BackgroundMigraine is a paroxysmal, disabling primary headache that affects 16 % of the adult population. In spite of decades of intense research, the origin and the pathophysiology mechanisms involved are still not fully known. Although triptans and gepants provide effective relief from acute migraine for many patients, their site of action remains unidentified. It has been suggested that during migraine attacks the leakiness of the blood-brain barrier (BBB) is altered, increasing the passage of anti-migraine drugs. This study aimed to investigate the effect of experimental inflammation, following dural application of complete Freund’s adjuvant (CFA) or inflammatory soup (IS) on brain and trigeminal microvascular passage.MethodsIn order to address this issue, we induced local inflammation in male Sprague-Dawley-rats dura mater by the addition of CFA or IS directly on the dural surface. Following 2, 24 or 48 h of inflammation we calculated permeability-surface area product (PS) for [51Cr]-EDTA in the trigeminal ganglion (TG), spinal trigeminal nucleus, cortex, periaqueductal grey and cerebellum.ResultsWe observed that [51Cr]-EDTA did not pass into the central nervous system (CNS) in a major way. However, [51Cr]-EDTA readily passed the TG by >30 times compared to the CNS. Application of CFA or IS did not show altered transfer constants.ConclusionsWith these experiments we show that dural IS/CFA triggered TG inflammation, did not increase the BBB passage, and that the TG is readily exposed to circulating molecules. The TG could provide a site of anti-migraine drug interaction with effect on the trigeminal system.Electronic supplementary materialThe online version of this article (doi:10.1186/s10194-015-0575-8) contains supplementary material, which is available to authorized users.
All tested substances with the exception of VIP and carbachol have been found to elicit migraine-like attacks in migraineurs. Since these two agents have vasodilatory effects in humans, it suggests that vasodilatation is not the only reason for eliciting a migraine-like attack in migraineurs. In addition, there are significant species differences that show the importance of performing experiments in human vessels.
BackgroundMigraine attacks occur spontaneously in those who suffer from the condition, but migraine-like attacks can also be induced artificially by a number of substances. Previously published evidence makes the meninges a likely source of migraine related pain. This article investigates the effect of several vasodilators on meningeal arteries in order to find a connection between the effect of a substance on a meningeal vessel and its ability to artificially induce migraine.MethodsA myograph setup was used to test the vasodilator properties of the substances acetylcholine (ACh), sodium nitroprusside (SNP), sildenafil, prostaglandin E2 (PGE2), pituitary adenylate cyclase activating peptide-38 (PACAP-38), calcitonin gene-related peptide (CGRP) and NaCl buffer on meningeal arteries from human and rat. An unpaired t-test was used to statistically compare the mean Emax(%) at the highest concentration of each substance to the Emax(%) of NaCl buffer.ResultsIn the human experiments, all substances except PACAP-38 had an Emax (%) higher than the NaCl buffer, but the difference was only significant for SNP and CGRP. For the human samples, clinically tested antimigraine compounds (sumatriptan, telcagepant) were applied to the isolated arteries, and both induced a significant decrease of the effect of exogenously administrated CGRP. In experiments on rat middle meningeal arteries, pre-contracted with PGF2α, similar tendencies were seen. When the pre-contraction was switched to K+ in a separate series of experiments, CGRP and sildenafil significantly relaxed the arteries.ConclusionsStill no definite answer can be given as to why pain is experienced during an attack of migraine. No clear correlation was found between the efficacy of a substance as a meningeal artery vasodilator in human and the ability to artificially induce migraine or the mechanism of action. Vasodilatation could be an essential trigger, but only in conjunction with other unknown factors. The vasculature of the meninges likely contributes to the propagation of the migrainal cascade of symptoms, but more research is needed before any conclusions can be drawn about the nature of this contribution.
The transfer of albumin from blood to tissue has been found to be increased in caveolin-1 knockout (KO) mice. This has been considered to reflect increased microvascular permeability, conceivably caused by an increased endothelial production of nitric oxide (NO) in these mice. To investigate whether such an increase in NO production would also affect glomerular barrier characteristics, the glomerular sieving coefficients (theta) to neutral FITC-Ficoll 70/400 (molecular radius 13-90 A) were determined in caveolin-1 KO mice vs. their wild-type counterparts. The theta for Ficoll were assessed using high-performance size-exclusion chromatography on blood and urine samples. Furthermore, the transcapillary escape rate (TER) of (125)I-labeled albumin and plasma volume (PV) were determined in both types of mice. The kidney expressed low levels of caveolin-1 compared with the lung and bladder, but immunofluorescence associated with vascular structures was evident. Staining was lost in the caveolin-1 KO kidney, as was caveolin-1 expression in the lung and bladder. Despite an increase in the glomerular filtration rate in caveolin-1 KO mice (0.23 +/- 0.04 vs. 0.10 +/- 0.02 ml/min; both n = 7; P < 0.05), the glomerular Ficoll sieving curves were nearly identical. Furthermore, caveolin-1 KO mice showed an increased PV (6.59 +/- 0.42 vs. 5.18 +/- 0.13 ml/100 g; P < 0.01) but only a tendency toward an increased TER (14.69 +/- 1.59 vs. 11.62 +/- 1.62%/h; not significant). It is concluded that in caveolin-1 KO mice the glomerular permeability was not increased, despite the presence of glomerular hyperfiltration. The present data are in line with the concept that the increased transvascular albumin leakage previously found in mice lacking caveolin-1 may be due to an elevation in systemic microvascular pressure due to precapillary vasodilatation, rather than being a consequence of increased microvascular permeability per se.
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