Abstract
Macroscopic features such as volume, surface estimate, thickness and caudorostral length of the human primary visual cortex (Brodman's area 17) of 46 human brains between midgestation and 93 years were studied by means of camera lucida drawings from serial frontal sections. Individual values were best fitted by a logistic function from midgestation to adulthood and by a regression line between adulthood and old age. Allometric functions were calculated to study developmental relationships between all the features. The three-dimensional shape of area 17 was also reconstructed from the serial sections in 15 cases and correlated with the sequence of morphological events. The sulcal pattern of area 17 begins to develop around 21 weeks of gestation but remains rather simple until birth, while it becomes more convoluted, particularly in the caudal part, during the postnatal period. Until birth, a large increase in cortical thickness (about 83% of its mean adult value) and caudorostral length (69%) produces a moderate increase in cortical volume (31%) and surface estimate (40%) of area 17. After birth, the cortical volume and surface undergo their maximum growth rate, in spite of a rather small increase in cortical thickness and caudorostral length. This is due to the development of the pattern of gyrification within and around the calcarine fissure. All macroscopic features have reached the mean adult value by the end of the first postnatal year. With aging, the only features to undergo significant regression are the cortical surface estimate and the caudorostral length. The total number of neurons in area 17 shows great interindividual variability at all ages. No decrease in the postnatal period or in aging could be demonstrated.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ang LC, Munoz DG, Shul D, George DH (1991) SMI-32 immunoreactivity in human striate cortex during postnatal development. Dev Brain Res 61:103–109
Antal M, Kraftsik R, Szekely G, Van der Loos H (1992) Synapses on motoneurons dendrites in the brachial section of the frog spinal cord: a computer-aided electron microspcopic study of cobalt-filled cells. J Neurocytol 21:34–49
Antonelli PL (1985) Mathematical essays on growth and the emergence of form. The University of Alberta Press, Edmonton, Alberta, Canada, pp 45–49
Atkinson J (1984) Human visual development over the first 6 months of life. A review and a hypothesis. Hum Neurobiol 3:61–74
Atkinson J (1992) Early visual development: differential functioning of parvocellular and magnocellular pathways. Eye 6:129–135
Becker LE, Armstrong DL, Chan F, Wood MM (1984) Dendritic development in human occipital cortical neurons. Dev Brain Res 13:117–124
Bertoni-Freddari C, Fattoretti P, Casoli T, Meier-Ruge W, Ulrich J (1990) Morphological adaptative response of the synaptic junctional zones in the human dentate gyrus during aging and Alzheimer's disease. Brain Res 517:69–75
Bourgeois J-P, Rakic P (1993) Changes of synaptic density in the primary visual cortex of the macaque monkey from fetal to adult stage. J Neurosci 13/7:2801–2820
Brodman K (1918) Individuelle Variationen der Sehsphäre und ihre Bedeutung für die Klinik der Hinterhauptschüsse. AllgZ Psychiatr (Berlin) 74:564–568
Clarke S, Miklossy J (1990) Occipital cortex in man: organization of callosal connections, related myelo- and cytoarchitecture, and putative boundaries of functional visual areas. J Comp Neurol 298:188–214
Coleman PD, Buell SJ (1985) Regulation of dendritic extent in developing and aging brain. In: Cotman CW (ed) Synaptic plasticity. Guilford Press, New York, pp 311–333
Coleman PD, Flood DG (1987) Neuron numbers and dendritic extent in normal aging and Alzheimer's disease. Neurobiol Aging 8:521–545
Curcio CA, Allen KA (1990) Topography of ganglion cells in human retina. J Comp Neurol 300:5–25
