Analgesic activity of morphiceptin, beta-casomorphin-4, and deltakephalin in normotensive Wistar-Glaxo and spontaneously hypertensive rats

The effects of intraventricular injection of beta-casomorphin-4, morphiceptin and deltakephalin (DTLET) on hot water tail flick and tail compression responses were investigated in Wistar Albino Glaxo (WAG) and spontaneously hypertensive rats (SHR). The effects of the mu agonist morphiceptin (20 nmol/rat), as assessed by the tail compression test, were significantly greater in SHR rats but did not differ between both strains when measured by tail flick latency. Opioid agonist deltakephalin (2 nmol/rat) in both tests elicited stronger analgesic effects in SHR as compared to WAG and these effects were blocked by naloxone in both tests used. beta-Casomorphin-4 exhibits moderate activity for mu receptors. In the tail flick test peptide (60 nmol/rat) produced an increase in latencies in SHR rats that was significantly greater than was observed in WAG rats. Naloxone pretreatment abolished the analgesic activity of beta-casomorphin-4 solely in the tail compression test in SHR. Analysis of the slopes of the dose-response curves seems to suggest that differences between the activity of these opioid peptides in SHR and WAG rats are based on a difference in the density and affinity of the subpopulation of the opioid receptors in these strains of rats.     

Analgesic effects of ethylketocyclazocine and morphine in rat and toad

We have previously found rat and toad (Bufo marinus) brain to contain inverse ratios of benzomorphan-preferring (kappa/sigma) and morphine-preferring (mu) opioid receptor types. The aim of the present study was to compare in vivo pharmacologic activity of a benzomorphan, ethylketocyclazocine (EKC) and morphine sulfate (MS) in rat and toad. Footshock intensity thresholds for eliciting locomotion were determined and dose-response curves for EKC and MS analgesia were obtained. Drugs were injected subcutaneously. In rats (high mu, low kappa in brain), both compounds produced analgesia and displayed similar sensitivity to naloxone antagonism. The analgesic effects of EKC and MS may, therefore, be mediated by a common receptor type (mu) in this pain test in rats. In toads (high kappa, low mu in brain), MS produced naloxone-reversible analgesia at doses 20-fold higher than were effective in rats. Toads did not display EKC analgesia at doses below those producing motor impairment. Moreover, 50-fold higher doses were required to produce such impairment in toads. Thirty minutes following subcutaneous injection of 3H-EKC, similar concentrations were found in rat and toad brain. Uptake into brain is probably not a factor in the behavioral resistance of toads to EKC.     

Antagonism of morphine analgesia by CCK-8-S does not extend to all assays nor all opiate analgesics

The conditions under which CCK-8-S may block opiate-induced analgesia were examined in detail. A U-shaped dose-response relationship was observed for the ability of CCK-8-S to attenuate (by approximately 50%, at most) morphine-induced tail flick analgesia. The analgesic effects of morphine in the hot plate or acetic acid-induced stretching tests were not altered by CCK-8-S at doses that antagonized morphine in the tail flick test. Tail flick latency elevations induced by meptazinol, a putative mu-1 receptor agonist, were also attenuated by CCK-8-S according to a U-shaped dose-response relationship, but those induced by U-50,488, a kappa agonist, were not antagonized by CCK-8-S doses that attenuated morphine analgesia. Thus, the ability of CCK-8-S to antagonize opiate analgesia does not follow a conventional dose-response relationship, does not extend to all tests of analgesia and may not extend to all opioid drugs. Analgesia mediated by the mu-1 opioid receptor subtype may be more amenable to antagonism by CCK-8-S than that mediated by the kappa receptor subtype.     

