The blood-spinal cord barrier (BSCB) is the functional equivalent of the blood-brain barrier (BBB) in the sense of providing a specialized microenvironment for the cellular constituents of the spinal cord. Even if intuitively the BSCB could be considered as the morphological extension of the BBB into the spinal cord, evidence suggests that this is not so. The BSCB shares the same principal building blocks with the BBB; nevertheless, it seems that morphological and functional differences may exist between them. Dysfunction of the BSCB plays a fundamental role in the etiology or progression of several pathological conditions of the spinal cord, such as spinal cord injury, amyotrophic lateral sclerosis, and radiation-induced myelopathy. This review summarizes current knowledge of the morphology of the BSCB, the methodology of studying the BSCB, and the potential role of BSCB dysfunction in selected disorders of the spinal cord, and finally summarizes therapeutic approaches to the BSCB.
The aim of this study was to test whether environmental enrichment alters the status and responsiveness of pituitary-adrenocortical and sympathetic-adrenomedullary hormones in rats. Previous studies have shown that rats kept in an enriched environment differ from those kept in standard cages in dendritic branching, synaptogenesis, memory function, emotionality and behaviour. In male Wistar rats kept in an enriched environment for 40 days, we studied basal concentrations of hormones, endocrine responses to 5-HT(1A) challenge and responsiveness and adaptation to repeated handling. Environmental enrichment consisted of large plexiglass cages with 10 rats per cage, which contained variety of objects exchanged three times a week. Rats kept in this enriched environment had higher resting plasma concentrations of corticosterone, larger adrenals and increased corticosterone release to buspirone challenge compared to controls. Lower adrenocorticotropic hormone, corticosterone and adrenaline responses to handling were noticed in rats kept in an enriched environment. Exposure to repeated handling led to a more rapid extinction of corticosterone responses in rats kept in an enriched environment. Thus, environmental enrichment leads to pronounced changes in neuroendocrine regulation, including larger adrenals and increased adrenocortical function, which are so far considered to be indication of chronic stress.
Stress-induced release of corticotropin-releasing factor (CRF) and vasopressin (AVP) was studied in rats by measuring the decline of CRF and AVP stores in the median eminence after blockade of fast axonal transport with colchicine (5 µg per rat intracisternally). Quantitative immunocytochemistry was used to detect changes in CRFi and AVPi in the external zone of the median eminence (ZEME) selectively. Immobilization stress induced a fast ACTH response to 1,000–2,000 pg/ml which was associated with a fall in both CRF and AVPi of 34% during the first 30 min. This is followed by different time courses of further AVPi and CRFi depletion. In additon, we investigated the effect of repeated daily stress exposure on CRFi and AVPi in the ZEM 1 day after stress exposure. Repeated daily immobilization for 9 or 16 subsequent days did not affect the CRFi stores in the ZEME, but increased the AVPi stores to 161 ± 13% and 218 ± 11% respectively. Quantitative analysis of electron microphotographs of repeatedly handled rats showed a mean density of CRF positive profiles in the ZEME of 45.5 ± 2.5 per 500 µm2 of which 25% also stained for pro-AVP-derived peptides. After 9 subsequent days of immobilization the total density of CRF-positive profiles remained unchanged, but the fraction of CRF swellings that also stained for pro-AVP-derived peptides increased approximately 2-fold. We conclude that (1) the secretion of AVPi and CRFi from the ZEME are independently controlled, indicating differential activation of AVP containing and AVP deficient CRF neurons during acute immobilization, and (2) repeated stress leads to plastic changes in hypothalamic CRF neurons resulting in increased AVP stores and colocalization in CRF nerve terminals.
Though oxytocin and vasopressin are similar in structure and are produced in the same brain regions, they show specific responses under stress conditions. In humans, increases in peripheral blood vasopressin appear to be a consistent finding during many acute stress situations, while in rats, vasopressin secretion is unresponsive to several stimuli known to induce ACTH and catecholamine release. Even decreases in vasopressin levels during stress were described. In accordance with others, we observed enhanced vasopressin release in response to stress stimuli with an osmotic component such as hypertonic saline injection but also during exposure of rats to a warm environment. Immobilization stress which fails to induce vasopressin release was reported to increase hypothalamic vasopressin mRNA and plasma vasopressin levels in chronically adreno-demedullated rats. Unlike vasopressin, oxytocin may be considered a typical stress hormone responding to osmotic as well as other stress stimuli. We found that acute exposure of rats to immobilization stress resulted in an increase in oxytocin mRNA level. In addition, we have shown that magnocellular neurons of the paraventricular nucleus, but not the supraoptic nucleus, are essential for oxytocin release during immobilization stress. The release of posterior pituitary hormones represents an important component of the stress response.
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