+353-1-416-8900REST OF WORLD
+44-20-3973-8888REST OF WORLD
1-917-300-0470EAST COAST U.S
1-800-526-8630U.S. (TOLL FREE)


Extrageniculostriate Mechanisms Underlying Visually-Guided Orientation Behavior. Progress in Brain Research Volume 112

  • ID: 1761461
  • Book
  • November 1996
  • Elsevier Science and Technology
The last few years have seen a dramatic increase in the number of areas known to be involved in mammalian vision. It has also seen a far greater understanding of the importance of reciprocal connections, intrinsic connections, structure-specific modules and modules which span different structures, as well as the introduction of parallel processing models within the thalamocortical and corticocortical streams.

The body of knowledge has become so vast, and is growing so rapidly, that periodic updates are essential even for experts in the field. This volume is based on a satellite meeting of an international group of researchers. It emphasizes the most current information regarding midbrain and extrastriate mechanisms underlying vision and visually-guided behavior. The book also places these data into the larger context of how interrelated components of the visual system function to produce coherent visual experiences and behavior. New research findings are presented that are unavailable elsewhere, as well as reviews and broad perspectives in which existing data from multiple sources are brought together in order to help understand the structure and function of extrageniculostriate visual areas.

Please Note: This is an On Demand product, delivery may take up to 11 working days after payment has been received.

Note: Product cover images may vary from those shown
List of Contributors. Preface. 1. Neural mechanisms of visual orienting responses (J.M. Sprague). 2.
The mosaic architecture of the superior colliculus (R.-B. Illing). 3. Neurochemical microcircuitry
underlying visual and oculomotor function in the cat superior colliculus (R.R. Mize). 4. Serotonin
modulates retinotectal and corticotectal convergence in the superior colliculus (R.D. Mooney et al).
5. Morphology of single axons of tectospinal and reticulospinal neurons in the upper cervical spinal
cord (Y. Shinoda, S. Kakei, N. Muto). 6. A projection linking motor cortex with the LM-suprageniculate
nuclear complex through the periaqueductal gray area which surrounds the nucleus of Darkschewitsch
in the cat (S. Onodera, T.P. Hicks). 7. Firing characteristics of neurones in the superior colliculus and
the pontomedullary reticular formation during orienting in unrestrained cats (S. Sasaki, K. Naito, M.
Oka). 8. Ibotenic acid lesions of the superior colliculus produce longer lasting deficits in visual
orienting behavior than aspiration lesions in the cat (A.C. Rosenquist, V.M. Ciaramitaro). 9. Spatial
distribution of tectotectal connections in cats (M. Behan, N.M. Kime). 10. Roles of the lateral
suprasylvian cortex in convergence eye movements in the cats (T. Bando et al.). 11. Functional
connectivity of the superior colliculus with saccade-related brain stem neurons in the cat (S. Chimoto
et al.). 12. Visual-auditory integration in cat superior colliculus: implications for neuronal control of
the orienting response (C.K. Peck). 13. Task-dependence of saccade-related activity in monkey
superior colliculus: implications for models of the saccadic system (A.J. Van Opstal, M.A. Frens). 14.
Coding of stimulus invariances by inferior temporal neurons (R. Vogels, G.A. Orban). 15. Theories
of visual cortex organization in primates: areas of the third level (J.H. Kaas). 16. Afferent and
developmentally inherent mechanisms of form and motion processing in cat extrastriate cortex (P.D.
Spear). 17. Extrinsic and intrinsic connections of the cat's lateral suprasylvian visual area (M. Norita
et al.). 18. Areas PMLS and 21a of cat visual cortex are not only functionally but also hodologically
distinct (B. Dreher et al). 19. Motion sensitivity and stimulus interactions in the striate-recipient zone
of the cat's lateral posterior-pulvinar complex (C. Casanova, T. Savard). 20. Comparisons of cross-modality integration in midbrain and cortex (B.E. Stein, M.T. Wallace). 21. Sensory organization of
the superior colliculus in cat and monkey (M.T. Wallace, B.E. Stein). 22. Substitution of visual by
auditory inputs in the cat's anterior ectosylvian cortex (J.P. Rauschecker). 23. Visual, somatosensory
and auditory modality properties along the feline suprageniculate-AES/insular pathway (Gy. Benedek
et al.). 24. The development of topographically-aligned maps of visual and auditory space in the
superior colliculus (A.J. King et al.). 25. What do developmental mapping rules optimize? (M. Xiong,
B.L. Finlay). 26. The effect of damage of the brachium of the superior colliculus in neonatal and adult
hamsters and the use of peripheral nerve to restore retinocollicular projections (K.-F. So et al). 27.
A proposed reorganization of the cortical input-output system (Y. Tamai). 28. Neural bases of residual
vision in hemicorticectomized monkeys (M. Ptito et al.). 29. Extrageniculostriate vision in humans:
investigations with hemispherectomy patients (C.M. Wessinger et al.). 30. Visual inputs to cerebellar
ventral paraflocculus during ocular following responses (K. Kawano et al.). 31. Context dependent
discharge characteristics of saccade-related Purkinje cells in the cerebellar hemispheres of the monkey
(N. Mano et al). 32. Further evidence for the specific involvement of the flocculus in the vertical
vestibulo-ocular reflex (VOR) (K. Fukushima et al.). Subject Index.
Note: Product cover images may vary from those shown
M. Norita Department of Anatomy, Niigata University School of Medicine, Asahimachi Niigata, Japan.

T. Bando Department of Physiology, Niigata University School of Medicine, Asahimachi Niigata, Japan.

B. Stein Neurobiology and Anatomy, The Bowman Gray School of Medicine, Wake Forest, Winston Salem, NC, USA.
Note: Product cover images may vary from those shown