Cortical GABAergic Interneurons in Cross-Modal Plasticity following Early Blindness

Early loss of a given sensory input in mammals causes anatomical and functional modifications in the brain via a process called cross-modal plasticity. In the past four decades, several animal models have illuminated our understanding of the biological substrates involved in cross-modal plasticity. Progressively, studies are now starting to emphasise on cell-specific mechanisms that may be responsible for this intermodal sensory plasticity. Inhibitory interneurons expressing γ-aminobutyric acid (GABA) play an important role in maintaining the appropriate dynamic range of cortical excitation, in critical periods of developmental plasticity, in receptive field refinement, and in treatment of sensory information reaching the cerebral cortex. The diverse interneuron population is very sensitive to sensory experience during development. GABAergic neurons are therefore well suited to act as a gate for mediating cross-modal plasticity. This paper attempts to highlight the links between early sensory deprivation, cortical GABAergic interneuron alterations, and cross-modal plasticity, discuss its implications, and further provide insights for future research in the field

Assymétries cérébrales lors de traitement de l’information visuelle rapide : investigations chez une population clinique et neurologiquement saine

Le phénomène de Clignement Attentionnel (Attentional Blink, AB), fait référence à une diminution transitoire du rapport exact d’une deuxième cible (C2) si celle-ci est présentée trop tôt après une première cible (C1) lors d’une présentation visuelle sérielle rapide (rapid serial visual presentation, RSVP), et ce, quand les deux cibles doivent être rapportées. Cette étude a examiné l’existence possible d’asymétries hémisphèriques dans le traitement attentionnel ainsi que l’éventualité que la présentation de cibles à deux hémisphères différents puisse diminuer le AB chez des participants neurologiquement sains et l’abolir dans le cas d’un patient callosotomisé. Pour ce faire, nous avons employé un paradigme modifié du AB dans lequel les cibles pouvaient apparaître dans n’importe quelle de quatre RSVP, une dans chaque quadrant du champ visuel, pour permettre des essais dans lesquels les deux cibles puissent être présentées au même hémisphère et d’autres où chaque cible était présentée à un hémisphère différent. Bien que nous n’ayons trouvé aucune diminution de l’effet AB lors de présentation inter-hémisphérique, dans les deux populations à l’étude, le taux de bonnes réponses globales à la deuxième cible était plus élevé quand les cibles étaient présentées à des hémisphères différents. Nous avons également trouvé un avantage de l’hémisphère gauche chez le patient callosotomisé.The Attentional Blink (AB) refers to a transient impairment in the accurate report of a second target (T2) if it closely follows the presentation of a first target (T1) in a rapid serial visual presentation (RSVP), when both targets must be reported. This study investigated both the possibility of hemispheric asymmetries of attentional processes as well as the possibility that presenting targets to different hemispheres could diminish the AB in neurologically intact participants and abolish it in the case of a split-brain patient. To do so, a modified AB paradigm was used in which targets could appear in any of four simultaneous RSVP streams, one in each quadrant of the visual field, so as to have trials in which both targets were presented to the same hemispheres and trials in which targets were presented to different hemispheres. Although no evidence of a diminished AB was observed by presenting targets to separate hemispheres, in both neurologically intact individuals and the split-brain patient, overall accuracy was higher when targets were presented to separate hemispheres. A left hemisphere advantage was only observed in the split-brain patient

The Connectivity of the Human Pulvinar: A Diffusion Tensor Imaging Tractography Study

Previous studies in nonhuman primates and cats have shown that the pulvinar receives input from various cortical and subcortical areas involved in vision. Although the contribution of the pulvinar to human vision remains to be established, anatomical tracer and electrophysiological animal studies on cortico-pulvinar circuits suggest an important role of this structure in visual spatial attention, visual integration, and higher-order visual processing. Because methodological constraints limit investigations of the human pulvinar's function, its role could, up to now, only be inferred from animal studies. In the present study, we used an innovative imaging technique, Diffusion Tensor Imaging (DTI) tractography, to determine cortical and subcortical connections of the human pulvinar. We were able to reconstruct pulvinar fiber tracts and compare variability across subjects in vivo. Here we demonstrate that the human pulvinar is interconnected with subcortical structures (superior colliculus, thalamus, and caudate nucleus) as well as with cortical regions (primary visual areas (area 17), secondary visual areas (area 18, 19), visual inferotemporal areas (area 20), posterior parietal association areas (area 7), frontal eye fields and prefrontal areas). These results are consistent with the connectivity reported in animal anatomical studies

