A neural network model for the development of direction selectivity in the visual cortex

A neural network model is proposed to explain the development of direction selectivity of cortical cells. The model is constructed under the following three hypotheses that are very plausible from recent neurophysiological findings. (1) Direction selectivity is developed by modifiable inhibitory synapses. (2) It results not from the direct convergence of many excitatory inputs from LGN cells but from cortical neural networks. (3) Direction-selective mechanism is independent of orientation-selective mechanism.—The model was simulated on a computer for a few kinds of inhibitory connections and initial conditions. The results were consistent with neurophysiological facts not only for normal cats but for cats reared in an abnormal visual environment.

[1]  D. N. Spinelli,et al.  Visual Experience Modifies Distribution of Horizontally and Vertically Oriented Receptive Fields in Cats , 1970, Science.

[2]  C. von der Malsburg Self-organization of orientation sensitive cells in the striate cortex. , 1973, Kybernetik.

[3]  A Hein,et al.  Cats reared in stroboscopic illumination: effects on receptive fields in visual cortex. , 1973, Proceedings of the National Academy of Sciences of the United States of America.

[4]  B. Dreher,et al.  Receptive field analysis: responses to moving visual contours by single lateral geniculate neurones in the cat , 1973, The Journal of physiology.

[5]  J. Pettigrew,et al.  Single units in visual cortex of kittens reared in stroboscopic illumination. , 1974, Brain research.

[6]  R. Pérez,et al.  Development of Specificity in the Cat Visual Cortex , 1975, Journal of mathematical biology.

[7]  W. Singer,et al.  Modification of direction selectivity of neurons in the visual cortex of kittens , 1975, Brain Research.

[8]  P. O. Bishop,et al.  Direction selectivity of simple striate cells: properties and mechanism. , 1975, Journal of neurophysiology.

[9]  J. L. Conway,et al.  Bicuculline reversal of deprivation amblyopia in the cat , 1976, Nature.

[10]  W. Singer,et al.  Modification of orientation and direction selectivity of cortical cells in kittens with monocular vision , 1976, Brain Research.

[11]  P. Schiller,et al.  Quantitative studies of single-cell properties in monkey striate cortex. V. Multivariate statistical analyses and models. , 1976, Journal of neurophysiology.

[12]  H. Kennedy,et al.  Effects of stroboscopic rearing on the binocularity and directionality of cat superior colliculus neurons , 1976, Brain Research.

[13]  M. Cynader,et al.  Abolition of direction selectivity in the visual cortex of the cat. , 1976, Science.

[14]  A. Sillito Inhibitory processes underlying the directional specificity of simple, complex and hypercomplex cells in the cat's visual cortex , 1977, The Journal of physiology.

[15]  Roman Bek,et al.  Discourse on one way in which a quantum-mechanics language on the classical logical base can be built up , 1978, Kybernetika.

[16]  Kunihiko Fukushima,et al.  Cognitron: A self-organizing multilayered neural network , 1975, Biological Cybernetics.

[17]  T. Nagano A model of visual development , 1977, Biological Cybernetics.

[18]  M. Cynader,et al.  Cats raised in a one-directional world: Effects on receptive fields in visual cortex and superior colliculus , 1975, Experimental Brain Research.

[19]  O. Creutzfeldt,et al.  An intracellular analysis of visual cortical neurones to moving stimuli: Responses in a co-operative neuronal network , 2004, Experimental Brain Research.

[20]  The distribution of orientation of optimal stimuli for cells of striate cortex , 1976, Biological Cybernetics.

[21]  L. Cooper,et al.  A theory for the development of feature detecting cells in visual cortex , 1975, Biological Cybernetics.