Magnetic fields inhibit opioid-mediated ‘analgesic’ behaviours of the terrestrial snail,Cepaea nemoralis

1. The terrestrial snail, Cepaea nemoralis, when placed on a warmed surface (40 degrees C) displays a thermal avoidance behaviour that entails an elevation of the anterior portion of the fully extended foot. The latency of this nociceptive response was increased by the prototypical mu and specific kappa opiate agonists, morphine and U-50, 488H, respectively, in a manner indicative of anti-nociception and the induction of 'analgesia'. Pretreatment with the prototypical opiate antagonist, naloxone, blocked the morphine- and reduced the U-50, 488H-induced analgesia. Naloxone had no effects on the thermal response latencies of saline treated animals. 2. Exposure to either cold (7 degrees C) or warm (38 degrees C) temperature stress increased the nociceptive thresholds of Cepaea in a manner indicative of the induction of 'stress-induced analgesia'. The warm stress-induced analgesia was opioid mediated, being blocked by naloxone, whereas, the cold stress-induced analgesia was insensitive to naloxone. 3. Exposure for 15-30 min to 0.5 Hz weak rotating magnetic fields (1.5-8.0 G) significantly reduced the analgesic effects of the mu and kappa opiate agonists in a manner similar to that observed with naloxone. The magnetic stimuli also inhibited the endogenous opioid mediated warm stress-induced analgesia and significantly reduced the cold stress-induced analgesia. The magnetic stimuli had no evident effects on the nociceptive responses of saline-treated animals. The dihydropyridine (DHP) and non-DHP calcium channel antagonists diltiazem, verapamil. and nifedipine differentially and significantly reduced, while the DHP calcium channel agonist, BAY K8644, significantly enhanced the inhibitory effects of the magnetic fields on morphine-induced analgesia.     

Tolerance to morphine-induced analgesia in mice: Magnetic fields function as environmental specific cues and reduce tolerance development

Mice receiving daily injection of morphine (10 mg/kg) developed tolerance to morphine-induced analgesia, such that after 5–7 days of treatment their thermal response (paw licking) latencies in the hot plate test were indistinguishable from those of control animals. Exposure to a rotating magnetic field for thirty minutes before the daily morphine administrations significantly reduced the development of tolerance. These magnetic exposure also significantly increased over 7–10 days the basal nociceptive thresholds and paw licking response latencies of saline treated mice. Control and sham exposed mice that were fully tolerant to the analgesic effects of morphine failed to show any tolerance to morphine-induced analgesia when exposed to the magnetic stimuli prior to injection. Likewise, the partial tolerance to morphine shown by mice exposed to the rotating magnetic field pre-injection environmental cues was eliminated when control or sham pre-injection cues lacking the magnetic stimuli were provided. In all cases tolerance to morphine-induced analgesia was evident in the subsequent re-test with the original cues. These results indicate that magnetic field exposure can reduce the development of tolerance to the analgesic effects of morphine. They also show that magnetic stimuli function as significant environmental cues for the development of tolerance to morphine-induced analgesia. This suggests that magnetic stimuli affect both the associative (classical conditioning) and non-associative (physiological, pharmacological) mechanisms involved in the development of opiate tolerance.     

Exposure to time varying magnetic fields associated with magnetic resonance imaging reduces fentanyl-induced analgesia in mice

The effects of exposure to clinical magnetic resonance imaging (MRI) on analgesia induced by the mu opiate agonist, fentanyl, was examined in mice. During the dark period, adult male mice were exposed for 23.2 min to the time-varying (0.6 T/sec) magnetic field (TVMF) component of the MRI procedure. Following this exposure, the analgesic potency of fentanyl citrate (0.1 mg/kg) was determined at 5, 10, 15, and 30 min post-injection, using a thermal test stimulus (hot-plate 50 degrees C). Exposure to the magnetic-field gradients attenuated the fentanyl-induced analgesia in a manner comparable to that previously observed with morphine. These results indicate that the time-varying magnetic fields associated with MRI have significant inhibitory effects on the analgesic effects of specific mu-opiate-directed ligands.     

