Neurons and Interneuronal Connections of the Central Visual System Neurons and Interneuronal Connections of the Central Visual System Ekaterina G. Shkol'nik-Yarros Brain Institute Academy of Medical Sciences of the USSR Moscow, USSR Translated from Russian by Basil Haigh Translation Editor Robert W. Doty Center for Brain Research University of Rochester Rochester, New York <±> PLENUM PRESS • NEW YORK-LONDON • 1971 The original Russian text, published by Meditsina Press in 1965 for the Academy of Medical Sciences of the USSR, has been corrected by the author for the present edition. The English translation is published under an agreement with Mezhdunarodnaya Kniga, the Soviet book export agency. E. r. WKonbH~K·flPPOC HE~POHbl ~ MEH{HE~POHHbIE CBfl3~-3P~TEnbHbl~ AHAn~3ATOP NEIRONY I MEZHNEIRONNYE SVYAZI-ZRITEL'NYI ANALIZATOR Library of Congress Catalog Card Number 69·18115 ISBN-13: 978-1-4684-0717-4 e-ISBN-13: 978-1·4684-0715-0 001: 10.1007/978-1-4684-0715-0 © 1971 Plenum Press, New York Softcover reprint of the hardcover 1s t edition 1971 A Division of Plenum Publishing Corporation 227 West 17th Street, New York, N.Y. 10011 United Kingdom edition published by Plenum Press, London A Division of Plenum Publishing Company, Ltd. Davis House (4th Floor), 8 Scrubs Lane, Harlesden, NW10 6SE, England All rights reserved No part of this pUblication !)lay be reproduced in any form without written permission from the publisher PREFACE This century has witnessed the creation of new sciences extending the frontiers of knowledge to an unprecedented degree. We have seen the birth of cybernetics and bionics, bringing together such apparently distantly related branches of science as neurohistology and automation, synaptology and electronics. The electron microscope has resolved tissues almost down to the molecular level, and histochemistry has led to the fine analysis of brain structure. However, before these and other new sciences can develop properly and scientifically, a precise knowledge of the structure of the material with which they are concerned is absolutely essential. That is why the need exists at the present time for a detailed study of the larger units, i.e., the neurons, their interrelationships and the pathways by which excitation is conducted. Biologists, neurologists, physicists, and specialists in other technical disci plines will find this study highly useful. During recent years many advances have been made in knowledge of the central visual system and its pathways. Above all, it has been found that the visual system is very extensive. The optic tract is connected, not only with the lateral geniculate body, but with the superior colliculus and the pulvinar. Besides the discovery of these principal pathways, connections have also been studied with the hypothalamus, the pretectal region, the medial geniculate body, subthalamus, and other parts of the brain stem. The visual system is thus connected with the reflex apparatus, the autonomic nervous system, and the auditory and reticular systems. At the cortical level, visual representation likewise has been shown not to be confined to the typical visual center in Area 17. The discovery of these complex and extensive connections at cortical and subcortical levels has considerably broadened present concepts of analyzers in general and of the visual analyzer in particular. Refined electrophysiological investigations in recent years have revealed remarkable facts concerning the convergence of excitation on visual cortical neurons. The same neuron can apparently receive not only specific visual impulses, but also impulses of a different character, such as vestibular, vi Preface auditory, etc. It has also been found that neurons reacting to onset and cessation of light and to changes in the direction of movement exist not only in the retina but also in the cortex (Jung et al.; Rubel and Wiesel), and that many other types of neurons can be distinguished by their response to exci tation of the visual receptor. Recent microelectrode studies of De Valois and co-workers are developing in the same direction. They have shown that neurons of the lateral geniculate body in primates do not respond equally to colored stimuli. What is revealed by these new data concerning the organization of analyzers? Is it possible to correlate the anatomical and physiological facts? With the gradual accumulation of facts concerning neurons of the central visual system, problems have arisen which have been partially solved or have given rise to other new problems: by comparison with other analyzers, does the structure of the visual analyzer exhibit specificity? Are the attempts to regard the retina as connected with the brain only by centripetal fibers valid? Can a morphological basis for color vision be found in the structure of the brain? These and many other questions can be answered most satisfactorily and completely by a systematic investigation of the neurons and inter neuronal connections of the central visual system, and this was the main purpose of the work described in this volume, most of which was done between 1947 and 1960. As a foundation for my research, carried on at the Brain Institute, Academy of Medical Sciences of the U.S.S.R., I have been fortunate in hav ing the experience of members of the Institute's staff, gained during many years of investigating the phylogeny and ontogeny of the brain and its neuronal structure. I particularly wish to express my sincere thanks to Professor G.I. Polyakov, to T.A. Leontovich, and to G.P. Zhukova for their unswerving and friendly support and for their helpful criticisms. I am also grateful to A. A. Kudryashev and M. A. Vinogradova, of the Photographic Laboratory of the Brain Institute and to laboratory artists A. V. Chekurova, V. A. Nilova, and R. I. Minakova for preparing the photographs and drawings for publication. The illustrations were made by means of a drawing apparatus; the cortex and lateral geniculate body are represented as composite drawings from series of sections impregnated by Golgi's method. I also wish to thank A. S. Novokhatskii, V. G. Skrebitskii, and I. M. Feigenberg for their valuable comments during preparation of the manu script for publication. E.G. SHKOL'NIK-YARROS CONTENTS Chapter 1. Neurons of the Central Visual System........................... 