Enhanced chemosensory detection of negative emotions in congenital blindness

It is generally acknowledged that congenitally blind individuals develop superior sensory abilities in order to compensate for their lack of vision. Substantial research has been done on somatosensory and auditory sensory information processing of the blind. However, relatively little information is available about compensatory plasticity in the olfactory domain. Although previous studies indicate that blind individuals have superior olfactory abilities, no studies so far have investigated their sense of smell in relation to social and affective communication. The current study compares congenitally blind and normal sighted individuals in their ability to discriminate and identify emotions from body odours. A group of 14 congenitally blind and 14 age- and sex-matched sighted control subjects participated in the study. We compared participants’ abilities to detect and identify by smelling sweat from donors who had been watching excerpts from emotional movies showing amusement, fear, disgust, or sexual arousal. Our results show that congenitally blind subjects outperformed sighted controls in identifying fear from male donors. In addition, there was a strong tendency that blind individuals were also better in detecting disgust. Our findings reveal that congenitally blind individuals are better at identifying ecologically important emotions and provide new insights into the mechanisms of social and affective communication in blindness

Are supramodality and cross-modal plasticity the yin and yang of brain development? From blindness to rehabilitation

Research in blind individuals has primarily focused for a long time on the brain plastic reorganization that occurs in early visual areas. Only more recently, scientists have developed innovative strategies to understand to what extent vision is truly a mandatory prerequisite for the brain’s fine morphological architecture to develop and function. As a whole, the studies conducted to date in sighted and congenitally blind individuals have provided ample evidence that several ‘visual’ cortical areas develop independently from visual experience and do process information content regardless of the sensory modality through which a particular stimulus is conveyed: a property named supramodality. At the same time, lack of vision leads to a structural and functional reorganization within 'visual' brain areas, a phenomenon known as cross-modal plasticity. Cross-modal recruitment of the occipital cortex in visually deprived individuals represents an adaptative compensatory mechanism that mediates processing of non-visual inputs. Supramodality and cross-modal plasticity appear to be the 'yin and yang' of brain development: supramodal is what takes place despite the lack of vision, whereas cross-modal is what happens because of lack of vision. Here we provide a critical overview of the research in this field and discuss the implications that these novel findings have for the development of educative/rehabilitation approaches and sensory substitution devices in sensory-impaired individuals

The Endocannabinoid System in the Vervet Monkey Retina

The main active compound found in the marijuana plant, tetrahydrocannabinol, is responsible for its psychotropic effects but also for its numerous beneficial actions such as appetite stimulation, nausea reduction, analgesia, and muscle spasm suppressor. Although cannabis consumption leads to some visual disturbances, the exact role of the endocannabinoid system (ECS) in normal vision is still unknown. Many studies have looked into the localization of this complex system (receptors, ligands, and enzymes) throughout the various components of the visual system of different animal models in order to obtain clues about its role. In fact, the retina, optic nerve, dorsal lateral geniculate nucleus, and visual cortices all express parts of the ECS. Manipulating this system pharmacologically or genetically has also an impact on visual function. In this book chapter, we provide the current understanding of how the ECS is involved in the functioning of the visual system and special emphasis is put on data obtained in monkeys, representing the most relevant animal model for visual neuroscience research. The mechanisms that control endocannabinoid (eCB) release and activation of cannabinoid receptors are discussed. We also propose a model highlighting the mechanisms involved in the regulation of photopic and scotopic vision taking advantage of the spatial specificity of the eCB signaling system and its physiological activation conditions