Disparity selective units in the superior colliculus of the opossum (original) (raw)
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References
- Barlow HB, Blakemore C, Pettigrew JD (1967) The neural mechanism of binocular depth discrimination. J Physiol 193: 327–342
Google Scholar - Berman N, Blakemore C, Cynader M (1975) Binocular interactions in the cat's superior colliculus. J Physiol 246: 595–615
Google Scholar - Bishop PO, Pettigrew JP (1986) Neural mechanisms of binocular vision. Vision Res 26: 1587–1600
Google Scholar - Chalupa L (1984) Visual physiology of the mammalian superior colliculus. In: Vanegas H (eds) Comparative neurology of the optic tectum. Plenum Publishing Corporation, New York, pp 775–818
Google Scholar - Cooper ML, Pettigrew, JD (1979) A neurophysiological determination of the vertical horopter in the cat and owl. J Comp Neurol 184: 1–24
Google Scholar - Dean P, Redgrave P, Sahibzaba N, Tsuji K (1986) Head and body movements produced by electrical stimulation of superior colliculus in rats: effects of interruption of the crossed tectorecticulospinal pathway. Neuroscience 19: 367–380
Google Scholar - Felleman DJ, Van Essen DC (1987) Receptive field properties of neurons in area V3 of macaque monkey extrastriate cortex. J Neurophysiol 57: 889–920
Google Scholar - Fernald R, Chase R (1971) An improved method for plotting retinal landmarks and focussing the eyes. Vision Res 11: 95–96
Google Scholar - Ferster F (1981) A comparision of binocular depth mechanisms in areas 17 and 18 of the cat visual cortex. J Physiol 311: 623–655
Google Scholar - Gawryszewski LG, Rocha-Miranda CE, Volchan E, Linden R (1978) Receptive field properties of single units in the opossum superior colliculus. In: Rocha-Miranda CE, Lent R (eds) Opossum neurobiology. Academia Brasileira de Ciencias, Rio de Janeiro, pp 167–192
Google Scholar - Lee C, Rohrer WH, Sparks DL (1988) Population coding of saccadic eye movements by neurons in the superior colliculus. Nature 332: 357–360
Article CAS PubMed Google Scholar - Nelson JI (1986) Unsolved problems in the cellular basis of stereopsis. In: Pettigew JD, Sanderson KJ, Levick WR (eds) Visual neuroscience. Cambridge University Press, Cambridge, pp 405–420
Google Scholar - Nikara T, Bishop PO, Pettigrew JD (1968) Analysis of retinal correspondence by studying receptive fields of binocular single units in cat striate cortex. Exp Brain Res 6: 353–372
Google Scholar - Oswaldo-Cruz E, Hokoc JN, Sousa APB (1979) A schematic eye for the opossum. Vision Res 19: 263
Google Scholar - Pettigrew JD (1979) Binocular visual processing in the owl's telencephalon. Proc R Soc Lond B 204: 435–454
Google Scholar - Pettigrew JD (1986) The evolution of binocular vision. In: Pettigew JD, Sanderson KJ, Levick WR (eds) Visual neuroscience. Cambridge University Press, Cambridge, pp 208–222
Google Scholar - Pettigrew JD, FRS, Dreher B (1987) Parallel processing of binocular disparity in the cat's retinogeniculocortical pathways. Proc R Soc Lond B 232: 297–321
Google Scholar - Pettigrew JD, Konishi M (1976) Neurons selective for orientation and binocular disparity in the visual Wulst of the barn owl (Tyto alba). Science 193: 675–678
Google Scholar - Picanço-Diniz CW, Silveira LCL, Oswaldo-Cruz E (1983) Electrophysiological determination of the refractive state of the eye of the opossum. Vision Res 23: 867–872
Google Scholar - Poggio GF, Fisher B (1977) Binocular interaction and depth sensitivity in striate and prestriate cortex of behaving rhesus monkey. JNeurophysiol 40: 1392–1405
Google Scholar - Poggio GF, Motter BC, Squatrito S, Trotter Y (1985) Responses of neurons in visual cortex (V1 and V2) of alert macaque to randomdot stereograms. Vision Res 25: 397–406
Google Scholar - Poggio GF, Poggio T (1984) The analysis of stereopsis. Ann Rev Neurosci 7: 379–412
Google Scholar - Poggio GF, Talbot, WH (1981) Mechanism of static and dynamic stereopsis in foveal cortex of rhesus monkey. J Physiol 315: 469–492
Google Scholar - Ramoa AS, Rocha-Miranda CE, Mendez-Otero R, Josua KM (1983) Visual receptive fields in the superficial layers of the opossum's superior colliculus: representation of the ipsi and contralateral hemifield by each eye. Exp Brain Res 49: 373–380
Google Scholar - Ramoa AS, Rocha-Miranda CE, Gawryszewski LG, Volchan E, Struchiner CJ (1985) Visuotopic information conveyed by each eye to the opossum's superior colliculus. Exp Brain Res 60: 576–583
Google Scholar - Rocha-Miranda CE, Cavalcante LA, Gawryszewski LG, Linden R, Volchan E (1978) The vertical meridian representation and the pattern of retinotectal projections in the opossum. In: Rocha-Miranda CE, Lent R (eds) Opossum neurobiology. Academia Brasileira de Ciencias, Rio de Janeiro, pp 113–126
Google Scholar - Rocha-Miranda CE, Mendez-Otero R, Ramôa AS, Volchan E, Gawryszewski LG (1984) Retinocollicular plasticity in the opossum. In: Stone J, Dreher B, Rappaport DH (eds) The development of visual pathways in mammals. Alan Liss, New York, pp 179–197
Google Scholar - Sousa APB, Gattass R, Oswaldo-Cruz E (1978) The projection of the opossum's visual field on the cerebral cortex. J Comp Neurol 177: 569–588
Google Scholar - Stein BE, Arigbede M (1972) Unimodal and multimodal response properties of neurons in the cat's superior colliculus. Exp Neurol 36: 179–196
Google Scholar - Volchan E, Bernardes RF, Rocha-Miranda CE, Gleiser L, Gawryszewski LG (1988) The ipsilateral field representation in the striate cortex of the opossum. Exp Brain Res 73: 297–314
Google Scholar