Abstract
We studied primary-somatosensory cortical plasticity due to selective stimulation of the sensory periphery by two procedures of active exploration in adult rats. Subjects, left with only three adjacent whiskers, were trained in a roughness discrimination task or maintained in a tactile enriched environment. Either training or enrichment produced 3-fold increases in the barrel cortex areas of behaviorally-engaged whisker representations, in their zones of overlap. While the overall areas of representation expanded dramatically, the domains of exclusive principal whisker responses were virtually identical in enriched vs normal rats and were significantly smaller than either group in roughness discrimination-trained rats. When animals were trained or exposed to enriched environments with the three whiskers arrayed in an are or row, very equivalent overlaps in representations were recorded across their greatly-enlarged whisker representation zones. This equivalence in distortion in these behavioral preparations is in contradistinction to the normal rat, where overlap is strongly biased only along rows, probably reflecting the establishment of different relations with the neighboring cortical columns. Overall, plasticity phenomena are argued to be consistent with the predictions of competitive Hebbian network plasticity.
Highlights
The general purpose of the present work was to study the functional reorganization of the primary somatosensory cortex (SI) generated by a sensory- perceptual learning task contrasted with SI plasticity driven by environmental sensory enrichment.Neuroscience is sharply focused on the determination of plastic events in the neocortex that underlie learning and memory
The selective stimulation of 3 vibrissae in a tactile enriched environment produced a 3to-4-fold increase in the cortical areas of their representation in SI
Our results confirm that behaviorally relevant stimulation was an important factor generating a large increase in cortical representation
Summary
The general purpose of the present work was to study the functional reorganization of the primary somatosensory cortex (SI) generated by a sensory- perceptual learning task contrasted with SI plasticity driven by environmental sensory enrichment.Neuroscience is sharply focused on the determination of plastic events in the neocortex that underlie learning and memory. The general purpose of the present work was to study the functional reorganization of the primary somatosensory cortex (SI) generated by a sensory- perceptual learning task contrasted with SI plasticity driven by environmental sensory enrichment. Evidence points to an important relevant role of primary cortices as memory loci, in contradistinction to the more traditional views that behavioral-driven changes may arise in association cortices. There has traditionally been a consensus about the essential stability of primary cortical maps representing the sensory periphery in adult subjects, in contrast to the great plasticity that characterized the developing nervous system. That conclusion has been challenged by a large number of studies showing that primary somatosensory cortical representations can be substantially remodeled following alterations of sensory inputs in adult
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