Bremazocine: a potent, long-acting opiate kappa-agonist

The benzomorphan analogue bremazocine is a potent, centrally-acting analgesic with a long duration of action. In animal models it is free of physical and psychological dependence liability, produces no respiratory depression, and has a variety of other properties which justify its classification as a putative opiate kappa-receptor agonist.Binding studies with tritiated (?)-bremazocine on rat brain membrane preparations show that this molecule differs in its binding properties from previously investigated exogenous or endogenous opioids. Studies on isolated guinea-pig ileum and mouse vas deferens indicate a preference for opiate kappa-receptors.In mice (hot plate, tail flick) and rhesus monkeys (shock titration), bremazocine is a potent analgesic with a long duration of action. Here also, the actions of the antagonists naloxone and Mr 2266 suggest a preference for opiate kappa-receptors.Bremazocine differs from morphine in the non-production of mydriasis and the Straub tail phenomenon in mice, in its lack of effects on respiration in rats, in that it is not self-administered by rhesus monkeys, and in that programmed administration in the same species does not lead to a morphine-like withdrawal syndrome upon cessation of drug treatment or upon naloxone challenge. Prolonged treatment of animals with bremazocine leads to tolerance to its analgesic effects; morphine treatment of such tolerant animals causes analgesia. Conversely, treatment of morphine-tolerant animals with bremazocine does not cause analgesia; these findings suggest that morphine and bremazocine interact with different subpopulations of opiate receptors.     

A possible involvement of beta-endorphin, substance P, and serotonin in rat analgesia induced by extremely low frequency magnetic field

Most of the research concerning magnetic antinociception was focused on brief exposure less than 1 h. The main purpose of the present study was to determine the effect of extremely low frequency (ELF) magnetic field (MF) repeated exposures on rats in inducing antinociception and to find the effective analgesic "time window." Meanwhile this investigation was to examine the role of central beta-endorphin, substance P, and 5-HT in magnetic analgesia. We found tail flick latencies (TFLs) increased significantly after the rats were exposed to 55.6 Hz, 8.1 mT magnetic field for 4 days, 6 h each day. The analgesic effects seemed to decrease gradually when the rats were exposed daily for another 10 days. Their levels of TFLs decreased within 1 day when the rats were removed after a 4-day exposure. The concentrations of hypothalamus beta-endorphin, substance P, and brainstem serotonin (5-HT) were increased significantly on Day 4. However, no differences were found when rats were exposed for another 10 days, and there were no significant increases when rats were removed after the fourth day of exposure and tested for nociception on Days 5 and 7 with no changes in the biochemical markers at 7 days. These results suggest that the ELF magnetic field has analgesic effect, but only on Days 3 and 4. The effect may be associated with increases in endogenous beta-endorphin, substance P, and 5-HT stimulated by the 55.6 Hz, 8.1 mT magnetic field.     

Ionizing radiation induces opioid-mediated analgesia in male mice

The effects of exposure to ionizing radiation on the nociceptive thresholds of CF-1 mice were examined. Significant increases in thermal response latencies, indicative of analgesia were observed after exposure to either high or low doses of radiation. However, the onset of analgesia occurred significantly more rapidly after treatment with the high doses. Administration of the opiate antagonist, naloxone, blocked and reversed the analgesic effects of both the high and low dose of radiation. These findings support the hypothesis that exposure to ionizing radiation results in opioid-mediated analgesia.     

Intravenous buprenorphine reduces pupil size and the light reflex in humans

The pupillary effects of intravenous buprenorphine were studied in eight nondependent male subjects who reported previous opiate use. Buprenorphine (0.3, 0.6, and 1.2 mg) decreased pupil size, the amplitude of the light reflex, and the velocities of constriction and dilation. Significant pupillary effects occurred within 15 min of the injection and persisted for 24 hr. At 48 hr most measures returned to baseline levels. Generally the magnitude of the effect was not dose related although recovery occurred sooner after the lower dose. The time course of the pupillary effects of buprenorphine exceeds duration of its analgesic and subjective effects. Previous studies have reported that pupillary measures are especially sensitive to the acute effects of full opiate agonists. The results of the present study indicate that buprenorphine, a partial opiate agonist, causes profound and persistent effects on pupillary size and dynamic measures.     

The interaction of ketamine with the opiate receptor

The analgesic effect of the anesthetic agent ketamine HCl is inhibited in rats by the narcotic receptor antagonist naloxone. Racemic (±) ketamine HCl also displaced ³H-naloxone in an opiate receptor binding-assay. The potency of ketamine in the assay was reduced nearly six-fold by sodium suggesting that the drug interacts as an agonist. However, some activity as an antagonist was not ruled out. The interaction of ketamine HCl with the opiate receptor was stereospecific with the (+) salt being more effective than the (-) salt. The stereoselective nature of the interaction is consistent with other studies (1) demonstrating that (+) ketamine HCl has a greater analgesic effect than the (-) salt.     

