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Notes: Abstract  The density of substance P (SP)-, calcitonin gene-related peptide (CGRP)- and vasoactive intestinal polypeptide (VIP)-immunoreactive (ir) nerve endings was quantitatively evaluated in intact and inflamed gastrocnemius-soleus muscle of the rat. In persistently inflamed muscle (12 days after a single injection of Freund’s adjuvant into the muscle), the density of SP-ir fibres was significantly increased. CGRP- and VIP-ir fibres displayed an insignificant increase in density. The density of fibres ir for nerve growth factor (NGF) and for growth-associated protein 43 (GAP-43/B-50), a marker for axonal sprouting, regeneration and synaptic reorganisation, increased significantly in persistently inflamed muscle. The data are consistent with the established contribution of NGF on the expression of SP and GAP-43 in afferent neurones under the influence of a persistent inflammation.

Notes: Summary In eleven hemispheres of nine marmoset monkeys (Callithrix jacchus), we have investigated the thalamo-cortical organization of the projections from the pulvinar to the striate and prestriate cortex. In each experiment, single or multiple injections of various retrograde fluorescent tracers were injected into adjacent regions or areas. In two experiments, horseradish peroxidase (HRP) was injected into the lateral geniculate nucleus (LGN) and the lateral pulvinar, respectively. The results show that the thalamo-cortical projection from LGN to striate cortex and from pulvinar to the prestriate cortex are similarly organized, but the geniculo-striate projection is more precise than the pulvinar-prestriate projection. The pulvinar-prestriate projection is topographically organized and preserves topological neighbourhood relations. Projection zones to the various visual areas are concentrically wrapped around each other. The projection zone to area 18 constitutes a central core region. It begins ventro-laterally in PuL where the pulvinar is in contact with the LGN. This contact zone we called the hilus region of the pulvinar. The area 18-projection zone stretches as a central cone into the posterior pulvinar through PuL and into PuM. It is surrounded by the projection zone to the posterior belt of area 19 and this in turn is surrounded by the projection zone to the anterior belt of area 19. The projection zones to area 19 are then surrounded medially and dorsally by zones projectiong to the temporal and parietal association cortex, respectively. The projection zone to area MT is located medio-ventrally in the posterior pulvinar (PuIP and surrounding nuclei) and coincides with a densely myelinated region. Area 17 also receives input from the pulvinar but probably predominantly in the region of the central visual field. The pulvinar zone projecting to area 17 is located ventrolaterally from the central core region projecting to area 18 and is contiguous laterally with the LGN. If the positions of the vertical and the horizontal meridian in the pulvinar correspond to those in the respective cortical projection zones, a second order visual field representation such as found in area 18, with the horizontal meridian split at an excentricity of about 7–10°, can also be recognized in the pulvinar.

Notes: Summary In the common marmoset (Callithrix jacchus), the cortical projection from the pulvinar and other diencephalic structures into the striate and prestriate cortex was investigated with various fluorescent retrograde tracers. Single cortical injections as well as multiple injections at distances of 1–2 mm with one tracer into an extended but coherent cortical region were applied. Fields with multiple injections were placed so that they touched each other (minimal distances 2 to 3 mm). Retrogradely labelled cells in the LGN and/or the pulvinar were arranged in coherent columns, volumes or slabs, but cell volumes resulting from neighbouring cortical injections overlapped at their border (for details of the thalamo-cortical topography see the companion paper Dick et al. (1991)). Double labelled cells (dl) were only found in the zones of overlap of the cell volumes labelled by the respective tracers. The relative number of dl-cells in these overlap zones was 6.2 ± 3.1%. The dl-frequency was the same in the various nuclei of the pulvinar and the LGN. In the main layers of LGN, dl-cells were found only in the overlap zone of two injection fields into area 17, but a few dl-cells were found in interlaminar cells after injections into area 17 and 18. Maximal cortical distances between injection fields which produced dl in the pulvinar, were 3 to exceptionally 4 mm but dl was highest at injection distances ≤2.5 mm and decreased sharply at wider distances. Such overlap zones were concerned with identical or overlapping regions of visual field representation in the cortex and probably also in the pulvinar. Although in individual experiments up to four different tracers were injected into different striate/prestriate regions, often embracing the same visual field representation, individual cells in the pulvinar showed dl from maximally only two tracers injected into neighbouring cortical regions. We conclude that dl in the posterior thalamic projection nuclei is determined essentially by cortical distance and thus reflects the local domain of branching of thalamo-cortical afferents. Pruning of such branches during development may further restrict bifurcating axons to identical visual field representations, but representation of identical visual field regions in different visual areas is not, per se, a sufficient condition for dl. It is not found if such regions are further apart from each other than the typical local domain of 2–3 mm, exceptionally up to 4 mm in one experiment after injections into area 17 and MT. Dl in the intralaminar nucleus CeL (5.0 ± 4.6%), the claustrum (5.4 ± 3.6%) and in the amygdala (5.7 ± 1.9%) was of the same order as in the pulvinar and LGN. In the hypothalamus around 10% and in the Nucleus basalis Meynert 15.8% of the cells labelled by visual cortical injections were double labelled. In all these extrathalamic regions dl was also restricted to overlap zones, but overlap of labelled fields in these nuclei was much wider and included the whole striate/prestriate cortex except for some topographical separation of striate and prestriate projection zones in the claustrum. Only in the Nucl. basalis Meynert and the hypothalamus some cells were labelled by three tracers.

Notes: Abstract In recent years, the regulation of the synthesis of nitric oxide (NO) in the central nervous system has attracted much interest because it has been shown that NO is involved in a wide variety of functions such as neuroprotection, neurotoxicity, neurotransmission, and neuroplas- ticity under physiological and pathophysiological conditions. However, the use of different detection techniques for neuronal nitric oxide synthase (nNOS), different animal species, and different experimental lesions has led to contradictory results concerning the direction of changes in spinal nNOS expression. This paper summarizes the available data on the expression on nNOS in the spinal cord under physiological and pathological conditions and tries to extract some of the basic mechanisms that underlie neuronal up- or downregulation of this enzyme. Wherever possible, results obtained with the NADPH-dependent diaphorase reaction are also included for reasons of comparison. The main conclusion is that changes in spinal nNOS expression critically depend on the type of afferent fibres activated by a specific lesion as well as the intensity and duration of input to the spinal cord. This input may be further modified by supraspinal influences. Thus the exact composition of these factors, which is undoubtfully highly variable between different experimental models, appears to determine whether the spinal NO system responds with an up- or downregulation of nNOS expression or in a bidirectional way. With regard to the diaphorase reaction it is becoming increasingly clear that under pathological conditions data obtained with this reaction differ markedly from those obtained with immunohistochemical visualization of nNOS.