Role of inferior temporal cortex in interhemispheric transfer

doi:10.1016/0006-8993(79)90821-7

Brain Research

Volume 167, Issue 2, 11 May 1979, Pages 259-272

https://doi.org/10.1016/0006-8993(79)90821-7 Get rights and content

Summary

Neurons in inferior temporal cortex of the rhesus monkey usually have large receptive fields that extend well across the midline into both visual half-fields. The responsiveness of these neurons to stimuli in the ipsilateral visual half-field depends on the splenium and anterior commissure, the same pathways necessary for interhemispheric transfer of visual habits. Since inferior temporal neurons have the same trigger features in both half-fields and are usually binocular, they may be the site of the interhemispheric neural convergence that underlies interhemispheric transfer. If so, bilateral removal of inferior temporal cortex should interfere with interhemispheric transfer even when the commissures are intact. To test this, monkeys were trained on pattern discriminations with one eye and then tested for transfer with the other eye. Five experimental monkeys received bilateral inferior temporal lesions and, to restrict input from each eye to one hemisphere, section of the optic chiasm. Ten controls received either bilateral temporal lesions alone, chiasm section alone or remained unoperated. Only the experimental animals showed impaired transfer. These results suggest that inferior temporal neurons mediate interhemispheric transfer by providing perceptual equivalence for patterns in the left and right visual fields, and by implication, perhaps also for patterns in different parts of the same field.

References (21)

GrossC.G. et al.
Contributions of the corpus callosum and the anterior commissure to the visual activation of inferior temporal neurons
Brain Research
(1977)
GrossC.G. et al.
The neural basis of stimulus equivalence across the retinal translation
MohlerC.W. et al.
Visual receptive fields of frontal eye field neurons
Brain Research
(1973)
AllmanJ.
Evolution of the visual system in the early primates
BerlucchiG. et al.
Effects of lesions of areas 17, 18 and 19 on interocular transfer of pattern discrimination in split-chiasm cats
Exp. Brain Res.
(1978)
BlackP. et al.
Visual function of the forebrain commissures in the chimpanzee
Science
(1964)
BruceC. et al.
Large visual receptive fields in a polysensory area in the superior temporal sulcus of the macaque
Neurosci. Abstr.
(1977)
DotyR.W. et al.
Forebrain commissures and vision
DownerJ.L. de C.
Interhemispheric integration in the visual system
GrossC.G.
Visual functions of inferotemporal cortex

There are more references available in the full text version of this article.

Cited by (17)

How position dependent is visual object recognition?
2008, Trends in Cognitive Sciences
Citation Excerpt :
However, IT has several characteristics that suggest minimal interhemispheric transfer in earlier areas. First, lesion studies suggest IT is necessary for interhemispheric transfer to occur [50,51] and transfer might be limited before IT [52]. Second, IT RFs are generally centered within the contralateral field and extend on average only 3° into the ipsilateral field [35,36,41] (Figure 2).
Visual object recognition is often assumed to be insensitive to changes in retinal position, leading to theories and formal models incorporating position-independent object representations. However, recent behavioral and physiological evidence has questioned the extent to which object recognition is position independent. Here, we take a computational and physiological perspective to review the current behavioral literature. Although numerous studies report reduced object recognition performance with translation, even for distances as small as 0.5 degrees of visual angle, confounds in many of these studies make the results difficult to interpret. We conclude that there is little evidence to support position-independent object recognition and the precise role of position in object recognition remains unknown.
Visuospatial processing and the right-hemisphere interpreter
2003, Brain and Cognition
Popular views of hemispheric asymmetry hold that the left hemisphere is specialized for linguistic and cognitive processes and fine motor control, whereas the right is specialized for visuospatial processing. Although this dichotomy contains more than a grain of truth, it is an oversimplification. Experiments with split-brain patients have demonstrated that the left hemisphere retains relatively sophisticated visuospatial abilities, and that the asymmetries that favor the right hemisphere are subtler than those that favor the left. A consideration of the constructive nature of visual perception, and the organization of the visual system in the two hemispheres suggests that asymmetries are likely to arise relatively late in visual processing in areas that represent both sides of visual space. I present evidence in favor of the view that the right hemisphere can be considered more “visually intelligent” than the left, and postulate the existence of a “right-hemisphere interpreter” dedicated to constructing a representation of the visual world.
fMRI activation in response to illusory contours and salient regions in the human Lateral Occipital Complex
2003, Neuron
Regions in the human Lateral Occipital Complex (LOC) show fMRI responses to illusory surfaces. We show that the LOC activation is due to the globally completed region and occurs even when the region is not bounded by illusory contours (ICs). Kanizsa-type stimuli were modified by rounding the corners of the “pacmen” inducers and misaligning them slightly. The impression of an enclosed, salient region (SR) remained, although ICs were no longer perceived (psychophysical data). fMRI activity was elevated for both the IC and SR stimuli, compared to their control stimuli. The LOC response to salient regions may be the result of fast but crude region-based segmentation processes, which are useful for selecting parts of cluttered images for more detailed, computationally intensive processing.
Chapter 3 Interhemispheric transfer of spatial and temporal frequency information
1997, Advances in Psychology
The contribution of the corpus callosum to receptive fields in the lateral suprasylvian visual areas of the cat
1982, Behavioural Brain Research
In both ordinary cats and ‘Boston’ Siamese cats the visual areas in the lateral parts of the middle and posterior suprasylvian gyri (LSA) contain an extensive representation of the ipsilateral half of the visual field. In addition, in both groups of cats the overwhelming majority of neurons in LSA can be driven from both eyes. In Siamese cats this binocular interaction is in marked contrast with what is found in area 17 where neurons are almost exclusively activated through the contralateral eye. Transection of the posterior $13$ to $12$ of the corpus callosum had a different effect on the physiological organization of LSA in the two types of cats. In ordinary cats it caused the loss of the ipsilateral hemifield representation in the eye ipsilateral to the side of recording and reduced this representation in the other eye. However, after the section of the corpus callosum LSA neurons remained binocular. In Siamese cats the callosal transection left the representation of the ipsilateral hemifield in LSA unaffected, but totally abolished the input from the ipsilateral eye. These findings suggest that the visual callosal input to LSA has a different functional significance in ordinary and Siamese cats. In the former cats it may be related to perceptual equivalence across the vertical meridian of the visual field, whereas in the latter cats it may subserve interocular equivalence.
Development of Interocular Equivalence of Place Learning in the Rat Requires Convergence Sites Established Prior to Training
1987, Behavioral Neuroscience

View all citing articles on Scopus

: Preliminary accounts of this study were presented at the 1975 Society for Neuroscience meeting, New York, N. Y. and the Conference on Lateralization in the Nervous System, April, 1975, Rutgers University, N. J.

View full text

Role of inferior temporal cortex in interhemispheric transfer

Summary

Brain Research

Brain Research

Evolution of the visual system in the early primates

Effects of lesions of areas 17, 18 and 19 on interocular transfer of pattern discrimination in split-chiasm cats

Exp. Brain Res.

Visual function of the forebrain commissures in the chimpanzee

Science

Large visual receptive fields in a polysensory area in the superior temporal sulcus of the macaque

Neurosci. Abstr.

Forebrain commissures and vision

Interhemispheric integration in the visual system

Visual functions of inferotemporal cortex