Experimental brain research. Experimentelle Hirnforschung. Expérimentation cérébrale
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Interactions between proprioceptive and vestibular inputs contributing to the generation of balance corrections may vary across muscles depending on the availability of sensory information at centres initiating and modulating muscle synergies, and the efficacy with which the muscle action can prevent a fall. Information which is not available from one sensory system may be obtained by switching to another. Alternatively, interactions between sensory systems and the muscle to which this interaction is targeted may be fixed during neural development and not switchable. ⋯ The disparity between the amplitudes of stretch reflex and automatic balance-correcting responses in triceps surae and the insignificant alteration in the timing of balance-correcting responses in these muscles with nulled ankle inputs indicates that ankle inputs do not trigger balance corrections. Furthermore, modulation of balance corrections normally performed by vestibular inputs in some but not all muscles is not achieved by switching to another sensory system on vestibular loss. We postulate that a confluence of trunk and upper-leg proprioceptive input establishes the basic timing of automatic, triggered balance corrections which is then preferentially weighted by vestibular modulation in muscles that prevent falling. (ABSTRACT TRUNCATED)
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Lattice-like perineuronal accumulations of extracellular-matrix proteoglycans have been shown to develop during postnatal maturation and to persist throughout life as perineuronal nets (PNs) in many brain regions. However, the dynamics of their reorganization in adults are as yet unknown. The aim of the present study was to examine the capability of PNs for reconstitution after experimental destruction and to search for possible consequences of extracellular-matrix degradation for neurons and glial cells. ⋯ In contrast to such transient changes, a diffuse chondroitin-sulphate proteoglycan immunoreactivity persisted in the neuropil. Loss of neurons or alterations of their structure as well as reactions of glial cells were not observed. We conclude from this study that PNs, enzymatically destroyed in the adult rat brain, can be completely reconstituted, but the restoration of their extracellular-matrix components needs several months.
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We investigated the ability of a novel direct current (DC) polarization technique to block selectively the conduction in peripheral myelinated nerve fibers and allowing propagation in only unmyelinated fibers. In anesthetized adult rats, distal branches of the sciatic nerve (caudal cutaneous sural and tibial nerves) were exposed for electrical stimulation of A- and C-fibers. Two specially fabricated trough electrodes of different size and surface area were placed onto the sciatic nerve. ⋯ These experiments demonstrate that anodally focused DC polarization, applied utilizing two trough electrodes of different sizes, is capable of effectively, reversibly, and reproducibly blocking conduction in myelinated A-fibers evoked either electrically or naturally, while still allowing conduction to occur in the unmyelinated C-fiber population. In the context of experimental usage, we have demonstrated blocking of low-threshold A-fiber, but not C-fiber, mediated inputs to the caudal brainstem. This technique should find wide application in studies involving the processing of information conveyed centrally by the unmyelinated C-fiber afferent population, including discriminating afferent responses to peripheral stimuli, the role of C-fiber input in reflex activity, and the plasticity following injury or other manipulations.