Analysis of the postnatal growth of visual cortex

Duffy, Kevin R.; Murphy, Kathryn; Jones, David

doi:10.1017/s0952523898155049

Cited by 29 publications

(33 citation statements)

References 28 publications

(45 reference statements)

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“…for fixed R. On the basis of the experimental work of Duffy et al (1998), who showed that between postnatal weeks 3 and 6 cat V1 undergoes a uniform expansion in which it approximately doubles in size, we assume that the growth is slow and isotropic. It should be noted that our extension of the Swindale model is formulated in terms of the normalized synaptic density n = (n L − n R )/N where N = n L + n R is the fixed total density at each point in cortex.…”

Section: Developmental Model On a Growing Domainmentioning

confidence: 99%

“…In the case of cats (and ferrets), ocular dominance columns can be visualized at a very early postnatal stage (Crowley and Katz, 2000;Crair et al, 2001), during which the cortex is still undergoing significant growth. Indeed, Duffy et al (1998) have shown that the surface area of adult cat V1 is more than double that of 1-week-old kittens, with the shape of V1 remaining unaltered. Although ocular dominance columns in macaque are fully formed at birth, the macaque brain undergoes a much smaller degree of postnatal growth (around 16%) (Purves and LaMantia, 1993).…”

Section: Introductionmentioning

confidence: 97%

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A Developmental Model of Ocular Dominance Column Formation on a Growing Cortex

Oster

Bressloff

2006

Bltn. Mathcal. Biology

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We derive an activity-based developmental model of ocular dominance column formation in primary visual cortex that takes into account cortical growth. The resulting evolution equation for the densities of feedforward afferents from the two eyes exhibits a sequence of pattern forming instabilities as the size of the cortex increases. We use linear stability analysis to investigate the nature of the transitions between successive patterns in the sequence. We show that these transitions involve the splitting of existing ocular dominance (OD) columns, such that the mean width of an OD column is approximately preserved during the course of development. This is consistent with recent experimental observations of postnatal growth in cat.

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Section: Developmental Model On a Growing Domainmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

A Developmental Model of Ocular Dominance Column Formation on a Growing Cortex

Oster

Bressloff

2006

Bltn. Mathcal. Biology

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“…In cat, the neocortical volume increases from ≈1000mm 3 at birth to ≈4500mm 3 in adulthood [2]. Consistently, the surface area of cat primary visual cortex (V1) increases postnatally by a factor of 2.5 between week 1 and week 12 [3]. This size increase implies that the distance between any two neuronal cell bodies grows on average by a factor of 1.6 during postnatal development.…”

Section: Introductionmentioning

confidence: 95%

Reorganization of columnar architecture in the growing visual cortex

Keil

Schmidt

Löwel

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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Many cortical areas increase in size considerably during postnatal development, progressively displacing neuronal cell bodies from each other. At present, little is known about how cortical growth affects the development of neuronal circuits. Here, in acute and chronic experiments, we study the layout of ocular dominance (OD) columns in cat primary visual cortex during a period of substantial postnatal growth. We find that despite a considerable size increase of primary visual cortext, the spacing between columns is largely preserved. In contrast, their spatial arrangement changes systematically over this period. Whereas in young animals columns are more band-like, layouts become more isotropic in mature animals. We propose a novel mechanism of growth-induced reorganization that is based on the "zigzag instability," a dynamical instability observed in several inanimate pattern forming systems. We argue that this mechanism is inherent to a wide class of models for the activity-dependent formation of OD columns. Analyzing one representative of this class, the Elastic Network model, we show that this mechanism can account for the preservation of column spacing and the specific mode of reorganization of OD columns that we observe. We conclude that column width is preserved by systematic reorganization of neuronal selectivities during cortical expansion and that this reorganization is well described by the zigzag instability. Our work suggests that cortical circuits may remain plastic for an extended period in development to facilitate the modification of neuronal circuits to adjust for cortical growth.cortical growth | ocular dominance columns | postnatal development | critical period | zigzag instability

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“…Only a few studies describe differences in the size, shape and locations of cortical areas across a population of individuals. Differences have been described in the size and shape of primary visual cortex in humans, macaques, cats, rats and mice, the consensus being that V1 differs in size more than in shape (Van Essen, Newsome & Maunsell, 1984;Duffy, Murphy & Jones, 1998;Hinds et al, 2008;Garrett et al, 2014). Necessarily, comparisons were across small numbers (<25) of individuals and no attempt was made to determine whether the differences resulted from differing organization of cortex across individuals (biological variation) or simply measurement error (noise).…”

Section: Introductionmentioning

confidence: 99%

Biological variation in the sizes, shapes and locations of visual cortical areas in the mouse

Waters

Lee

Gaudreault

et al. 2018

Preprint

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Visual cortex is organized into discrete sub-regions or areas that are arranged into a hierarchy and serve different functions in the processing of visual information. In our previous work, we noted that retinotopic maps of cortical visual areas differed between mice, but did not quantify these differences or determine the relative contributions of biological variation and measurement noise. Here we quantify the biological variation in the size, shape and locations of 11 visual areas in the mouse. We find that there is substantial biological variation in the sizes of visual areas, with some visual areas varying in size by two-fold across the population of mice.

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Analysis of the postnatal growth of visual cortex

Cited by 29 publications

References 28 publications

A Developmental Model of Ocular Dominance Column Formation on a Growing Cortex

A Developmental Model of Ocular Dominance Column Formation on a Growing Cortex

Reorganization of columnar architecture in the growing visual cortex

Biological variation in the sizes, shapes and locations of visual cortical areas in the mouse

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