Yohimbine and flumazenil: effect on nitrous oxide-induced suppression of dorsal horn neurons in cats.

PURPOSE: The purpose of this study was to determine the mechanisms of nitrous oxide (N2O) antinociception at the spinal level with yohimbine (an α2-adrenergic antagonist) and flumazenil (a specific benzodiazepine antagonist) using chemonociceptive stimuli in spinal dorsal horn neurons in the cat. METHODS: A lumbar laminectomy extending from L4 to L6 was performed to allow insertion of a extracellular recording device via a microelectrode. Additional laminectomy was performed at the T12 level to transect the spinal cord. As a noxious stimulus, bradykinin (BK) was injected via the cannula inserted into the femoral artery. Animals were divided into four treatment groups for subsequent experiments: N2O+flumazenil, N2O+yohimbine, flumazenil (alone), and yohimbine (alone). RESULTS: N2O suppressed BK-induced nociceptive responses in transected feline spinal cords. The BK-induced neuronal firing rates were significantly suppressed: to 69.2%, 61.8%, and 52.2% of the baseline firing rate at 10, 20, and 30 min, respectively, after N2O administration. The 47.8% suppression on BK-induced neuronal responses at 30 min after N2O administration was reversed 5 min after administration of yohimbine (25.2% suppression). Similarly, N2O suppression (42.5%) on chemically induced neuronal responses was reversed by flumazenil (24.9% suppression) at identical postadministration intervals. CONCLUSION: These data imply that N2O suppresses the nociceptive responses in part probably through its agonistic binding activity to the α2-adrenergic, γ-aminobutyric acid (GABA)-benzodiazepine, or both receptor systems in dorsal born neurons of the feline spinal cord.

Suppressive action of enflurane on dorsal horn neurons in rabbits.

The neurophysiologic mechanism of the suppressive action of enflurane on spinal nociceptive transmission was examined in rabbits with intact and with transected spinal cords. Enflurane suppressed nociceptive responses in both intact and transected spinal cord groups. The suppressive effects of enflurane were significantly greater in the intact group than in the transected group. The suppressive effects of enflurane were not reversed by the addition of 0.2 mg·kg-1 of naloxone. These results suggest that enflurane suppresses nociceptive responses by activating descending inhibitory systems and directly suppressing activity at the spinal level. This suppressive action of enflurane does not interact with the opioid receptor.