Devaney KO, Johnson HA (1980) Neuron loss in the aging visual cortex of man. J Gerontol 35/6:836–841
Dow BM, Vautin RG, Bauer R (1985) The mapping of visual space onto foveal striate cortex in the macaque monkey. J Neurosci 5/4:890–902
Fahle M, Palm G (1983) Calculation of surface areas from serial sections. J Neurosci Methods 9:75–85
Fisken RA, Garey LJ, Powell TPS (1973) The intrinsic, association and commissural connections of area 17 of the visual cortex. Philos Trans R Soc Lond Biol 272:487–536
Haug H (1985) Are neurons of the human cerebral cortex really lost during aging? a morphometric examination. In: Traber J, Gispen WH (eds) Senile dementia of the Alzheimer type. Springer, Berlin Heidelberg New York, pp 150–163
Haug H, Barmwater U, Eggers R, Fischer D, Kühl S, Sass N-L (1983) Anatomical changes in aging brain: morphometric analysis of the human prosencephalon. In: Cervos-Navarro J, Sarkander H-I (eds) Brain aging: neuropathology and neuropharmacology. Aging, vol 21. Raven Press, New York, pp 1–12
Haug H, Kühl S, Mecke E, Sass N-L, Wasner K (1984) The significance of morphometric procedures in the investigation of age changes in cytoarchitectonic structures of human brain. J Hirnforsch 25:353–374
Hickey TL, Guillery RW (1979) Variability of laminar patterns in the human lateral geniculate nucleus. J Comp Neurol 183:221–246
Holmes G (1917) Disturbances of vision by cerebral lesions. Br J Ophthalmol 2:353–384
Holmes G, Lister WT (1916) Disturbances of vision from cerebral lesions with special reference to the cortical representation of the macula. Brain 39:34–73
Hornung J-P, Kraftsik R (1988) Three-dimensional reconstruction procedure using GKS primitives and software transformations for anatomical studies of the nervous system. In: Magnenat-Thalmann N, Thalmann D (eds) New trends in computer graphics. Springer, Berlin Heidelberg New York, pp 555–564
Horton JC, Hoyt WF (1991) The representation of the visual field in human striate cortex. Arch Ophthalmol 109:816–824
Horton JC, Hedley-White ET (1984) Mapping of cytochrome oxidase patches and ocular dominance columns in human visual cortex. Philos Trans R Soc Lond Biol 304:255–272
Horton JC, Dagi LR, McCrane EP, De Monasterio FM (1990) Arrangement of ocular dominance columns in human visual cortex. Arch Ophtalmol 108:1025–1031
Huttenlocher PR, De Courten C (1987) The development of synapses in striate cortex of man. Hum Neurobiol 6:1–9
Huttenlocher PR, De Courten C, Garey LJ, Van der Loos H (1982) Synaptogenesis in human visual cortex — evidence for synapse elimination during normal development. Neurosci Lett 33:247–252
Klekamp J, Riedel A, Harper C, Kretschmann HJ (1989) Morphometric study on the postnatal growth of non-cortical brain regions in Australian Aborigenes and Causasians. Brain Res 485:79–88
Klekamp J, Riedel A, Harper C, Kretschmann H-J (1991) Quantitative changes during the postnatal maturation of the human visual cortex. J Neurol Sci 103/2:136–143
Kline DW, Schieber F (1985) Vision and aging. In: Birren JE, Schaie KW (eds) Handbook of the psychology of aging. Van Nostrand Reinhold, New York, pp 296–331
Kretschmann H-J, Schleicher A, Wingert F, Zilles K, Löblich H-J (1979) Human brain growth in the 19th and 20th century. J Neurol Sci 40:169–188
Le Gros Clark WE, Sunderland S (1939) Structural changes in the isolated visual cortex. J Anat 73:563–574
Leuba G, Garey LJ (1987) Evolution of neuronal numerical density in the developing and aging human visual cortex. Hum Neurobiol 6:11–18
Leuba G, Garey LJ (1989) Comparison of neuronal and glial numerical density in primary and secondary visual cortex of man. Exp Brain Res 77:31–38
Leuba G, Kraftsik R (1994) Visual cortex in Alzheimer's disease: occurrence of neuronal death and glial proliferation, and correlation with pathological hallmarks. Neurobiol Aging 15:29–43
