Maria Gabriella Buzzi

Trigeminal sensory fiber stimulation induces morphological changes reflecting secretion in rat dura mater mast cells

Mast cells are involved in allergic reactions, but may also participate in neurogenic inflammation. The morphology of mast cells in rat dura mater and tongue was evaluated by histochemistry, as well as by scanning and transmission electron microscopy following unilateral trigeminal ganglion stimulation (5 min, 5 Hz, 5 ms, and 0.02, 0.1 or 1.0 mA). Mast cells in dura and tongue of normal animals were numerous, perivascular and often in close proximity to nerve fibers. After 5 min of electrical stimulation, mast cells contralateral to the stimulation showed histochemical characteristics of normal peripheral tissue mast cells (Safranin-positive), and by electron microscopy appeared homogeneous with numerous intact electron-dense granules. On the stimulated side, however, the staining characteristics of mast cells showed changes indicating progressive intracellular loss of their granular content. In addition, the total number of stainable mast cells decreased at all three stimulus intensities, but reached significance only at 0.1 and 0.02 mA. Ultrastructural evidence of granule changes consistent with secretion were observed although degranulation was not observed until 20 min after stimulation. There were no mast cell changes after electrical trigeminal stimulation in adult rats treated as neonates with capsaicin to destroy small caliber sensory afferent axons. These results suggest that mast cells may secrete in response to electrical stimulation of trigeminal axons, possibly mediated by antidromic release of neuropeptides, and may participate in the development of neurogenic inflammation.

Ultrastructural evidence for neurogenically mediated changes in blood vessels of the rat dura mater and tongue following antidromic trigeminal stimulation

We investigated the effects of unilateral electrical trigeminal ganglion stimulation (0.1 or 1.0 mA, 5 Hz, 5 ms, 5 min) on the morphology of blood vessels within the rat dura mater and tongue using light and transmission electron microscopy. Stimulation at both intensities caused changes which were confined to the ipsilateral post-capillary venules except in the tongue where arterioles were affected as well. Changes were more marked after 1.0 mA. Dramatic increases in the numbers of endothelial pinocytotic vesicles were found along the luminal and abluminal surfaces ipsilateral to the stimulation. Tight junctions remained largely intact, except that injected ferritin particles were occasionally trapped inside these junctions. Cytoplasmic microvilli and endothelial blebs were sometimes present as well. Approximately 80% of the examined dural post-capillary venules showed one or more of these endothelial changes. Horseradish peroxidase injected intravenously 5 min prior to stimulation was detected in the extracellular space surrounding dural blood vessels and within pinocytotic vesicles. Ferritin injected similarly, was also localized in post-capillary venule walls, interstitial spaces, intraendothelial vesicles and in vacuoles. Platelet accumulation and aggregation were present in approximately 10% of post-capillary venules in dura and tongue. These changes were associated with mast cell secretion, but neither vascular nor mast cell activation was observed in adult rats in whom C-fibers were destroyed during the neonatal period with capsaicin. The present observations provide morphological evidence which supports findings from previously reported albumin tracer studies suggesting enhanced transport and endothelial activation following electrical stimulation of small caliber afferent fibers.

Evidence for 5‐HT1B/1D receptors mediating the antimigraine effect of sumatriptan and dihydroergotamine