Analgesia induced by intrathecal injection of dynorphin B in the rat

A dose-dependent analgesic effect of intrathecally injected dynorphin B was observed in rats using the tail flick as nociceptive test. Intrathecal injection of 20 nmol of dynorphin B increased the tail flick latency by 90 +/- 23%, an effect that lasted about 90 min. For the same degree of analgesia, dynorphin B was 50% more potent than morphine on a molar basis. The analgesic effect of this dose of dynorphin B was partially blocked by 10 mg/kg, but not by 1 mg/kg, of subcutaneous naloxone, showing a relative resistance to naloxone reversal as compared with morphine analgesia. The analgesia produced by dynorphin B was unchanged in morphine-tolerant rats but was significantly decreased in rats tolerant to ethylketazocine. These results suggest that dynorphin B produces its potent analgesic effect by activation of kappa rather than mu opioid receptors in the rat spinal cord.     

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.     

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.     

The effect of opiates and opiate antagonists on heat latency response in the parasitic nematode Ascaris suum

The effects of the opiates morphine and morphine-6-glucuronide (M6G), the mu opioid receptor specific antagonist D-Phe-Cys-Tyr-D-Trp-Om-Thr-Pen-Thr-NH(2) (CTOP), and the general opiate antagonist naloxone on the latency of response to thermal stimulation were determined in the parasitic nematode Ascaris suum. Thermal detection and avoidance behaviors of the worms were evaluated with a tail flick analgesia meter using a modification of a technique employed for nociception experiments in rodents. Morphine and M6G were shown to have a dose dependent analgesic effect on A. suum's latency of response to heat with morphine being the most potent. The analgesic effect of morphine was reversed by naloxone but not CTOP. Neither naloxone nor CTOP was able to block the analgesia of M6G. CTOP but not naloxone had significant analgesic effects on its own. These findings are generally consistent with previous results on the effects of opiates and nitric oxide release from A. suum tissue. Apparently these nematodes possess opioid receptors that effect nociception.     

Intrathecal endomorphin-1 produces antinociceptive activities modulated by alpha 2-adrenoceptors in the rat tail flick, tail pressure and formalin tests

It is known that spinal morphine produces antinociception that is modulated by alpha 2-adrenoceptors. Endomorphin-1, a newly-isolated endogenous opioid ligand, shows the greatest selectivity and affinity for the mu-opiate receptor of any endogenous substance found to date and may serve as a natural ligand for the mu-opiate receptor. We examined the antinociceptive effects of endomorphin-1 administered intrathecally (i.t.) in the rat tail flick, tail pressure and formalin tests. Intrathecal endomorphin-1 produced dose-dependent antinociceptive effects in the three tests. ED50 (CI95) values for antinociception of i.t. endomorphin-1 in the tail flick test and tail pressure test were 1.9 (0.96-3.76) nmol and 1.8 (0.8-4.2) nmol, respectively. ED50 (CI95) values for phase 1 and phase 2 in the formalin test were 12.5 (7.9-19.8) nmol and 17.5 (10.2-30) nmol, respectively. Pretreatment with i.t. beta-funaltrexamine (a mu-opioid receptor selective antagonist) significantly antagonized the antinociceptive effects of endomorphin-1 in the three tests. Beta-funaltrexamine alone had not effects on the three tests. The antinociceptive effects of endomorphin-1 were also antagonized by i.t. yohimbine (an alpha 2-adrenoceptor selective antagonist). The combination of ineffective doses of i.t. clonidine (an alpha 2-adrenoceptor agonist) and endomorphin-1 produced a significant antinociception in the three tests. The results showed that intrathecal endomorphin-1 produced antinociception in a dose-dependent manner in the rat tail flick, tail pressure and formalin tests, which was mediated by spinal mu-opioid receptors and modulated by alpha 2-adrenoceptors.     

Antinociceptive activity of a 3(2H)-pyridazinone derivative in mice.

The antinociceptive activity of a 3(2H)-pyridazinone derivative (18a) was investigated in mice. 18a administered at doses which did not change either motor coordination or locomotor activity was able to induce antinociceptive effects in four nociceptive tests, the hot plate test, the tail flick test, the writhing test, and the formalin test. In the hot plate and tail flick test, 18a-induced antinociception was observed both after intraperitoneal administration and after intracerebroventricular injection thus indicating 18a has a central site of action. The pretreatment with the opioid antagonist naloxone, the alpha2-antagonist yohimbine or the GABA(B) antagonist CGP 35348 did not change 18a-induced antinociception in the hot plate test and in the tail flick test. Pretreatment with nicotinic antagonist mecamylamine did not change 18a effects either. A reversion of the 18a effects was observed after pretreatment with the muscarinic antagonists atropine and pirenzepine. Binding experiments revealed that 18a binds to muscarinic receptors, suggesting that 18a antinociception is mediated by central muscarinic receptors. The above findings together with the lack of parasympathomimetic cholinergic side effects indicate useful clinical application for this compound.     

