Brain research
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Intraplantar administration of zymosan produces inflammation and results in behavioral evidence of hyperalgesia to mechanical and thermal stimuli in the rat. In the present studies, responses of primary afferents and spinal dorsal horn neurons to mechanical and thermal stimuli were examined before and during zymosan-induced inflammation of the hindpaw. In tests of responses of primary afferents to mechanical stimuli, group mean mechanical response thresholds of C-mechanonociceptor (CMN) units significantly decreased after zymosan administration. ⋯ These data suggest that the zymosan-induced hyperalgesia to mechanical stimuli observed in behavioral studies reflects decreases in response thresholds of peripheral CMN units and spinal NS neurons. Hyperalgesia to thermal stimuli reflects decreases in response thresholds of peripheral CMH units, spinal WDR neurons, and spinal NS neurons. These data support the view that different physiological substrates mediate hyperalgesia to either thermal or mechanical stimuli following intraplantar administration of zymosan.
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In animal models of neuropathic pain, transection or constrictive injury to peripheral nerves produces ectopic discharges originating at both injury sites and related dorsal root ganglia (DRG). In addition, hyperexcitability is observed in associated dorsal horn (DH) neurons of the spinal cord. As ectopic discharges are inhibited by agents that block voltage-sensitive Na+ channels, it has been postulated that accumulation of Na+ channels in the membrane at nerve injury sites may contribute to the development of ectopic nerve activity (ENA). ⋯ Lidocaine or QX-314 also significantly reduced HR and MBP in the same dose range as that which reduced ENA in DRG or neuromas. In isolated rat vagus nerve recordings, QX-314 induced marked use-dependent inhibition of C-spike amplitude, with IC50 values (microM) of 9000 (4600-18,000) and 350 (290-420) for low- (0.03 Hz) and high-frequency (30 Hz) C-spikes, respectively. These data support the hypothesis that Na+ channel accumulation contributes to the generation of ectopic discharges in neuromas and DRG, and suggests that intravenous QX-314 can acutely block Na+ channels at these sites.