Pattern of Development of the Callosal Transfer of Visual Information to Cortical Areas 17 and 18 in the Cat

Milleret, Chantal; Houzel, Jean-Christophe; Buser, P

doi:10.1111/j.1460-9568.1994.tb00261.x

Cited by 38 publications

(39 citation statements)

References 49 publications

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“…This conclusion is comparable to conclusions reached in similar studies on areas 17 and 18 (Berlucchi and Rizzolatti, 1968;Lepore and Guillemot, 1982;Lepore etal., 1992;Milleret, 1994), 19 (Antonini et at., 1985;Guillemot et al, 1993) and the suprasylvian regions (Antonini et al, 1983), attesting to the apparent similarity of receptive field properties for gross spatial features (receptive field size, orientation and directional selectivities, position, etc.) derived from these two routes of activation.…”

Section: Functional Implicationsmentioning

confidence: 96%

Spatial Resolution and Contrast Sensitivity of Single Neurons in Area 19 of Split‐chiasm Cats: A Comparison With Primary Visual Cortex

Tardif¹,

Richer²,

Bergeron³

et al. 1997

Eur J of Neuroscience

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Electrophysiological recordings were carried out in the callosal recipient zone of area 19 in normal and split-chiasm cats and, for comparison purposes, at the border of areas 17 and 18 of split-chiasm cats. The influences of retinothalamic and callosal inputs on a single cortical neurons were thereby evaluated. Extracellular recordings of single cells were made in anaesthetized and paralysed cats in the zone representing the central visual field. Receptive field properties were assessed using sine wave gratings drifting in optimal directions. Results showed that in area 19 and areas 17/18 one-third of the cells were binocularly driven after section of the optic chiasm. In area 19, the spatial resolution and contrast sensitivity of cells driven via the dominant eye were similar in the normal and split-chiasm groups. In areas 17/18 and area 19 of split-chiasm cats, binocular cells showed significant interocular matching of their receptive field properties (spatial resolution and contrast threshold), although small differences were observed. These small interocular differences were related to the cell's ocular dominance rather than to the signal transmission route (thalamic or callosal).

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Section: Functional Implicationsmentioning

confidence: 96%

Spatial Resolution and Contrast Sensitivity of Single Neurons in Area 19 of Split‐chiasm Cats: A Comparison With Primary Visual Cortex

Tardif¹,

Richer²,

Bergeron³

et al. 1997

Eur J of Neuroscience

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show abstract

“…the midline, but that this may not happen to the same degree in areas that are involved primarily with pattern recognition and high-acuity vision. It is unclear whether the biased topographies appear gradually, as a result of postnatal development (e.g., by a process of ''pruning'' of afferents similar to that described for callosal connections; Milleret et al, 1994), or are genetically ''preprogrammed'' by natural selection. Future studies aimed at defining the timetable of postnatal development of the flying fox visual system may be relevant to this question, given that these animals do not start to fly until the second or third postnatal month.…”

Section: Biased Representation Of the Visual Fieldmentioning

confidence: 98%

Topographic organisation of extrastriate areas in the flying fox: Implications for the evolution of mammalian visual cortex

Rosa

1999

J. Comp. Neurol.

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“…Recordings from split-chiasm cats indicated, in addition to matched orientation between thalamic and callosal afferents, a precise correspondence of retinotopic position, as evidenced by the high degree of receptive field overlap, which increases progressively with normal binocular experience (10). This was compatible with the classic view that callosal connections perform a point-to-point topographic mapping between corresponding loci located in symmetric regions of the two hemispheres, and thereby contribute to the construction of receptive fields in the vicinity of the vertical midline.…”

Section: Functional Implications Of the Topographic Divergence Of Calmentioning

confidence: 99%

“…b) Extensive receptive field mapping of the 17/18 border, confirming earlier recordings from the fibers running within the posterior part of the corpus callosum (8), indicates that the callosally connected parts of visual areas include, on each side, the representation of the vertical midline together with a narrow portion of the ipsilateral hemifield (7). c) Recordings from split-chiasm cats, in which the geniculocortical and transcallosal pathways can be differentially activated by visual stimulation of one or the other eye, reveal that ipsi-and contralateral inputs converging onto callosal recipient neurons are closely matched in terms of retinotopic location, size, and orientation selectivity (9,10). d) Taken as a whole, these and other observations suggest that, indeed, callosal projections are functionally equivalent to corticocortical projections, being only longer-reaching (1,6).…”

Section: Introductionmentioning

confidence: 99%

Interhemispheric connections between primary visual areas: beyond the midline rule

Houzel

Carvalho

Lent

2002

Braz J Med Biol Res

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In the last five years, a number of detailed anatomical, electrophysiological, optical imaging and simulation studies performed in a variety of non-human species have revealed that the functional organization of callosal connections between primary visual areas is more elaborate than previously thought. Callosal cell bodies and terminals are clustered in columns whose correspondence to features mapped in the visual cortex, such as orientation and ocularity, are starting to be understood. Callosal connections are not restricted to the vertical midline representation nor do they establish merely point-to-point retinotopic correspondences across the hemispheres, as traditionally believed. In addition, anatomical studies have revealed the existence of an ipsilateral component of callosal axons. The aim of this short review is to propose how these new data can be integrated into an updated scheme of the circuits responsible for assembling the primary visual field map. Correspondence

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Pattern of Development of the Callosal Transfer of Visual Information to Cortical Areas 17 and 18 in the Cat

Cited by 38 publications

References 49 publications

Spatial Resolution and Contrast Sensitivity of Single Neurons in Area 19 of Split‐chiasm Cats: A Comparison With Primary Visual Cortex

Spatial Resolution and Contrast Sensitivity of Single Neurons in Area 19 of Split‐chiasm Cats: A Comparison With Primary Visual Cortex

Topographic organisation of extrastriate areas in the flying fox: Implications for the evolution of mammalian visual cortex

Interhemispheric connections between primary visual areas: beyond the midline rule

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