The blockade of spinal glycine receptors with intrathecal (i.t.) strychnine (STR) produces reversible, segmentally localized allodynia in the rat. The purpose of this study was: (1) to investigate the effect of the anticonvulsant agent, milacemide, a glycine pro-drug on STR-allodynia; (2) to compare this effect with that of milacemide on normal nociception (without STR); and (3) to determine the sensitivity of the anti-allodynic effect of milacemide to pretreatment with selective monoamine oxidase (MAO)-A (clorgyline) and MAO-B (L-deprenyl) inhibitors. Male Sprague-Dawley rats, fitted with chronic i.t. catheters, were lightly anesthetized with urethane. Hair deflection (HD) evoked maximum changes in blood pressure and heart rate were recorded from left carotid artery, and cortical electroencephalographic (EEG) activity was continuously monitored using subdermal needle electrodes before and after i.t. STR (40 microg). Rats were pretreated with a single intravenous (i.v.) injection of milacemide (100-600 mg/kg), 1 h before i.t. STR. To sustain the allodynic state, STR was injected every hour for up to 4 h. HD was applied to the affected dermatomes (2 min duration) using a cotton-tipped applicator at 5-min intervals for the duration of the STR effect. Normally innocuous HD elicited a marked increase in mean arterial blood pressure and heart rate, an immediate motor responses, and desynchronisation of EEG when applied to the cutaneous dermatomes affected by i.t. STR. Milacemide (100-600 mg/kg, i.v.) dose-dependently inhibited the heart rate and pressor responses (ED50 = 398 mg/kg; 95%CI = 196-873) and the motor responses (ED50 = 404 mg/kg; 95%CI = 275-727). Maximum inhibition was observed approximately 2 h after i.v. injection. The duration of action ranged from 3 h (400 mg/kg) to 4 h (600 mg/kg). Milacemide had no effect on the percent synchrony in the EEG. At the time of maximum inhibition of STR-allodynia (2 h post-infusion), responses evoked by noxious pinch were unaffected by milacemide. Pretreatment with L-deprenyl (3 mg/kg, i.p.), but not clorgyline (10 mg/kg, i.p.) significantly blocked the anti-allodynic effect of milacemide (600 mg/kg i.v). These data indicate that i.v. milacemide significantly attenuates the allodynia arising from spinal glycine receptor blockade, and are consistent with: (1) the selective modulation of low threshold afferent input by STR-sensitive, glycine interneurons in the rat spinal cord; and (2) the pharmacological actions of milacemide as a glycine pro-drug.
The blockade of spinal glycine receptors with intrathecal (i.t.) strychnine produces segmentally-localized allodynia in the rat; a reversible and highly reproducible effect that is attained without peripheral or central nerve injury. We investigated the effect of i.v. mexiletine, an orally active congener of lidocaine, on strychnine allodynia and compared the dose-response relationship of mexiletine in normal (noxious paw pinch) versus abnormal (i.t. strychnine) nociceptive conditions. In addition, we determined the dose-response effect of i.t. AP-7 (an NMDA antagonist) on strychnine allodynia. Male, Sprague-Dawley rats, fitted with chronic i.t. catheters, were lightly anesthetized with urethane. Stimulus evoked changes in blood pressure and heart rate were recorded from the left carotid artery and cortical electroence-phalographic (EEG) activity was continuously monitored using subdermal needle electrodes. After i.t. strychnine (40 micrograms), repetitive brushing of the hair (hair deflection) evoked a progressive increase in mean arterial pressure and heart rate, an abrupt motor withdrawal response, and desynchronization of the EEG, equivalent to those elicited by the chemical nociceptive agent, mustard oil (without strychnine). Pretreatment with mexiletine (5-30 mg/kg i.v. 5 min before i.t. strychnine) dose-dependently inhibited the responses evoked by noxious hind paw pinch (no strychnine) and hair deflection (after i.t. strychnine) with equal potency (ED50's = 9.1-17 mg/kg). Below 30 mg/kg, this effect was achieved without a change in EEG synchrony (cortical activity reflecting the level of anesthesia) and without affecting motor efferent pathways. Strychnine allodynia was also significantly blocked by i.t. AP-7. The ED50's and 95% confidence intervals were 1.1 micrograms (0.7-1.8) for mean arterial pressure, 1.7 micrograms (0.5-6.0) for heart rate, and 0.4 microgram (0.07-2.0) for withdrawal duration. Cortical EEG synchrony was unchanged after i.t. AP-7 consistent with a spinal site of action. The data indicate that: (i) robust allodynia can be selectively induced with i.t. strychnine in animals whose somatosensory systems are otherwise normal; (ii) sub-anesthetic doses of i.v. mexiletine inhibit the abnormal responses to low-threshold (A-fiber) afferent input in the strychnine model of allodynia (i.e., in the absence of peripheral or central nerve injury) at doses which affect normal nociception; and (iii) in the presence of i.t. strychnine, low-threshold afferent input activates a spinal NMDA-receptor mediated process normally restricted to noxious afferent input. Systemic mexiletine may have an important spinal site of action in abnormal pain states.
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