing in human visual cortex..
L. G. Appelbaum, A. R. Wade, V. Y. Vildavski, M. W. Pettet, and A. M. Norcia (2006)
J. Neurosci. 26, 11695-11708
   Abstract »    Full Text »    PDF »
Charting the lower superior temporal region, a new motion-sensitive region in monkey superior temporal sulcus..
K. Nelissen, W. Vanduffel, and G. A. Orban (2006)
J. Neurosci. 26, 5929-5947
   Abstract »    Full Text »    PDF »
Neural basis for stereopsis from second-order contrast cues..
H. Tanaka and I. Ohzawa (2006)
J. Neurosci. 26, 4370-4382
   Abstract »    Full Text »    PDF »
Processing of Kinetic Boundaries in Macaque V4.
S. G. Mysore, R. Vogels, S. E. Raiguel, and G. A. Orban (2006)
J Neurophysiol 95, 1864-1880
   Abstract »    Full Text »    PDF »
Orientation-Selective Adaptation to First- and Second-Order Patterns in Human Visual Cortex.
J. Larsson, M. S. Landy, and D. J. Heeger (2006)
J Neurophysiol 95, 862-881
   Abstract »    Full Text »    PDF »
The Integration of Colour and Motion by the Human Visual Brain.
M. W. Self and S. Zeki (2005)
Cereb Cortex 15, 1270-1279
   Abstract »    Full Text »    PDF »
Stimulus Dependence of Disparity Coding in Primate Visual Area V4.
J. Hegde and D. C. Van Essen (2005)
J Neurophysiol 93, 620-626
   Abstract »    Full Text »    PDF »
Unilateral Deficits in Visual Perception and Learning after Unilateral Inferotemporal Cortex Lesions in Macaques.
W. H. Merigan and R. C. Saunders (2004)
Cereb Cortex 14, 863-871
   Abstract »    Full Text »    PDF »
Convergence of Depth from Texture and Depth from Disparity in Macaque Inferior Temporal Cortex.
Y. Liu, R. Vogels, and G. A. Orban (2004)
J. Neurosci. 24, 3795-3800
   Abstract »    Full Text »    PDF »
The Processing of Visual Shape in the Cerebral Cortex of Human and Nonhuman Primates: A Functional Magnetic Resonance Imaging Study.
K. Denys, W. Vanduffel, D. Fize, K. Nelissen, H. Peuskens, D. Van Essen, and G. A. Orban (2004)
J. Neurosci. 24, 2551-2565
   Abstract »    Full Text »    PDF »
Representation of the Perceived 3-D Object Shape in the Human Lateral Occipital Complex.
Z. Kourtzi, M. Erb, W. Grodd, and H. H. Bulthoff (2003)
Cereb Cortex 13, 911-920
   Abstract »    Full Text »    PDF »
Anterior Inferotemporal Neurons of Monkeys Engaged in Object Recognition Can be Highly Sensitive to Object Retinal Position.
J. J. DiCarlo and J. H. R. Maunsell (2003)
J Neurophysiol 89, 3264-3278
   Abstract »    Full Text »    PDF »
Psychological and neural perspectives on the role of motion in face recognition..
D. A. Roark, S. E. Barrett, M. J. Spence, H. Abdi, and A. J. O'Toole (2003)
Behav Cogn Neurosci Rev 2, 15-46
   Abstract »    PDF »
Human Cortical Object Recognition from a Visual Motion Flowfield.
N. Kriegeskorte, B. Sorger, M. Naumer, J. Schwarzbach, E. van den Boogert, W. Hussy, and R. Goebel (2003)
J. Neurosci. 23, 1451-1463
   Abstract »    Full Text »    PDF »
Effects of Surface Cues on Macaque Inferior Temporal Cortical Responses.
G. Kovacs, G. Sary, K. Koteles, Z. Chadaide, T. Tompa, R. Vogels, and G. Benedek (2003)
Cereb Cortex 13, 178-188
   Abstract »    Full Text »    PDF »
The Processing of Kinetic Contours in the Brain.
S. Zeki, R.J. Perry, and A. Bartels (2003)
Cereb Cortex 13, 189-202
   Abstract »    Full Text »    PDF »
Columns for Complex Visual Object Features in the Inferotemporal Cortex: Clustering of Cells with Similar but Slightly Different Stimulus Selectivities.
