A model of experimental peripheral neuropathy producing pain-related disorders has recently been described in the rat. The present study aimed to investigate, using a different and quantifiable behavioural approach, the abnormal pain-related sensations in the animals. The neuropathy was produced by 4 ligatures tied loosely around the common sciatic nerve. 6-8 days after surgery, most of the rats exhibited pain-related disorders ipsilateral to the sciatic ligation, which became maximal 2 weeks after surgery. Mechanical noxious stimulation (pinching of the hind paw) revealed hyperalgesia in all the animals. Rats also exhibited allodynia when tested with the vocalization threshold test to paw pressure (mean vocalization thresholds were 65.5 +/- 3.6% of the preoperative control, P less than 0.01, n = 95). Tests using heat (40, 42, 44, 46 degrees C) and cold (10 degrees C) stimulation (immersion of the rat's hind paw in a bath until it was observed to struggle) indicated hyperalgesia to noxious heat (decrease of 30% in the immersion duration (ID) at a temperature of 46 degrees C), and allodynia to non-noxious heat (decrease of 30% in the temperature of the struggle threshold) and to cold stimulation (decrease by 40% in the ID). In addition, the animals showed modifications in the spontaneous postures of the affected hind paw in a natural setting, suggesting a 'spontaneous' pain-related behaviour (the mean 'pain' rating, derived from the technique used for the formalin test and numbered 0-5, was 2.8 +/- 0.4, P less than 0.01, n = 12). Lastly, sensitized responses were observed to mechanical stimulation after thermal stimulation in the non-noxious range applied to the lesioned but not the non-lesioned paw. The time course of pain-related disorders was comparable whatever the behavioural test, with recovery 2 months after surgery. These results clearly show that the neuropathy produces abnormal pain-related disorders in the rat, which are reminiscent of those observed in some human neuropathies.
Responses resulting from injury to the trigeminal nerve exhibit differences compared with those caused by lesion of other peripheral nerves. With the aim of elucidating the physiopathological mechanisms underlying cephalic versus extracephalic neuropathic pain, we determined the time course expression of proinflammatory cytokines interleukin-6 (IL-6) and IL-1, neuronal injury (ATF3), macrophage/microglial (OX-42), and satellite cells/astrocyte (GFAP) markers in central and ganglion tissues in rats that underwent unilateral chronic constriction injury (CCI) to either infraorbital nerve (IoN) (cephalic area) or sciatic nerve (SN) (extracephalic area). Whereas CCI induced microglial activation in both models, we observed a concomitant upregulation of IL-6 and ATF3 in the ipsilateral dorsal horn of the lumbar cord in SN-CCI rats but not in the ipsilateral spinal nucleus of the trigeminal nerve (Sp5c) in IoN-CCI rats. Preemptive treatment with minocycline (daily administration of 20 mg/kg, i.p., for 2 weeks) partially prevented pain behavior and microglial activation in SN-CCI rats but was ineffective in IoN-CCI rats. We show that IL-6 can upregulate OX-42 and ATF3 expression in cultured microglia and neurons from spinal cord, respectively, as well as in the dorsal horn after acute intrathecal administration of the cytokine. We propose that IL-6 could be one of the promoters of the signaling cascade leading to abnormal pain behavior in SN-CCI but not IoN-CCI rats. Our data further support the idea that different pathophysiological mechanisms contribute to the development of cephalic versus extracephalic neuropathic pain.
Extensive studies in rodents suggest that serotonin (5-HT) modulates nociceptive responses through the stimulation of several receptor types. However, it remains to demonstrate that these receptors participate in the control of nociception under physiological conditions. Pain behaviors of mutants which do not express 5-HT1A, 5-HT1B, 5-HT2A or 5-HT3A receptors, or lacking the 5-HT transporter, compared to paired wild-type mice of the same genetic background, were examined using validated tests based on different sensory modalities. Mechanical (von Frey filaments, tail pressure, tail clip tests), thermal (radiant heat, 46 degrees C water bath, hot-plate test) and formalin-induced nociception were determined in 2- to 3-month-old males. 5-HT1A knock-out mice differed from wild-types by higher thermal sensitivity (hot-plate test only), and 5-HT1B knock-out mice by higher thermal and formalin sensitivity. Both 5-HT2A and 5-HT3A knock-out mice differed from wild-types by a dramatic decrease in the formalin-induced nociceptive responses for phase II (16-45 min after injection/inflammatory phase). In contrast, neither mechanical, thermal nor formalin-induced nociception differed between mutants lacking the 5-HT transporter and paired wild-type mice. Although differences in spontaneous locomotor activity in 5-HT1B-/- (increase) and 5-HT3A-/- (decrease) knock-out mice versus paired wild-types might have confounded differences in nociception, acute 5-HT receptor blockade by selective antagonists was found to replicate in wild-type mice the effects on pain behavior, but not on locomotor activity, of the respective gene knock-out in mutants. These results support the conclusion that the complex control of pain mechanisms by 5-HT, acting at multiple receptors, is physiologically relevant in mice.
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