Pretreatment with sedative-hypnotics, but not with nondepolarizing muscle relaxants, attenuates alfentanil-induced muscle rigidity.

STUDY OBJECTIVE: To evaluate and compare the efficacy of various pretreatment agents to attenuate or prevent opioid-induced muscle rigidity using a well-established, previously described clinical protocol. DESIGN: Prospective, controlled, single-blind, partially randomized study. SETTING: Large medical center. PATIENTS: ASA physical status I-III patients undergoing elective surgical procedures of at least 3 hours' duration. INTERVENTIONS: The effect of pretreatment with nondepolarizing muscle relaxants (atracurium 40 micrograms/kg or metocurine 50 micrograms/kg), benzodiazepine agonists (diazepam 5 mg or midazolam 2.5 mg), or thiopental sodium 1 mg/kg on the increased muscle tone produced by alfentanil 175 micrograms/kg was compared with a control group (given no pretreatment). MEASUREMENTS AND MAIN RESULTS: Rigidity was assessed quantitatively by measuring the electromyographic activity of five muscle groups (biceps, intercostals, abdominals, quadriceps, and gastrocnemius). Rigidity also was rated qualitatively by attempts to initiate and maintain mask ventilation, attempts to flex an extremity, and the occurrence of myoclonic movements. Pretreatment with the two nondepolarizing muscle relaxants had no effect on the severe muscle rigidity produced by high-dose alfentanil. Whereas thiopental was only mildly effective, the benzodiazepines midazolam and diazepam significantly attenuated alfentanil rigidity (p < 0.05). CONCLUSION: This study suggests that benzodiazepine pretreatment is frequently, but not always, effective in preventing opioid-induced muscle rigidity.

Brain sites mediating opiate-induced muscle rigidity in the rat: methylnaloxonium mapping study.

Previous work has demonstrated that direct injections of methylnaloxonium (MN), a hydrophilic quaternary opiate antagonist, in the area of the nucleus raphe pontis (RPn) significantly attenuated alfentanil-induced muscle rigidity in the rat. To extend these observations and to explore further the regions important for opiate-induced rigidity, rats were implanted with chronic guide cannulae aimed at discrete brain sites with an emphasis on the region from the periaqueductal grey (PAG) to the RPn. Each animal was pretreated by a blinded observer with an intracerebral injection of MN (125 ng total dose) or saline, and electromyographic (EMG) activity was recorded from the gastrocnemius muscle. Alfentanil (ALF; 500 micrograms/kg) was then administered subcutaneously and the magnitude of tonic EMG activity was assessed as a measure of hindlimb rigidity. The administration of MN into the pontine raphe nucleus (RPn) and also into the more lateral nucleus reticularis tegmenti pontis significantly attenuated ALF rigidity compared with saline-pretreated controls. Within the midbrain, MN selectively reversed rigidity when injected into the periaqueductal grey (PAG). The dorsal PAG appeared to be a more important site than the ventral PAG. There was no significant effect on ALF rigidity of MN injections into brain regions between the ventral PAG and the RPn while MN injections into the deep layers of the superior colliculus, lateral to the dorsal PAG, partially attenuated ALF rigidity. In contrast, rigidity was not consistently reversed after MN injections into the basal ganglia, the dorsal superior colliculus, or the region of the decussation of the dorsal tegmentum. This study provides strong evidence that nuclei of the reticular formation, specifically the PAG, raphe pontis, and reticularis tegmenti pontis that are known to play a role in other opioid-mediated behaviors, are important in opiate-induced muscle rigidity in the rat. These results could have implications for the prevention of this undesirable effect of high-dose opiate administration.

Localization of brainstem sites which mediate alfentanil-induced muscle rigidity in the rat.

