NO-induced migraine attack: Strong increase in plasma calcitonin gene-related peptide (CGRP) concentration and negative correlation with platelet serotonin release

The aim of the present study was to investigate changes in the plasma calcitonin gene-related peptide (CGRP) concentration and platelet serotonin (5-hydroxytriptamine, 5-HT) content during the immediate headache and the delayed genuine migraine attack provoked by nitroglycerin. Fifteen female migraineurs (without aura) and eight controls participated in the study. Sublingual nitroglycerin (0.5 mg) was administered. Blood was collected from the antecubital vein four times: 60 min before and after the nitroglycerin application, and 60 and 120 min after the beginning of the migraine attack (mean 344 and 404 min; 12 subjects). In those subjects who had no migraine attack (11 subjects) a similar time schedule was used. Plasma CGRP concentration increased significantly ðP , 0:01Þ during the migraine attack and returned to baseline after the cessation of the migraine. In addition, both change and peak, showed significant positive correlations with migraine headache intensity ðP , 0:001Þ: However, plasma CGRP concentrations failed to change during immediate headache and in the subjects with no migraine attack. Basal CGRP concentration was significantly higher and platelet 5-HT content tended to be lower in subjects who experienced a migraine attack. Platelet serotonin content decreased significantly ðP , 0:01Þ after nitroglycerin in subjects with no migraine attack but no consistent change was observed in patients with migraine attack. In conclusion, the fact that plasma CGRP concentration correlates with the timing and severity of a migraine headache suggests a direct relationship between CGRP and migraine. In contrast, serotonin release from platelets does not provoke migraine, it may even counteract the headache and the concomitant CGRP release in this model

Hepatic insulin sensitizing substance: a novel ‘sensocrine' mechanism to increase insulin sensitivity in anaesthetized rats

1. We recently described the sensory nitrergic nature of the hepatic insulin sensitizing substance (HISS) mechanism linked to postprandial activation of anterior hepatic plexus fibres in rabbits. This study is designed to assess the involvement of the sensory pathways in this mechanism. 2. Selective sensory denervation of the anterior hepatic plexus (AHP) was achieved by a 3-day perineurial treatment with 2% capsaicin solution in Wistar rats (230–250 g). After 1 week, hyperinsulinaemic (100 μU kg(−1)) euglycaemic (5.5 mmol kg(−1)) glucose clamp studies were performed to estimate insulin sensitivity. 3. The rats with regional AHP sensory denervation exhibited a significantly decreased insulin sensitivity, that is, 9.1±1.0 mg kg(−1) min(−1) glucose reinstalled euglycaemia vs 13.3±1.9 mg kg(−1) min(−1) glucose (P<0.01) in control rats. 4. Acute partial hepatic denervation by AHP cut was without effect on insulin sensitivity, whereas chronic hepatic denervation induced insulin resistance was similar to that achieved by regional AHP capsaicin treatment. 5. Intraportal administration of L-NAME (10 mg kg(−1)) decreased, whereas capsaicin (0.3 mg kg(−1) min(−1)) increased insulin sensitivity. Neither atropine (1 mg kg(−1)) nor acetylcholine (1–10 μg mg min(−1)) produced any significant effect. In animals with preceding regional capsaicin desensitization, none of the pharmacological manoeuvres modified the resulting insulin-resistant state. 6. Cysteamine (200 mg kg(−1) s.c.) is known to cause functional somatostatin depletion-induced insulin resistance similar to that produced by either chronic partial hepatic denervation or perineurial AHP capsaicin desensitization. Intraportal capsaicin (0.3 mg kg(−1) min(−1)) was unable to modify insulin resistance achieved by cysteamine. 7. We conclude that capsaicin-sensitive sensory fibres play a crucial role in neurogenic insulin sensitization known as the HISS mechanism without involvement of anatomical reflex-mediated circuits. The results also suggest that HISS is identical to somatostatin of AHP sensory neural origin