Phencyclidine-induced inhibition of striatal acetylcholine release: comparisons with mu, kappa, and sigma opiate agonists

The effects of phencyclidine (PCP) on ACh release were compared to those of morphine, ethylketocyclazocine (EKC), and N-allylnormetazocine (SKF10047) in a superfused striatal slice preparation. The (+)-isomer of the prototypic sigma opiate agonist, SKF10047, and the prototypic kappa opiate agonist, EKC, had essentially the same pharmacological profile as did PCP. That is, they each inhibited ACh release in a concentration dependent manner (with EKC being the most potent) and this effect was antagonized by 0.1 microM naloxone. Since morphine was without effect on ACh release, it is unlikely that these drugs inhibit ACh release by acting at mu receptors. In addition, we observed that the inhibitory effect of PCP, (+) SKF10047, and EKC on ACh release was reversed by 0.1 microM haloperidol. Given that PCP has been shown to stimulate basal DA release in this preparation, it is possible that PCP, EKC and (+) SKF10047 inhibit ACh release indirectly by stimulating DA release. The naloxone-induced blockade of the effect of PCP and these benzomorphans is discussed in relation to the effects of naloxone on other systems known to influence ACh release.     

The occurrence of cross-tolerance between morphine and ethyl-ketocyclazocine using the tail-flick test: Lack of effect of diazepam,phenobarbital, or amphetamine

Experiments were designed to test for short-term tolerance to morphine and ethyl-ketocyclazocine (EKC), mu and kappa agonists, respectively, and cross-tolerance between the two drugs. Mice were primed with one of the drugs, using doses that did not affect the tail-flick response when tested at a time 1 or 3 hours later, when the same or alternate test drug was administered. All animals were injected with the priming drug IP. In one series of experiments, the test drugs were given SC, and in the other, the test drugs were injected ICV under brief halothane anesthesia. Priming with morphine (30 or 100 mg/kg) significantly raised the ED₅₀ for ICV morphine. Priming with EKC (2 or 6 mg/kg) similarly elevated the ED₅₀'s for SC and ICV EKC. Symmetrical cross-tolerance was produced in experiments where the test drugs were administered SC when tested at 3 hrs. The effects of priming with EKC on morphine analgesia was evident when the interval between priming and test drugs was 1 hour. When the test drugs were given ICV, cross-tolerance was also symmetrical: priming with EKC significantly raised the ED₅₀ for morphine and priming with morphine raised the ED₅₀ for EKC when tested at 3 hrs. These data suggest that both agonists act on a common site to produce analgesia as similar pA₂ values for naloxone antagonism were determined. The occurrence of short-term tolerance and cross-tolerance to the opiates was unaltered by chronic pretreatment with diazepam, phenobarbital, or amphetamine.     

Prejunctional effects of opioids in the perfused mesentery of the rat and rabbit: interactions with alpha 2-adrenoceptors.