1 The Cortex and Lateral Geniculate Body .................................. .. Neuronal Structure of the Visual Cortex and Lateral Geniculate Body in Some Mammals ... . .. ... ...... ... ...... . . . ... . .. .. .. .. ... . .. .. . ... . .. 13 Visual System of the Hedgehog (Insectivora) ........................... 13 Visual System of the Rabbit (Rodentia) ................................. 20 Visual System of the Dog (Carnivora) .................................... 37 Visual System of Monkeys (Primates) .................................... 57 Visual System of Man......................................................... 79 Size of the Neurons and Density of Their Arrangement ............ 100 Characteristics of the Layers of the Visual Cortex ..................... 105 Similarities and Differences Between Neurons of Monkey and Man ........................................................................ 111 Distinctive Structural Features of Neurons in Areas 17, 18, and 19 of the Human Occipital Cortex ................................. 114 Chapter 2. Connections Between Neurons and Details of Their Structure ........................................................................... 118 Endings and Branches of Axons ... .. .... .. .. .. .. .. .. .... .. ...... ......... ...... 118 Dendrites, Their Endings and Ramifications ................................. 124 Varieties of Connections Between Neurons in the Cortical and Subcortical Parts of the Visual System .............................. 135 Axo-dendritic Contacts of Cortical Pyramidal Cells .................. 140 Axo-somatic Connections of Cortical Pyramidal Cells ............... 155 Axo-dendritic Contacts of Cortical Stellate Cells " ................ '" 160 Axo-somatic Contacts of Cortical Stellate Cells ..................... '" 161 Axo-axonal Connections in the Cortex .. ....... .. .. .. .. .. .. .. .......... 165 Axo-dendritic and Axo-somatic Contacts of Cells of the Lateral Geniculate Body ... . .. ... ... .... .. ... . .. .. .. .. .. . ... .. .. .. .. . . ... .. .. . ... 166 Connections in the Retina ................................................... 173 Reality of the Systems of Spines on Dendrites; Their Origin and Role 175 vii viii Contents Structure of Interneuronal Connections in the Cortex 182 Chapter 3. Differences in Structure and Connections of the Visual System at Cortical and Subcortical Levels .............................. 189 The Cortical Level .;................................................................ 189 Connections of Pyramidal Cells and Their Significance ........... . 189 Connections of the Long-Axon Star Cells of Cajal ................. . 193 Connections of Short-Axon Stellate Cells and Their Significance 195 The Subcortical Level .............................................................. . 199 Neurons of the Lateral Geniculate Body ................................. 199 The Main Differences Between Neurons of the Visual Cortex and Lateral Geniculate Body................................................ 202 Chapter 4. Structure of the Central Visual System and Pathways ...... 210 Cortical Analyzer and Diffuse Elements ....................................... 210 Efferent Connections of the Visual Cortex ........................ ' ........... 221 Centrifugal Connections of the Retina.......................................... 239 A Scheme of the Structure of the Visual System ........................ '" 245 Chapter 5. Specificity of Structure of the Central Visual System ... '" 249 Structure of Neurons of the Visual System and Their Comparison with Other Neurons............................................................ 249 Specificity of Structure in Relation to the Problem of Color Vision ... 258 New Data on the Structure and Function of the Lateral Geniculate Body in Primates Relative to the Problem of Color Vision......... 268 Bibliography ........................................................................... 275 Index .................................................................................... 293 Chapter 1 NEURONS OF THE CENTRAL VISUAL SYSTEM THE CORTEX AND LATERAL GENICULATE BODY Progressive development of the cerebral cortex in mammals in the course of evolution takes place through many interdependent processes. The surface area of the cortex is increased by the formation of fissures and gyri. The fissures and gyri are formed as a result of an increase in the number of neurons and of their long processes forming the white matter. The mass of white matter is increased, particularly on account of association pathways, and this in turn is connected with an increase in the number of pyramidal cells in the cortex. Considerable differentiation takes place in the cortex, with the appearance of new areas and subareas and their corresponding new connections, for thousands of association, commissural, and projection fibers arise from every point of the cortex. As the brain develops, and increases in complexity in response to adaptation to the external environment, the num ber of layers in the cortex changes. Changes in the architectonics of the brain and in the structure of its layers are a manifestation of neuronal speciali zation corresponding to the areas and lobes of the brain. Within the limits of the visual system, differences are found in cortical structure depending on the level of development of the nervous system and the state of visual function. It must also be emphasized that this process of progressive development does not take place equally at all levels of the visual system. The extremely fine specialization of the eyes of many fish (Detwiler, 1955) and the fine differentiation of the retina in many birds are well known. The accurate swoop of a predatory bird from a height while seeking food, and the precise coordination of vision with movements and vestibular responses are charac teristic of vision in birds. It is not surprising that in many vertebrates the eye is larger than the brain (Fig. 1); at lower levels of evolution the peripheral 1 2 Chapter 1 h to bo h--+-'. ... Fig. 1. Relative size of the eye and brain in some vertebrates, mammals, and man. A: 1, fish; 2, frog; 3, lizard (monitor); 4, bird (fowl); to, tectum opticum; bo, bulbus oculi; t, telencephalon; h, hemisphere. Neurons of the Central Visual System 3 Fig. 1. (Continued) B: 1, rabbit; 2, dog; 3, marmoset (lateral surface of hemisphere); 4, macaque; 5, man (sagittal section through skull and hemisphere). Remainder of legend as in A. (Zvorykin and Shkol'nik-Yarros, 1953.)