K. Tanaka (2003)
Cereb Cortex 13, 90-99
   Abstract »    Full Text »    PDF »
Physiological Responses of New World Monkey V1 Neurons to Stimuli Defined by Coherent Motion.
J. A. Bourne, R. Tweedale, and M. G.P. Rosa (2002)
Cereb Cortex 12, 1132-1145
   Abstract »    Full Text »    PDF »
Effects of Illumination Intensity and Direction on Object Coding in Macaque Inferior Temporal Cortex.
R. Vogels and I. Biederman (2002)
Cereb Cortex 12, 756-766
   Abstract »    Full Text »    PDF »
The Spatiotemporal Dynamics of Illusory Contour Processing: Combined High-Density Electrical Mapping, Source Analysis, and Functional Magnetic Resonance Imaging.
M. M. Murray, G. R. Wylie, B. A. Higgins, D. C. Javitt, C. E. Schroeder, and J. J. Foxe (2002)
J. Neurosci. 22, 5055-5073
   Abstract »    Full Text »    PDF »
Contrast Sensitivity in Human Visual Areas and Its Relationship to Object Recognition.
G. Avidan, M. Harel, T. Hendler, D. Ben-Bashat, E. Zohary, and R. Malach (2002)
J Neurophysiol 87, 3102-3116
   Abstract »    Full Text »    PDF »
Macaque Inferior Temporal Neurons Are Selective for Three-Dimensional Boundaries and Surfaces.
P. Janssen, R. Vogels, Y. Liu, and G. A. Orban (2001)
J. Neurosci. 21, 9419-9429
   Abstract »    Full Text »    PDF »
Representation of Perceived Object Shape by the Human Lateral Occipital Complex.
Z. Kourtzi and N. Kanwisher (2001)
Science 293, 1506-1509
   Abstract »    Full Text »    PDF »
Processing of Shape Defined by Disparity in Monkey Inferior Temporal Cortex.
H. Tanaka, T. Uka, K. Yoshiyama, M. Kato, and I. Fujita (2001)
J Neurophysiol 85, 735-744
   Abstract »    Full Text »    PDF »
Invariance of Angular Threshold Computation in a Wide-Field Looming-Sensitive Neuron.
F. Gabbiani, C. Mo, and G. Laurent (2001)
J. Neurosci. 21, 314-329
   Abstract »    Full Text »    PDF »
Processing of Kinetically Defined Boundaries in Areas V1 and V2 of the Macaque Monkey.
V. L. Marcar, S. E. Raiguel, D. Xiao, and G. A. Orban (2000)
J Neurophysiol 84, 2786-2798
   Abstract »    Full Text »    PDF »
Cortical Regions Involved in Perceiving Object Shape.
Z. Kourtzi and N. Kanwisher (2000)
J. Neurosci. 20, 3310-3318
   Abstract »    Full Text »    PDF »
Visual discrimination after anterior temporal lobectomy in humans.
J. D. Mendola, J. F. Rizzo III, G. R. Cosgrove, A. J. Cole, P. Black, and S. Corkin (1999)
Neurology 52, 1028
   Abstract »    Full Text »    PDF »
Effect of Motion Contrast on Human Cortical Responses to Moving Stimuli.
G. L. Shulman, J. Schwarz, F. M. Miezin, and S. E. Petersen (1998)
J Neurophysiol 79, 2794-2803
   Abstract »    Full Text »    PDF »
Positron-emission tomography imaging of long-term shape recognition challenges.
A. Rosier, L. Cornette, P. Dupont, G. Bormans, J. Michiels, L. Mortelmans, and G. A. Orban (1997)
PNAS 94, 7627-7632
   Abstract »    Full Text »    PDF »
Detection and Discrimination of First- and Second-Order Motion in Patients with Unilateral Brain Damage.
M. W. Greenlee and A. T. Smith (1997)
J. Neurosci. 17, 804-818
   Abstract »    Full Text »    PDF »
The Analysis of Complex Motion Patterns by Form/Cue Invariant MSTd Neurons.
B. J. Geesaman and R. A. Andersen (1996)
J. Neurosci. 16, 4716-4732
   Abstract »    Full Text »    PDF »
Neuronal tuning and associative mechanisms in form representation..
K Sakai, Y Naya, and Y Miyashita (1994)
Learn. Mem. 1, 83-105
   Abstract »    PDF »


To Advertise     Find Products

Science. ISSN 0036-8075 (print), 1095-9203 (online)