Although callosal connections have been shown to link extensive regions of primary visual cortex, the distribution of these connections with respect to the map of visual space and the map of orientation preference remains unclear. Here we combine optical imaging of intrinsic signals with injection of fluorescent microspheres to assess the functional specificity of callosal connections in the tree shrew. By imaging both hemispheres simultaneously while presenting a series of spatially restricted stimuli, we find that a substantial region of visual space is represented bilaterally. Each hemisphere includes a representation of the ipsilateral visual field that is highly compressed relative to that of the contralateral visual field and is most extensive in the lower visual field, where approximately 30(o) of central visual space are represented bilaterally. Callosal connections extend throughout the region of bilateral representation but terminate in a spatially restricted manner that links visuotopically corresponding sites in the two hemispheres. In contrast, callosal connections appear to terminate without regard for the map of orientation preference, showing little sign of the orientation-specific modular and axial specificity that is characteristic of long-range horizontal connections. By coordinating the activity in the two hemispheres in a way that preserves nearest neighbor relationships, callosal connections may best be viewed as elements of local circuits that operate within a single bilateral representation of visual space.
BackgroundThe basal forebrain (BF) regulates cortical activity by the action of cholinergic projections to the cortex. At the same time, it also sends substantial GABAergic projections to both cortex and thalamus, whose functional role has received far less attention. We used deep brain stimulation (DBS) in the BF, which is thought to activate both types of projections, to investigate the impact of BF activation on V1 neural activity.ResultsBF stimulation robustly increased V1 single and multi-unit activity, led to moderate decreases in orientation selectivity and a remarkable increase in contrast sensitivity as demonstrated by a reduced semi-saturation contrast. The spontaneous V1 local field potential often exhibited spectral peaks centered at 40 and 70 Hz as well as reliably showed a broad γ-band (30-90 Hz) increase following BF stimulation, whereas effects in a low frequency band (1-10 Hz) were less consistent. The broad γ-band, rather than low frequency activity or spectral peaks was the best predictor of both the firing rate increase and contrast sensitivity increase of V1 unit activity.ConclusionsWe conclude that BF activation has a strong influence on contrast sensitivity in V1. We suggest that, in addition to cholinergic modulation, the BF GABAergic projections play a crucial role in the impact of BF DBS on cortical activity.
The "all cone" retina of the tree shrew (Tupaia belangeri) was examined in the adult and early postnatal stages by light and electron microscopy. Rods are not as rare as previously thought, but make up about 4% of the photoreceptors. They are relatively short and narrow cells, which stain (toluidine blue) more intensively and lie more proximal than cones. Among the cones three morphological varieties could be distinguished. Most cones stain lightly but have a light or a dark giant mitochondrion in their inner segment; a third type stains darker but occurs only rarely. All cones possess extensive radial processes ("lateral fins") around the basal part of their inner segments. Such fins are well known from reptiles and birds, but have only once been described in a mammal (gray squirrel). The maturation of the retina in Tupaia belangeri proceeds centrifugally, i.e., from the vitreal to the scleral side, as in most mammals. A few synapses are already present at birth in the outer and inner plexiform layers, but seem to be more advanced in the latter. Such early synapses are small and have only few synaptic vesicles; they appear almost mature by day 14. The light-sensitive outer segments develop last. The first disks are seen by day 10, but regular membrane stacks are only present by day 18. Thus, it seems that the retina is functional when the young first open their eyes, which occurs around day 18.
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