Neurogenic plasma extravasation, endothelial cell activation (increase in vesicle number and vacuole formation), platelet aggregation and adhesion, and mast cell degranulation occur selectively in postcapillary venules of the dura mater following electrical trigeminal ganglion stimulation, and are mediated by release of neuropeptides from perivascular unmyelinated C fibres. Pre-treatment with the antimigraine drugs dihydroergotamine and sumatriptan, two drugs that bind with high affinity to 5-HT1B/1D receptors, markedly attenuated plasma protein extravasation induced by electrical trigeminal ganglion stimulation. Trigeminal stimulation increased plasma calcitonin gene-related peptide levels in rat superior sagittal sinus. Pre-treatment with dihydroergotamine and, to a lesser extent, sumatriptan, attenuated this increase. Both drugs reduced morphological changes in post-capillary venules and mast cells within dura mater following electrical trigeminal ganglion stimulation. Plasma protein extravasation was selectively blocked in dura mater (but not in extracranial tissues) by pre-treatment with those receptor agonists showing a rank order of potency suggesting a 3-HT1B/1D interaction (5-CT > 5-BT > DHE > sumatriptan > 8-OH-DPAT). Pre-treatment with 5-HT2 and 5-HT3 antagonists was not effective. Taken together, these data are consistent with the interpretation that putative 5-HT-1B/1D receptors located on sensory fibres are coupled to inhibition of peptide release and blockade of neurogenic inflammation. An important therapeutic action of ergot alkaloids and sumatriptan in migraine headaches is so defined.

The pathophysiology of migraine: year 2005

Migraine is a complex patholophysiology in which both central and peripheral components of the trigeminal pain pathway probably play a significant role, both in the symptoms and signs of the attack and in the mechanisms of action of antimigraine compounds, such as triptans, which constitute the most important therapy for aborting migraine pain and posses several mechanisms on 5–HT receptor–mediated actions. The experimental neurogenic inflammation model represents a simple procedure to obtain preliminary information on well characterized receptortargeted drugs. The apparent paradox observed with certain drugs that are shown to be effective in this model but not in clinical trials offers the opportunity to better manipulate structure–activity to obtain the best pharmacological profile using an array of experimental models. The observation that nitric oxide donors induce migraine–like pain in migraineours and that nitric oxide plays a pivotal role in the control of several functions in the central nervous system, has prompted the use of such molecules for better understanding the pathophysiology of migraine attacks. A link between central and peripheral components of the trigeminal pain pathway is provided by the observation that cortical spreading depression in the rat activates trigeminovascular afferents and induces a series of cortical meningeal and brainstem events consistent with the development of headache. Studies in humans support the hypothesis that cortical spreading depression underlies migraine.aura. Therefore, tt is possible that visual, motor or sensory aura might be responsible for the generation of the pain through the above mechanisms

Familial basilar migraine associated with a new mutation in the ATP1A2 gene

Basilar migraine (BM), familial hemiplegic migraine (FHM), and sporadic hemiplegic migraine (SHM) are phenotypically similar subtypes of migraine with aura, differentiated only by motor symptoms, which are absent in BM. Mutations in CACNA1A and ATP1A2 have been found in FHM. The authors detected a novel mutation in the ATP1A2 gene (R548H) in members of a family with BM, suggesting that BM and FHM may be allelic disorders.

Neuroeffector functions of sensory fibres: implications for headache mechanisms and drug actions

SummaryThe results of recent investigations designed to elucidate the neuroeffector functions of sensory fibres, the cause of migraine headache and the mechanism of action of antimigraine drugs are reviewed and discussed. Neurogenic inflammation (vasodilatation and neurogenic plasma extravasation) is one explanation for the development of headaches and the blood flow changes which occur during migraine headache. Numerous studies have recently been carried out on rats and guinea-pigs into the effects of antimigraine agents, including ergot alkaloids, sumatriptan and non-steroidal anti-inflammatory drugs (NSAIDs), on neurogenic plasma protein extravasation in the dura mater induced by electrical stimulation of trigeminal ganglia or systemic administration of capsaicin. It is known that the dura mater is able to produce headaches in man. Ergot alkaloids have been shown to block neurogenic inflammation via a C-fibre dependent neuronal mechanism. Sumatriptan appears to act fairly similarly although, whereas the ergot alkaloids are non-selective for either 5-hydroxytryptamine (5-HT; serotonin) receptors or 5-HT1, sumatriptan is selective for 5-HT1 receptors. The antimigraine action of NSAIDs may be via either an effect on blood vessels or an effect on the nerve fibre. The antimigraine effects of ergot alkaloids, sumatriptan and NSAIDs are discussed in the light of the common vasoconstrictor actions of these agents and knowledge that vasodilatation is apparently not responsible for migraine headache pain in most cases.

