The journal of pain : official journal of the American Pain Society
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Primary headaches such as migraine are postulated to involve the activation of sensory trigeminal pain neurons that innervate intracranial blood vessels and the dura mater. It is suggested that local activation of these sensory nerves may involve dural mast cells as one factor in local inflammation, causing sensitization of meningeal nociceptors. Immunofluorescence was used to study the detailed distribution of calcitonin gene-related peptide (CGRP) and its receptor components calcitonin receptor-like receptor (CLR) and receptor activity-modifying protein 1 (RAMP1) in whole-mount rat dura mater and in human dural vessels. The relative distributions of CGRP, CLR, and RAMP1 were evaluated with respect to each other and in relationship to mast cells, myelin, substance P, neuronal nitric oxide synthase, pituitary adenylate cyclase-activating polypeptide, and vasoactive intestinal peptide. CGRP expression was found in thin unmyelinated fibers, whereas CLR and RAMP1 were expressed in thicker myelinated fibers coexpressed with an A-fiber marker. CLR and RAMP1 immunoreactivity colocalized with mast cell tryptase in rodent; however, expression of both receptor components was not observed in human mast cells. Immunoreactive substance P fibers coexpressed CGRP, although neuronal nitric oxide synthase and vasoactive intestinal peptide expression was very limited, and these fibers were distinct from the CGRP-positive fibers. Few pituitary adenylate cyclase-activating polypeptide immunoreactive fibers occurred and some colocalized with CGRP. ⋯ This study demonstrates the detailed distribution of CGRP and its receptor in the dura mater. These data suggest that CGRP is expressed in C-fibers and may act on A-fibers, rodent mast cells, and vascular smooth muscle cells that express the CGRP receptor. These sites represent potential pathophysiological targets of novel antimigraine agents such as the newly developed CGRP receptor antagonists.
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Studies of peripheral nerve inflammation (neuritis) suggest that some symptoms of neuropathic pain can be generated from inflamed but otherwise uninjured axons. We have previously inferred a role for inflammation-induced axonal transport disruption in the underlying mechanisms. In the present study, we have investigated the development of sensory hypersensitivities following vinblastine-induced axonal transport disruption. Similar to neuritis, locally applied .1 mM vinblastine caused the rapid development of mechanical hypersensitivity within the first week postsurgery. The same animals did not develop heat hypersensitivity. Because aberrant firing from primary sensory neurons is considered necessary to drive spinal mechanisms that lead to hypersensitivities, the levels of ongoing activity and axonal mechanical sensitivity were examined. Recordings from A- and C-fiber neurons did not reveal differences in the levels of ongoing activity between vinblastine-treated (<5.8%) and saline-treated control animals (<4.6%). However, 28% of C-fiber axons were mechanically sensitive at the vinblastine treatment site. Using kinesin immunohistochemistry, we confirmed a reduction of anterograde axonal transport in vinblastine-treated and neuritis animals. In summary, this study has revealed an alternative pain model, which may be relevant to conditions that are not accompanied by frank nerve injury. ⋯ In this study, we expand our previous reports and demonstrate that focal reduced axonal transport causes distal mechanical hypersensitivity considered consistent with neuropathic pain but in the absence of nerve injury. These findings may inform pain conditions that have a neural inflammatory component.