Prejunctional effects of opioids were examined in the perfused mesentery of two species: the rat and rabbit. Use of agonists selective for subtypes of mu, delta, and kappa opioid receptors produced no effect on contractile responses to adrenergic nerve stimulation in the rat perfused mesentery, except for small effects of the kappa agonist EKC, which may be non specific. In contrast, mu, delta and kappa receptors appear to be present in the rabbit. The mu selective agonist, DAMGO, kappa agonist, ethylketocyclazocine, and delta agonists, DPDPE and [Leu5]-enkephalin, all produced significant inhibition of contractile responses to transmural nerve stimulation. The inhibitory effect was greatest for ethylketocyclazocine. To test the possibility that prejunctional activation of alpha 2 adrenoceptors with endogenous norepinephrine might decrease the activity of prejunctional opioid receptors in the rabbit, inhibitory effects of delta and kappa selective agonists were tested in the presence of 10(-7) M yohimbine. Inhibitory responses of the kappa selective agonist ethylketocyclazocine were enhanced, while that of delta selective agonists [Leu5]-enkephalin and DPDPE remained unchanged when yohimbine was present. Thus, the effects of opioids vary and depend on the tissue and receptor subtypes they act upon. Furthermore, the enhanced inhibitory effect of opioid receptor activation in the presence of yohimbine is not found for all opioid receptors.     

Phorbol ester suppression of opioid analgesia in rats

Protein kinase C (PKC) has been shown to be an important substrate in intracellular signal transduction. Very little is known concerning its possible role in mediating opiate-induced analgesia. In the present study, 12-O-tetradecanoylphorbol 13-acetate (TPA), a selective activator of PKC, was injected intrathecally (ith) to assess its influence on the analgesia induced by intrathecal injection of the mu opioid agonist PL017, the delta agonist DPDPE and the kappa agonist 66A-078. Radiant heat-induced tail flick latency (TFL) was taken as an index of nociception. TPA in the dose of 25-50 ng, which did not affect the baseline TFL, produced a marked suppression of opioid antinociception, with a higher potency in blocking mu and delta than the kappa effect. In addition, mu and delta agonists induced remarkable decreases in spinal cyclic AMP (cAMP) content whereas the kappa effect was weak. The results suggest a cross-talk between the PKC system and the signal transduction pathway subserving opioid analgesia.     

Antagonism by nalmefene of systemic and intrathecal morphine-induced analgesia in mice

Nalmefene is an orally active opiate antagonist structurally related to naloxone and naltrexone. In this study using two different strains of mice (Swiss Cox and ICR), the antagonist activity of nalmefene given subcutaneously (sc) was quantified by determination of the apparent pA2 values against the antinociceptive activity (tail flick and hot plate tests) of morphine given sc or intrathecally (lumbar spinal cord). The apparent pA2 values (constrained to a slope of -1) were 8.06 (7.79-8.33) in Swiss Cox mice and 7.81 (7.62-8.00) in ICR mice in the tail flick test with sc morphine. These values were larger than the corresponding value for naloxone in ICR mice, 7.35 (7.10-7.60). The hot plate test provided similar results: the apparent pA2 values for nalmefene with sc morphine were 8.14 (7.89-8.39) in Swiss Cox mice and 7.81 (7.65-7.97) in ICR mice, values which were different from naloxone 7.33 (7.23-7.42) in ICR mice. Apparent pA2 values for nalmefene with intrathecal morphine were not different from those for naloxone in the tail flick test. Thus, these sets of results suggest that it may be worthwhile to further determine whether systemic nalmefene might possibly possess an advantage over naloxone in antagonizing systemic side effects of morphine arising from local spinal morphine administration.     

Potentiation of analgesia and reversal of tolerance to morphine by calcium channel blockers

Effect of four calcium channel blockers (CCBs) belonging to different chemical classes, alone and in combination with morphine was investigated on two models of pain sensitivity, i.e. formalin and tail flick tests in mice. All the studied CCBs, i.e. diltiazem, flunarizine, nimodipine and verapamil inhibited formalin-induced pain responses; however, with verapamil, though there was a trend towards a reduction of paw-licking response to formalin, it was not found to be statistically significant. In contrast, none of the CCBs affected the tail flick latency at any of the doses studied. Morphine, a mu-receptor agonist exerted a significant analgesic effect in formalin as well in tail flick tests. Pretreatment with all CCBs significantly enhanced the analgesic effect of morphine in both tests of nociception. Further, concomitant administration of one of the CCBs, diltiazem with morphine prevented the development of tolerance to the latter. However, combination of diltiazem with morphine, like morphine alone was found to be ineffective in morphine tolerant animals. Results, thus, show that CCBs produced an analgesic effect of their own in formalin-induced tonic pain and potentiated the analgesic activity of morphine. They also modulated opioid-induced tolerance.     

