Vanessa Kainz

A neural mechanism for exacerbation of headache by light

The perception of migraine headache, which is mediated by nociceptive signals transmitted from the cranial dura mater to the brain, is uniquely exacerbated by exposure to light. We found that exacerbation of migraine headache by light is prevalent among blind individuals who maintain non–image-forming photoregulation in the face of massive rod/cone degeneration. Using single-unit recording and neural tract tracing in the rat, we identified dura-sensitive neurons in the posterior thalamus whose activity was distinctly modulated by light and whose axons projected extensively across layers I–V of somatosensory, visual and associative cortices. The cell bodies and dendrites of such dura/light-sensitive neurons were apposed by axons originating from retinal ganglion cells (RGCs), predominantly from intrinsically photosensitive RGCs, the principle conduit of non–image-forming photoregulation. We propose that photoregulation of migraine headache is exerted by a non–image-forming retinal pathway that modulates the activity of dura-sensitive thalamocortical neurons.

Activation of Meningeal Nociceptors by Cortical Spreading Depression: Implications for Migraine with Aura

Attacks of migraine with aura represent a phenomenon in which abnormal neuronal activity in the cortex produces sensory disturbances (aura) some 20–40 min before the onset of headache. The purpose of this study was to determine whether cortical spreading depression (CSD)—an event believed to underlie visual aura—can give rise to activation of nociceptors that innervate the meninges—an event believed to set off migraine headache. CSD was induced in anesthetized male rats by stimulation of the visual cortex with electrical pulses, pin prick, or KCl; single-unit activity of meningeal nociceptors was monitored in vivo in the rat before and after CSD. Regardless of the method of cortical stimulation, induction of CSD was recorded in 64 trials. In 31 of those trials, CSD induced a twofold increase in meningeal nociceptor firing rate that persisted for 37.0 ± 4.6 min in trials in which activity returned to baseline, or >68 min in trials in which activity remained heightened at the time recording was interrupted. In two-thirds of the trials, onset of long-lasting neuronal activation began ∼14 min after the wave of CSD. The findings demonstrates for the first time that induction of CSD by focal stimulation of the rat visual cortex can lead to long-lasting activation of nociceptors that innervate the meninges. We suggest that migraine with aura is initiated by waves of CSD that lead up to delayed activation of the trigeminovascular pathway.

Mast cell degranulation activates a pain pathway underlying migraine headache.

Abstract Intracranial headaches such as that of migraine are generally accepted to be mediated by prolonged activation of meningeal nociceptors but the mechanisms responsible for such nociceptor activation are poorly understood. In this study, we examined the hypothesis that meningeal nociceptors can be activated locally through a neuroimmune interaction with resident mast cells, granulated immune cells that densely populate the dura mater. Using in vivo electrophysiological single unit recording of meningeal nociceptors in the rat we observed that degranulation of dural mast cells using intraperitoneal administration of the basic secretagogue agent compound 48/80 (2 mg/kg) induced a prolonged state of excitation in meningeal nociceptors. Such activation was accompanied by increased expression of the phosphorylated form of the extracellular signal‐regulated kinase (pERK), an anatomical marker for nociceptor activation. Mast cell‐induced nociceptor interaction was also associated with downstream activation of the spinal trigeminal nucleus as indicated by an increase in c‐fos expression. Our findings provide evidence linking dural mast cell degranulation to prolonged activation of the trigeminal pain pathway believed to underlie intracranial headaches such as that of migraine.

Activation of central trigeminovascular neurons by cortical spreading depression

Cortical spreading depression (CSD) has long been implicated in migraine attacks that begin with visual aura. Having shown that a wave of CSD can trigger long‐lasting activation of meningeal nociceptors—the first‐order neurons of the trigeminovascular pathway thought to underlie migraine headache—we now report that CSD can activate central trigeminovascular neurons in the spinal trigeminal nucleus (C1–2).

Sensory innervation of the calvarial bones of the mouse.