Partial reversal of behavioral action of the agonist D-Trp-6-LH-RH by naloxone in mice

The effects of the superactive agonist analog D-Trp-6-LH-RH were investigated in several neuropharmacological tests: inhibition of picrotoxin-induced seizures, open-field behavior, hot-plate and tail-flick tests, assessment of catalepsy and apomorphine-induced cage-climbing. In most tests, D-Trp-6-LH-RH was administered subcutaneously (sc.) at the dose of 100 micrograms/kg. The opiate involvement in the peptide action was checked by using naloxone HCl (NX) in a dose of 1 mg/kg intraperitoneally (ip.), with the exception of the analgesic tests where the dose was 0.5 mg/kg. The analog significantly suppressed the open-field parameters of ambulation, rearing and grooming; except for grooming, these actions were fully antagonized by NX. Similarly, NX pretreatment restored to the control levels the latencies of seizure parameters increased by D-Trp-6-LH-RH. The hot-plate latencies did not change after pretreatment with NX but the opiate antagonist was fully able to antagonize the analgesic effect of the peptide in the tail-flick test. The cataleptogenic effect and the inhibition of apomorphine-induced cage-climbing demonstrated after D-Trp-LH-RH were not antagonized by NX.     

Exposure to a hypogeomagnetic field or to oscillating magnetic fields similarly reduce stress-induced analgesia in C57 male mice

Previous studies have shown that exposure to altered magnetic fields alters analgesic responses in a variety of species, including humans. Here we examined whether deprivation of the normally occurring geomagnetic field also affects stress-induced analgesia, by measuring the nociceptive responses of C57 male mice that were restraint-stressed in a hypogeomagnetic environment (inside a mu-metal box). Stress-induced analgesia was significantly suppressed in a manner comparable to that observed in mice that were either exposed to altered oscillating magnetic fields or treated with the prototypic opiate antagonist naloxone. These results represent the first piece of evidence that a period in a hypogeomagnetic environment inhibits stress-induced analgesia.     

Opiate properties of SKF 525A.

SKF 525A, a classical inhibitor of microsomal drug-metabolizing enzymes, is structurally similar to the diphenylpropylamine analgesics, and certain reported effects in animals resemble those produced by opiate drugs. In an opiate radioreceptor assay, SKF 525A was 50 times less potent than methadone in the absence of sodium and 10 times less potent in the prescence of sodium. The nature of the sodium effect indicates SKF 525A to have less opiate agonist character than does methadone. In mice, 2 mg of SKF 525A given intraperitoneally induced less profound analgesia on a hot plate (44 degrees C) than did 0.1 mg of methadone. Analgesia by SKF 525A was prevented by pretreatment of the mice with naloxone. In rats, 50 microgram of SKF 525A given intracerebroventricularly was analgesic.     

Oxymorphone-naltrexonazine, a mixed opiate agonist-antagonist

Previous studies from our laboratories have reported the synthesis and pharmacological characteristics of a series of symmetrical opiate azines: naloxonazine, oxymorphonazine and naltrexonazine. We have now synthesized and characterized in binding assays and in vivo two asymmetrical azines: oxymorphone-naltrexonazine and oxymorphone-3-methoxynaltrexonazine. Oxymorphone-naltrexonazine, which theoretically could interact with the receptor as either an agonist or antagonist, displayed antagonist properties in vitro and in vivo. Oxymorphone-3-methoxynaltrexonazine, which theoretically could bind only as an agonist, possessed agonist properties in binding studies and was a potent analgesic in vivo.     

Opioid involvement in the control of feeding in an insect, the American cockroach

Administration of the kappa opiate agonist, U-50,488H (0.10-10 mg/kg), produced over three hours a significant dose-dependent increase in the ingestive responses of free feeding American cockroaches, Periplaneta americana. These effects could be decreased by the opiate antagonist, naloxone (1.0 mg/kg), with naloxone by itself blocking the augmented feeding responses of food-deprived cockroaches. The mu opiate agonist, morphine (1.0-20 mg/kg) caused a significant dose-dependent and naloxone-reversible increase in the locomotory activity of cockroaches. These results suggest that opioid systems may be involved in the control of the feeding in cockroaches in a manner analogous to that proposed for vertebrates.     

Spinal analgesia: Comparison of the mu agonist morphine and the kappa agonist ethylketazocine

The sites of analgesic action of the mu agonist morphine and the purported kappa agonist ethylketazocine (EKC) were compared. Using local drug injections and parenteral administration of drugs to spinalized rats, our data support a predominantly spinal site of action for EKC and a major supraspinal action for morphine in antinociceptive tests. This spinal analgesic action of EKC was dose dependent and naloxone reversible indicating opiate receptor involvement. The possibility that EKC activates a spinal kappa receptor population is under further study.     