Lintl P, Braak H (1983) Loss of intracortical myelinated fibers: a distinctive age-related alteration in the human striate area. Acta Neuropathol 61:178–182
Marquardt DW (1963) An algorithm for least squares estimation of nonlinear parameters. J Soc Industr Appl Math 11:431–441
Michel AE, Garey LJ (1984) The development of dendritic spines in the human visual cortex. Hum Neurobiol 3:223–227
Missler M, Eins S, Merker H-J, Rothe H, Wolff JR (1993) Pre- and postnatal development of the primary visual cortex of the common marmoset. I. A changing space for synaptogenesis. J Comp Neurol 333:41–52
Mohn G, Van Hof-Van Duin J (1986) Development of the binocular and monocular visual fields of human infants during the first year of life. Clin Vision Sci 1:51–64
Murphy GM (1985) Volumetric asymmetry in the human striate cortex. Exp Neurol 88:288–302
O'Kusky J, Colonnier M (1982) Postnatal changes in the number of neurons and synapses in the visual cortex (area 17) of the macaque monkey: a stereological analysis in normal and monocularly deprived animals. J Comp Neurol 210:291–306
Provis JM (1987) Patterns of cell death in the ganglion cell layer of the human fetal retina. J Comp Neurol 259:237–246
Provis JM, Van Driel D, Billson FA, Russell P (1985) Human fetal optic nerve: overperoduction and elimination of retinal axons during development. J Comp Neurol 238:92–100
Purves D, Lamantia A (1993) Development of blobs in the visual cortex of macaques. J Comp Neurol 334:169–175
Putnam TJ (1926) Studies on the central visual connections. III. The general relationships between the external geniculate body, optic radiation and visual cortex in man. Report of two cases. Arch Neurol Psychiatry 16:566–596
SAS Institute (1989) SAS/STAT User's Guide, vol 1. SAS, Cary, NC, pp 1–943
SAS Institute (1990) SAS/GRAPH Software: reference, vol 1. SAS, Cary, NC, pp 1–794
Sauer B, Kammradt G, Krauthausen I, Kretschmann H-J, Lange HW, Wingert F (1983) Qualitative and quantitative development of the visual cortex in man. J Comp Neurol 214:441–450
Stanley OH (1991) Cortical development and visual function. Eye 5:27–30
Stensaas SS, Eddington DK, Dobelle WH (1974) The topography and variability of the primary visual cortex in man. J Neurosurg 4:747–755
Takashima S, Chan F, Becker LE, Armstrong DL (1980) Morphology of the developing visual cortex of the human infant. A quantitative and qualitative Golgi study. Neuropathol Exp Neurol 39:487–501
Teller DY, Movshon JA (1986) Visual development. Vision Res 26/9:1483–1506
Uylings HBM, Van Edden CG, Hofman MA (1986) Morphometry of size/volume variables and comparison of their bivariate relations in the nervous system under different conditions. J Neurosci Methods 18:19–37
Van Essen DC, Newsome WT, Maunsell JHR (1984) The visual field representation in striate cortex of the macaque monkey: asymmetries, anisotropies, and individual variability. Vision Res 24:429–448
William RW, Rakic P (1988) Elimination of neurons from the rhesus monkey's lateral geniculate nucleus during development. J Comp Neurol 272:424–436
Wong-Riley MTT, Hevner RF, Cutlan R, Earnest M, Egan R, Frost J, Nguyen T (1993) Cytochrome oxidase in the human visual cortex: distribution in the developing and the adult human brain. Vis Neurosci 10:41–58
Zilles K, Werners R, Büsching U, Schleicher A (1986) Ontogenesis of the laminar structure in areas 17 and 18 of the human visual cortex. Anat Embryol 174:339–353
Zilles K, Armstrong E, Schleicher A, Kretschmann H-J (1988) The human pattern of gyrification in the cerebral cortex. Anat Embryol 179:173–179
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Leuba, G., Kraftsik, R. Changes in volume, surface estimate, three-dimensional shape and total number of neurons of the human primary visual cortex from midgestation until old age. Anat Embryol 190, 351–366 (1994). https://doi.org/10.1007/BF00187293
Accepted:
Issue date:
DOI: https://doi.org/10.1007/BF00187293