Migraine sufferers frequently testify that their headache feels as if the calvarial bones are deformed, crushed, or broken (Jakubowski et al. [2006] Pain 125:286–295). This has lead us to postulate that the calvarial bones are supplied by sensory fibers. We studied sensory innervation of the calvaria in coronal and horizontal sections of whole‐head preparations of postnatal and adult mice, via immunostaining of peripherin (a marker of thinly myelinated and unmyelinated fibers) or calcitonin gene‐related peptide (CGRP; a marker more typical of unmyelinated nerve fibers). In pups, we observed nerve bundles coursing between the galea aponeurotica and the periosteum, between the periosteum and the bone, and between the bone and the meninges; as well as fibers that run inside the diploë in different orientations. Some dural fibers issued collateral branches to the pia at the frontal part of the brain. In the adult calvaria, the highest concentration of peripherin‐ and CGRP‐labeled fibers was found in sutures, where they appeared to emerge from the dura. Labeled fibers were also observed in emissary canals, bone marrow, and periosteum. In contrast to the case in pups, no labeled fibers were found in the diploë of the adult calvaria. Meningeal nerves that infiltrate the periosteum through the calvarial sutures may be positioned to mediate migraine headache triggered by pathophysiology of extracranial tissues, such as muscle tenderness and mild trauma to the skull. In view of the concentration of sensory fibers in the sutures, it may be useful to avoid drilling the sutures in patients undergoing craniotomies for a variety of neurosurgical procedures. J. Comp. Neurol. 515:331–348, 2009.

Cortical Projections of Functionally Identified Thalamic Trigeminovascular Neurons: Implications for Migraine Headache and Its Associated Symptoms

This study identifies massive axonal arbors of trigeminovascular (dura-sensitive) thalamic neurons in multiple cortical areas and proposes a novel framework for conceptualizing migraine headache and its associated symptoms. Individual dura-sensitive neurons identified and characterized electrophysiologically in first-order and higher-order relay thalamic nuclei were juxtacellularly filled with an anterograde tracer that labeled their cell bodies and processes. First-order neurons located in the ventral posteromedial nucleus projected mainly to trigeminal areas of primary (S1) as well as secondary (S2) somatosensory and insular cortices. Higher-order neurons located in the posterior (Po), lateral posterior (LP), and lateral dorsal (LD) nuclei projected to trigeminal and extra-trigeminal areas of S1 and S2, as well as parietal association, retrosplenial, auditory, ectorhinal, motor, and visual cortices. Axonal arbors spread at various densities across most layers of the different cortical areas. Such parallel network of thalamocortical projections may play different roles in the transmission of nociceptive signals from the meninges to the cortex. The findings that individual dura-sensitive Po, LP, and LD neurons project to many functionally distinct and anatomically remote cortical areas extend current thinking on projection patterns of high-order thalamic neurons and position them to relay nociceptive information directly rather than indirectly from one cortical area to another. Such extensive input to diverse cortical areas that are involved in regulation of affect, motor function, visual and auditory perception, spatial orientation, memory retrieval, and olfaction may explain some of the common disturbances in neurological functions during migraine.

Sensitization of central trigeminovascular neurons: blockade by intravenous naproxen infusion

We have previously observed that migraine attacks impervious to triptan therapy were readily terminated by subsequent i.v. administration of the non-steroidal anti-inflammatory drug (NSAID) ketorolac. Since such attacks were associated with periorbital allodynia--a symptom of central sensitization--we examined whether infusion of the NSAID naproxen can block sensitization of central trigeminovascular neurons in the medullary dorsal horn, using in vivo single-unit recording in the rat. Topical exposure of the cerebral dura to inflammatory soup (IS) for 5 min resulted in a short-term burst of activity (<8 min) and a long-lasting (>120 min) neuronal hyper-responsiveness to stimulation of the dura and periorbital skin (group 1). Infusion of naproxen (1 mg/kg) 2 h after IS (group 1) brought all measures of neuronal responsiveness back to the baseline values recorded prior to IS, and depressed ongoing spontaneous activity well below baseline. When given preemptively 1 h before IS (group 2), naproxen blocked the short-term burst of activity and every long-term measure of neuronal hyper-responsiveness that was studied in the central neurons. The same preemptive treatment, however, failed to block IS-induced short-term bursts of activity in C-unit meningeal nociceptors (group 3). The results suggest that parenteral administration of naproxen, unlike triptan therapy, can exert direct inhibition over central trigeminovascular neurons in the dorsal horn. Though impractical as a routine migraine therapy, parenteral NSAID administration should be useful as a non-narcotic rescue therapy for migraine in the setting of the emergency department.

Tumor necrosis factor-α induces sensitization of meningeal nociceptors mediated via local COX and p38 MAP kinase actions.

