Pain
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Withdrawal reflex responses to graded von Frey filaments applied to the plantar surface of the paw were measured before and after bone hole damage in rats with either a dorsal column (DC) lesion or a sham DC lesion. Two methods were employed to produce models of osteotomy; a small hole was drilled through either the (1) tibia or (2) calcaneus (Houghton, A. K., Hewitt, E. and Westlund, K. ⋯ Nocifensive behavior, characterized by a lifting and guarding of the damaged limb, was also observed in animals with a hole through the calcaneus. In contrast, we found that interrupting the dorsal column pathway with a small mid-line lesion (1 week prior to the osteotomy) prevented the development of both the primary and secondary mechanical hyperalgesia and allodynia but not the guarding of the damaged limb. This study provides evidence that axons in the medial part of the dorsal column are involved in the development of mechanical hyperalgesia and allodynia after bone hole injury.
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The present study was undertaken to examine the involvement of descending pain modulatory systems from the brainstem rostral ventromedial medulla (RVM) in modulating visceral hyperalgesia produced by intracolonic instillation of zymosan. Three hours after intracolonic zymosan, the visceromotor response (VMR) to noxious colorectal distension (CRD, 80 mmHg, 20s) was increased significantly. This hyperalgesia was attenuated in a dose-dependent manner by the selective NMDA receptor antagonist APV (10-30 fmol, 1 microl) microinjected into the RVM. ⋯ In contrast to the effects of APV and L-NAME, administration of the non-NMDA receptor antagonist DNQX into the RVM further enhanced the already facilitated VMR to CRD in zymosan-treated rats. Taken together, these data suggest that zymosan-produced visceral hyperalgesia is influenced by two descending pain modulatory systems: a facilitatory system mediated by activation of NMDA receptors in the RVM and production of nitric oxide, and an inhibitory system mediated by activity at non-NMDA receptors in the RVM. The unmasking of one system by selective blockade of the other suggests simultaneous activation of both by colonic inflammation.
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We have previously shown in rats that the provision of analgesic doses of morphine significantly reduces the tumor-promoting effects of undergoing and recovering from surgery. Because morphine had no effect in non-operated animals, and because a single preoperative dose given hours before tumor inoculation was effective, we have suggested that it is the pain-relieving effects of the drug that underlies its beneficial impact. To support and strengthen this suggestion, two different regimens of analgesia were employed, the systemic administration of the more selective mu-agonist, fentanyl, and the intrathecal (i.t.) administration of bupivacaine plus morphine. ⋯ Unlike the in vivo study, fentanyl suppressed NK activity at this time point in non-operated rats, but had no effect in operated rats. Taken together, these findings strengthen the suggestion that the management of perioperative pain is a critical factor in preventing surgery-induced decreases in host resistance against metastasis. If similar relationships between pain and metastasis occur in humans, then pain control must become a priority in the postoperative care of individuals with cancer.
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Inflammatory hyperalgesia is a complex process that depends on the sensitization of primary nociceptive neurons triggered by proinflammatory mediators, such as interleukin 1β (IL-1β). Recently, the peripheral activation of caspase-1 (previously known as IL-1β-converting enzyme) was implicated in the induction of acute inflammatory pain by promoting the processing of IL-1β from its precursor form, pro-IL-1β. Caspase-1 activation in several systems requires the assembly of an intracellular molecular platform called an inflammasome. ⋯ The reduced hyperalgesia was accompanied by significant impairments in the levels of mature forms of IL-1β (p17) and caspase-1 (p20) compared to wild-type mice at the inflammatory site. Therefore, these results identified the inflammasome components NLRC4 and ASC as the molecular platform involved in the peripheral activation of caspase-1 and IL-1β maturation, which are responsible for the induction of acute inflammatory pain. In conclusion, our study provides new therapeutic targets for the control of acute inflammatory pain.