Previous work has demonstrated that direct injections of methylnaloxonium (MN), a relatively lipophobic quaternary opiate antagonist, in the area of the nucleus raphe pontis (RPn) significantly attenuated alfentanil-induced rigidity. It was hypothesized that other hindbrain sites, particularly the other raphe nuclei, might play a role in this rigidity. Therefore, a study was performed in which 57 rats, divided into four groups, were implanted with chronic guide cannulae directed at brain sites anterior, lateral, or posterior to the RPn. After each animal was pretreated with intracerebral injections of MN, alfentanil (0.5 mg/kg) was administered subcutaneously. Electromyographic activity was recorded from the gastrocnemius muscle as a measure of hindlimb rigidity. Each animal was subsequently injected at 4 to 5 day intervals with MN two additional times at sites 1 and 2 mm deeper, respectively, than the initial injection. Data were thus obtained on animals treated with either MN or saline at 3 successive histologically identified sites which were either anterior, lateral or posterior to the RPn. The administration of MN into two specific sites in the region just lateral to the nucleus raphe pontis significantly [F(1,38) = 18.68 and 5.02 respectively, p less than 0.05] reversed the rigidity produced by systemic alfentanil administration. There was a weak effect of MN injections anterior to the RPn but this could not be localized to any one site. These results suggest that discrete brainstem regions involved in opiate action can be sensitively and selectively identified by direct intracranial injections of a lipophobic opiate antagonist.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of the nucleus raphe pontis and the caudate nucleus in alfentanil rigidity in the rat.

Attempts to eliminate or reduce the rigidity induced with high-dose narcotic anesthesia in the operating room have been only partially successful. Previous investigations of opioid receptor sites mediating this rigidity have implicated two central regions: the nucleus raphe pontis (NRP) within the reticular formation and the caudate nucleus (CN) within the basal ganglia. The present study used systemically administered alfentanil (ALF), a potent, short-acting fentanyl analog, and intracerebrally infused methylnaloxonium (MN), a quaternary derivative of naloxone, to elucidate further the functional role of the NRP and CN in rigidity. ALF (0.5 mg/kg s.c.) produced a reliable model of rigidity, as documented by gastrocnemius electromyography. The onset of this rigidity was within 60 s of ALF administration, with a total duration of approximately 40-50 min. Intracerebroventricular (i.c.v.) injections of 2.0 or 4.0 micrograms of MN 15 min prior to ALF treatment prevented rigidity, while 0.125 or 0.5 microgram had no significant effect on rigidity. MN injected directly into the NRP at doses as low as 0.125 microgram significantly antagonized ALF-induced rigidity, while injections of MN into the caudate nucleus at doses as high as 4.0 micrograms failed to antagonize ALF-induced rigidity. These observations demonstrate that injection of MN into the NRP is at least 16-fold more effective in blocking ALF-induced rigidity than MN injected into the ventricle and, more importantly, at least 32-fold more effective than MN injected into the CN. The results suggest that the NRP may be an important site for the neural control of muscular rigidity associated with high-dose narcotic administration.

'Catatonia' produced by alfentanil is reversed by methylnaloxonium microinjections into the brain.

Alfentanil, a short-acting and powerful analgesic, when injected peripherally to rats (0.5 mg/kg) produced a catatonic state characterized by a rigid akinesia. The present study was designed to explore the neuroanatomical location of the opiate receptors mediating the alfentanil induced catatonia. The catatonic effect of alfentanil was measured using a bar test and depression of locomotor activity in rats tested in photocell cages during an active nocturnal phase of their cycle. Methylnaloxonium HCl (MN), a quaternary derivative of naloxone which does not readily cross the blood-brain barrier, injected into the lateral ventricle significantly reduced the catatonia at doses of 0.125-2.0 micrograms as measured in both the locomotor and bar test. MN perfusion of similar doses directly into the nucleus raphe pontis, but not in the caudate nucleus significantly antagonized the catatonia. These data complement results on alfentanil-induced muscular rigidity (Blasco et al., see companion paper) where EMG indices of rigidity in rats were reversed by microinjections of low doses of MN (0.125 and 0.5 microgram) in the nucleus raphe pontis, but not the caudate nucleus even at a high dose (4.0 micrograms). Together these results suggest that the region of the nucleus raphe pontis is an important neural substrate for opiate-induced muscular rigidity, and that the catatonic state produced by opiates depends on more diffuse opiate receptor activation of which one important component may be the nucleus raphe pontis.