&NA; The proinflammatory cytokine TNF‐&agr; has been shown to promote activation and sensitization of primary afferent nociceptors. The downstream signaling processes that play a role in promoting this neuronal response remain however controversial. Increased TNF‐&agr; plasma levels during migraine attacks suggest that local interaction between this cytokine and intracranial meningeal nociceptors plays a role in promoting the headache. Here, using in vivo single unit recording in the trigeminal ganglia of anesthetized rats, we show that meningeal TNF‐&agr; action promotes a delayed mechanical sensitization of meningeal nociceptors. Using immunohistochemistry, we provide evidence for non‐neuronal localization of the TNF receptors TNFR1 to dural endothelial vascular cells and TNFR2 to dural resident macrophages as well as to some CGRP‐expressing dural nerve fibers. We also demonstrate that meningeal vascular TNFR1 is co‐localized with COX‐1 while the perivascular TNFR2 is co‐expressed with COX‐2. We further report here for the first time that TNF‐&agr; evoked sensitization of meningeal nociceptors is dependent upon local action of cyclooxygenase (COX). Finally, we show that local application of TNF‐&agr; to the meninges evokes activation of the p38 MAP kinase in dural blood vessels that also express TNFR1 and that pharmacological blockade of p38 activation inhibits TNF‐&agr; evoked sensitization of meningeal nociceptors. Our study suggests that meningeal action of TNF‐&agr; could play an important role in the genesis of intracranial throbbing headaches such as migraine through a mechanism that involves at least part activation of non‐neuronal TNFR1 and TNFR2 and downstream activation of meningeal non‐neuronal COX and the p38 MAP kinase.

Mast cell degranulation distinctly activates trigemino-cervical and lumbosacral pain pathways and elicits widespread tactile pain hypersensitivity

Mast cells (MCs) are tissue resident immune cells that participate in a variety of allergic and other inflammatory conditions. In most tissues, MCs are found in close proximity to nerve endings of primary afferent neurons that signal pain (i.e. nociceptors). Activation of MCs causes the release of a plethora of mediators that can activate these nociceptors and promote pain. Although MCs are ubiquitous, conditions associated with systemic MC activation give rise primarily to two major types of pain, headache and visceral pain. In this study we therefore examined the extent to which systemic MC degranulation induced by intraperitoneal administration of the MC secretagogue compound 48/80 activates pain pathways that originate in different parts of the body and studied whether this action can lead to development of behavioral pain hypersensitivity. Using c-fos expression as a marker of central nervous system neural activation, we found that intraperitoneal administration of 48/80 leads to the activation of dorsal horn neurons at two specific levels of the spinal cord; one responsible for processing cranial pain, at the medullary/C2 level, and one that processes pelvic visceral pain, at the caudal lumbar/rostral sacral level (L6-S2). Using behavioral sensory testing, we found that this nociceptive activation is associated with development of widespread tactile pain hypersensitivity within and outside the body regions corresponding to the activated spinal levels. Our data provide a neural basis for understanding the primacy of headache and visceral pain in conditions that involve systemic MC degranulation. Our data further suggest that MC activation may lead to widespread tactile pain hypersensitivity.

Hypothalamic and basal ganglia projections to the posterior thalamus: Possible role in modulation of migraine headache and photophobia

Migraine attacks are typically described as unilateral, throbbing pain that is usually accompanied by nausea, vomiting, and exaggerated sensitivities to light, noise and smell. The headache phase of a migraine attack is mediated by activation of the trigeminovascular pathway; a nociceptive pathway that originates in the meninges and carries pain signals through meningeal nociceptors to the spinal trigeminal nucleus and from there to the cortex through relay neurons in the thalamus. Recent studies in our lab have identified a population of trigeminovascular neurons in the posterior (Po) and lateral posterior (LP) thalamic nuclei that may be involved in the perception of whole-body allodynia (abnormal skin sensitivity) and photophobia (abnormal sensitivity to light) during migraine. The purpose of the current study was to identify sub-cortical areas that are in position to directly regulate the activity of these thalamic trigeminovascular neurons. Such process begins with anatomical mapping of neuronal projections to the posterior thalamus of the rat by performing discrete injections of the retrograde tracer Fluorogold into the Po/LP region. Such injections yielded retrogradely labeled neurons in the nucleus of the diagonal band of Broca, the dopaminergic cells group A11/A13, the ventromedial and ventral tuberomammillary nuclei of the hypothalamus. We also found that some of these neurons contain acetylcholine, dopamine, cholecystokinin and histamine, respectively. Accordingly, we speculate that these forebrain/hypothalamic projections to Po and LP may play a role in those migraine attacks triggered by disrupted sleep, skipping meals and emotional reactions.