Differential inhibitory effects of MIF-1, Tyr-MIF-1, naloxone and beta-funaltrexamine on body rotation-induced analgesia in the meadow vole, Microtus pennsylvanicus

The effects of body rotation in a horizontal plane and various opiate antagonists on the nociceptive responses of a day-active microtine rodent, the meadow vole, Microtus pennsylvanicus, were examined. Intermittent rotation (70 rpm, schedule of 30 sec on, 30 sec off) for 30 min induced significant analgesic responses in the voles for 15 min after rotation. These increases in thermal response latency were blocked by intraperitoneal pretreatment with either naloxone or the irreversible mu opiate receptor antagonist beta-funaltrexamine (beta-FNA; 10 mg/kg; 24 hr pretreatment). This antagonistic effect of beta-FNA indicates mu opioid involvement in the mediation of rotation-induced analgesia. The antiopiate peptides MIF-1 (Pro-Leu-Gly-NH2) and Tyr-MIF-1 also significantly reduced, though did not completely block, body rotation-induced opiate analgesia. This suggests that Tyr-MIF-1 and MIF-1 have significant antagonistic effects on mu opioid systems that are involved in the mediation of stress (rotation)-induced analgesia.     

Social conflict activates opioid analgesic and ingestive behaviors in male mice

The activation of endogenous opioid mechanisms and their subsequent effects on rodent behavior and physiology has usually been characterized following artificial stress. In this study the more naturalistic stress arising from social conflict between male mice was used to investigate the involvement of opioid systems in post-conflict analgesic and ingestive behaviors. Both the aggressive encounters and the subsequent defeat experience resulted in marked analgesia and the induction of ingestive behaviors. Feeding and drinking responses were analogous to those observed after administrations of either the endogenous opioid peptide, β-endorphin, or the exogenous opioid agonist morphine. The ingestive behaviors following defeat or central opiate administration were blocked by the opiate antagonist naloxone. The present results support the hypothesis of a direct activation of the endogenous opiate system following social conflict.     

Prostaglandins, cyclic AMP and the biochemical mechanism of opiate agonist action.

The paper re-examines, in the light of recent evidence, the original proposition that the ability of opiates to inhibit the stimulation by E prostaglandins of cyclic AMP formation in rat brain homogenate represents a biochemical mechanism that could account for the analgesic and allied effects of these drugs. It is concluded that subsequent evidence largely supports the original proposition; but that this can now be made more definite. It is proposed that inhibition of an adenylate cyclase of morphine-sensitive neurones is the decisive biochemical consequence of the binding of an opiate agonist with its specific receptor.     

The role of adrenocorticotropic hormone in inhibition of pain reaction in awake rats

The effect of hormones of hypothalamic-pituitary-adrenocortical system on pain sensitivity were studied in experiments on awake Sprague-Dawley males rats. Pain sensitivity was tested by tail flick reaction induced by thermal stimuli. Systemic glucocorticoids and ACTH injection increased the tail flick latency. The ACTH-induced analgesic effect was unaffected by deficiency of glucocorticoids production in pretreatment with pharmacological dose of cortisol but was fully eliminated by pretreatment with opiate antagonist naltrexone. These findings suggest that ACTH-induced analgesic effect is mediated by opiate receptors but not by glucocorticoids released in response to ACTH injection.     

Purinoreceptors are involved in the control of acute morphine withdrawal.

The effects exerted by P1 and P2 purinoceptor agonists and antagonists on the acute opiate withdrawal induced by morphine were investigated in vitro. Following a 4 min in vitro exposure to morphine, the guinea-pig isolated ileum exhibited a strong contracture after the addition of naloxone. The P1 purinoceptor agonist, adenosine, was able dose-dependently to reduce morphine withdrawal whereas alpha,beta-methylene ATP (APCPP), a P2 purinoceptor agonist, increased morphine withdrawal. Caffeine, a P1 purinoceptor antagonist, was able significantly and in a concentration dependent manner to increase morphine withdrawal whereas quinidine, a P2 receptor antagonist, reduced it. The results of our experiments indicate that both P1 and P2 purinoceptor agonists and antagonists are able to influence opiate withdrawal in vitro, suggesting an important functional interaction between the purinergic system and opioid withdrawal.     

Opioid receptor types in the brain of the Afghan pika (Ochotona rufescens), a species which is naturally tolerant to morphine

The rabbit is normally sensitive to morphine while another lagomorph, the Afghan pika Ochotona rufescens is naturally tolerant to the analgesic effects elicited by the opium alkaloid. In spite of the different responsiveness of the two species to morphine we find that the pika brain and the rabbit brain both contain a mixture of mu-, delta- and kappa-opioid sites in nearly the same proportions: 46-47% mu, 23% delta and 28-30% kappa. Moreover, apparent binding of morphine in pika and rabbit brain membranes is inhibited in the presence of Na+ ions and/or of 5-guanylylimidodiphosphate indicating that morphine should behave as an opiate agonist (analgesic) not only in rabbits, which it does but also in pikas, which it does not. Taken together these results suggest that the natural tolerance of the Afghan pika to morphine may not reside in modified opioid receptor types and that its origin should be sought elsewhere.