The journal of pain : official journal of the American Pain Society
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Skeletal muscle injuries can induce chronic pain, but the underlying mechanism is unknown. One possible cause has been suggested to be an increased sensitivity to inflammatory mediators. We demonstrate that self-limited inflammatory hyperalgesia induced by intramuscular carrageenan (lasting approximately 5 days) results in a state of chronic-latent hyperalgesia, revealed by injection of prostaglandin E(2) (PGE(2)) 10 days after carrageenan at the same site. In carrageenan-pretreated muscle, PGE(2) produced hyperalgesia that was unattenuated even 14 days after injection, markedly longer than the 4-hour hyperalgesia induced by PGE(2) in naive rats. This chronic-latent hyperalgesia was reversed as well as prevented by spinal intrathecal injection of oligodeoxynucleotide antisense to protein kinase Cepsilon, a second messenger implicated in long-lasting plasticity in cutaneous nociceptors. ⋯ We describe a novel experimental model for chronic muscle pain, produced by mild acute muscle inflammation, that has clinical significance since it has the potential to reveal cellular processes by which acute inflammation or muscle trauma underlies chronic muscle pain.
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The pituitary adenylate cyclase-activating polypeptide type 1 receptor (PAC(1)-R) is a member of the 7-transmembrane domain, group 2 G-protein coupled receptor family. PAC(1)-Rs modulate neurotransmission and neurotrophic actions and have been implicated in both pronociception and antinociception. To better understand the role of PAC(1)-Rs in pain, PACAP 6-38, a PAC(1)-R antagonist, was evaluated in several inflammatory and neuropathic pain models after intrathecal (i.t.) administration. PACAP 6-38 potently reduced mechanical allodynia in a neuropathic spinal nerve ligation model (77% +/- 15% maximal effect at 12 nmol, P < .01) and was also effective in reducing thermal hyperalgesia in the carrageenan model of inflammatory pain (89% +/- 17% maximal effect at 12 nmol, P < .01). Although nociceptive responses were also attenuated with PACAP 6-38 in a dose-dependent manner in models of chronic inflammatory and persistent pain, no effects on motor performance were observed at analgesic doses. Taken together, these data demonstrate that blockade of the PAC(1)-R/PACAP complex by PACAP 6-38 can effectively attenuate thermal hyperalgesia and mechanical allodynia associated with inflammatory and neuropathic pain states. These results further emphasize that at the level of the spinal cord, PAC(1)-R activation is pronociceptive. ⋯ This article presents the analgesic profile generated by the blockade, at the spinal cord level, of the PAC-1 receptor by a potent peptide antagonist. This comprehensive data set demonstrates that if small molecule PAC-1 receptor antagonists could be identified, they would potentially produce broad-spectrum analgesia in both inflammatory and neuropathic pain states.
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The toxicity profile of oxaliplatin, a platinum derivative currently used in the treatment of colorectal cancer, differs from those of the other platinum compounds, cisplatin and carboplatin. Oxaliplatin treatment induces an acute neurotoxicity characterized by a rapid onset of cold-induced distal dysesthesia and a chronic sensory peripheral neuropathy. A single intravenous dose of oxaliplatin produced a dose-dependent mechanical hyperalgesia and heat and cold allodynia; repeated administration intensified symptoms. A single intradermal dose of oxaliplatin produced a dose-dependent mechanical hyperalgesia. A single dose intravenous oxaliplatin also lowered thresholds and increased responses of C-fiber nociceptors to mechanical stimulation, confirming a peripheral site of action. Whereas peripheral administration of inhibitors of second messengers implicated in models of other painful peripheral neuropathies (PKA, PKC, NO, Ca(2+), and caspase) had no effect; both systemic and local administration of antioxidants (acetyl-L-carnitine, alpha-lipoic acid or vitamin C), all markedly inhibited oxaliplatin-induced hyperalgesia. Intrathecal administration of the neurotoxin for IB4-positive nociceptors, IB4-saporin, markedly attenuated IB4 staining in the dorsal horn of the spinal cord and completely prevented oxaliplatin-induced hyperalgesia. We suggest that oxaliplatin acts on IB4 (+)-nociceptors to induce oxidative stress-dependent acute peripheral sensory neuropathy. ⋯ Many drugs used to treat cancer produce pain as their dose-limiting side effect. We used a model of this pain syndrome induced by oxaliplatin to demonstrate that pain is produced by action on a subset of nociceptors, the IB4-positive DRG neurons. This information could help define cellular targets against which protective therapies could be developed.
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Chronic pain that responds to antisympathetic treatments and alpha-adrenergic antagonists is clinically referred to as sympathetically maintained pain. Animal models of neuropathic pain have shown mixed results in terms of antinociceptive effectiveness of antisympathetic agents. The effectiveness of these agents have not been yet investigated in animal models of complex regional pain syndrome-type 1 (CRPS-I). In this study, we examined the effectiveness of antisympathetic agents and sympathetic vasoconstrictor antagonists, as well as agents that are vasodilators, in relieving mechanical allodynia in a recently developed animal model of CRPS-I (chronic postischemia pain or CPIP) produced by 3 hours of hind paw ischemia-reperfusion injury. Systemic guanethidine, phentolamine, clonidine, and prazosin are effective in reducing mechanical allodynia particularly at 2 days after reperfusion, and less so at 7 days after reperfusion. A nitric oxide donor vasodilator, SIN-1, also reduces mechanical allodynia more effectively at 2 days after reperfusion, but not at 7 days after reperfusion. These results suggest that the pain of CPIP, and possibly also CRPS-I, is relieved by reducing sympathetically mediated vasoconstriction, or enhancing vasodilatation. ⋯ The results of this study indicate that sympathetic block, or administration of alpha(1)-adrenergic antagonists, clonidine, or a nitric oxide donor, relieve allodynia in an animal model of CRPS-I. Thus, the pain of CRPS-I may depend on enhanced vasoconstrictor responsiveness, which may be relieved by blocking sympathetic efferent-dependent vasoconstriction, or by enhancing nitric oxide-dependent vasodilatation.