Dopamine hypersensitivity in migraine : Role of the apomorphine test

We investigated the effects of apomorphine administration at two different doses (2-10 micrograms/kg, s.c.) in 35 migraineurs in headache-free period and in 20 age-matched healthy control subjects, with and without pretreatment with domperidone. Neither patients or controls complained of headache at either dose, whereas at the dose of 10 micrograms/kg migraineurs showed a statistically significant higher incidence of dopaminergic symptoms (nausea, vomiting, drowsiness, yawning, dizziness, sweating) than controls. Furthermore, symptoms due to postsynaptic dopamine receptors activation (i.e., nausea and vomiting) only appeared in migraineurs. No symptom, however, resembled those characterizing a spontaneous migraine attack. In conclusion, migraineurs show a lower threshold for dopamine receptor activation than normal subjects.

Electrophysiological evidence for trigeminal neuron sensitization in patients with migraine

The electrically elicited corneal reflex is a useful tool for exploring the trigeminal system in humans and it may provide additional evidence pointing to a dysfunction of this system in migrainous patients. Tactile perception, corneal reflex and pain thresholds were studied in 48 migraine without aura patients during pain-free periods and compared with those observed in 24 controls. Twenty-eight of the patients had strictly unilateral headache, while the other 20 had bilateral or side-shifting pain during attacks. Both migraine subgroups (bilateral and unilateral) showed significantly lower thresholds compared with controls. The lowest values were observed on the symptomatic side of unilateral migraine patients. These findings suggest that sensorimotor mechanisms and/or pain control systems at the trigeminal level are impaired in migraine. The bilateral location of these abnormalities seems to point to a centrally located dysfunction.

A Novel ATP1A2 Mutation in a Family with FHM Type II

Familial hemiplegic migraine (FHM) is a rare subtype of migraine with aura with an autosomal dominant pattern of inheritance. Six FHM families underwent extensive clinical and genetic investigation. The authors identified a novel ATP1A2 mutation (E700K) in three patients from one family. In the patients, attacks were triggered by several factors including minor head trauma. In one subject a 3-day coma developed after a cerebral angiography. Overall, the phenotype of the patients closely resembles that of previously reported cases of FHM type II. The E700K variant might be regarded as the cause of the disease in this family, but this was not tested functionally.

Shortened cortical silent period in facial muscles of patients with migraine

Abstract Despite intensive neurophysiological research, evidence is lacking to show whether abnormal cortical excitability in migraine reflects a primary cortical disturbance or reduced control by thalamo‐cortical loops. One way to contribute to the scientific discussion on this topic is to deliver transcranial magnetic stimulation (TMS) and test the cortical silent period (SP) recorded in facial muscles. The facial‐muscle SP is a purely cortical phenomenon that reflects the excitability of inhibitory interneurons, and can disclose changes in cortical inhibition even in patients without documented primary lesions of the motor cortices. To test the interictal excitability of cortical motor inhibitory interneurons in migraine, we investigated the facial‐SP in patients with migraine with and without aura between attacks. In 26 patients and 15 age‐matched controls, high‐intensity magnetic stimuli were delivered with a round coil centered at the vertex during a maximal muscle contraction. Electromyographic responses were recorded from surface electrodes placed over the subjects’ perioral muscles. Facial SPs were significantly shorter in patients than in controls. The SP shortening provides neurophysiological evidence showing hypoexcitability of cortical inhibitory neurons in patients with migraine between attacks. Despite a possible primary deficit of cortical inhibitory interneurons in migraine, we favor the interpretation of a secondary disfacilitation by hypoactive thalamo‐cortical loops. Based on this interpretation, the interictal reduced cortical inhibition documented by the shortened SP could be considered the motor counterpart of the reduced preactivation excitability level in the sensory cortices purported to explain why cortical evoked responses habituate poorly in patients with migraine.