Receptor-related interactions of opiates with PGE-induced adenylate cyclase in brain

The inhibition by opiates of the PGE2-induced formation of cAMP in slices from rat brain striatum was investigated. A maximal, 3.5-fold increase over the basal level of cAMP was obtained with an EC50 for PGE2 of 3 microM. Opiate agonists of both mu and kappa type were inhibitory. The IC50 values for morphine, levorphanol and ethylketocyclazocine (EKC) were 110 nM, 80 nM and 25 nM, respectively. These values were similar to the potencies of the compounds in displacing stereospecifically bound 3H-etorphine in rat brain membranes. As evidenced by the inactivity of dextrorphan, the inhibition of PGE2-dependent cAMP formation was stereospecific. Also ineffective were the opiate antagonists naloxone, naltrexone and MR 2266. These compounds did, however, reverse the inhibition by agonists, displaying thereby selectivity toward the putative mu and kappa opiates. Thus, the inhibition by morphine was antagonized to a greater degree by naloxone than by MR 2266, and the action of EKC was blocked more effectively by MR 2266 relative to naloxone.     

Neonatal administration of beta-endorphin produces "chronic" insensitivity to thermal stimuli

Male and female rat pups were injected with β-endorphin, naloxone or a saline control solution during days 2–7 postnatally. At 90 days of age the rats were tested for analgesia with the tail flick test. Testing was conducted during the first 2 hours of the light and the dark cycle. In both sexes and during both phases of the light cycle rats treated with β-endorphin as infants evidenced a significant elevation in threshold for painful thermal stimuli. Early treatment with naloxone also resulted in elevated threshold for thermal stimuli. Administration of naloxone to these rats as adults did not reverse the analgesic effect. It was concluded that early exposure to β-endorphin results in permanent changes in behavior perhaps by altering the interaction of endogenous opiates with their binding sites during a ciritcal period of opiate receptor development.     

Opioid control of the ruminant stomach motility: functional importance of mu, kappa and delta receptors

In sheep, the subcutaneous (SC) or intracerebroventricular (ICV) administration of the mu-type opioid agonists, fentanyl and morphine, evokes a blockade of the cyclic contractions of the reticulum. A similar inhibition of forestomach motility was recorded following the administration of the two enkephalin analogs, D-Ala2-Met5-enkephalinamide (DAMA) and D-Ala2-D-Leu5-enkephalin (DADLE) which are mixed mu - delta opioid agonists. In contrast, the reticular contractions were enhanced by the SC or ICV administration of the kappa type agonist, ethylketazocine (EKC) and U - 50 488 H. The proximal duodenum motor activity was transiently increased resulting in the occurrence of a phase III-like activity by these opioid agonists, regardless of the subtypes. The effects of the opioid agonists on reticular motility were prevented by the injection of naloxone but not by the quaternary parent compound methylnaloxone which does not cross the blood-brain barrier. The duodenal motor effects elicited by the opioid agonists were antagonized by both naloxone and methylnaloxone. The results suggest that the inhibition of the ruminant stomach motility is centrally mediated by mu - delta type opioid agonists and are consistent with opposite effects from kappa type opioid agonists. The stimulatory effect of peptide and non-peptide opioid agonists on the duodenum may result in part from direct opioid receptor-mediated actions on smooth muscle.     

Opioid receptor agonists in the rabbit colon: comparison of in vivo and in vitro studies

Myoelectrical activity was recorded in the proximal and distal colon of rabbits using chronically implanted electrodes. The motility in both the proximal and distal colon was inhibited by the intravenous (IV) administration of the following opioid agonists for mu receptors: morphine and fentanyl, kappa receptors: ethylketazocine (EKC) and U 50 488 H, and delta receptors: D-Ala2 D-Leu5-enkephalin (DADLE) and D-Ser2 Leu-enkephalin-Thr6 (DSLET). In contrast, the myoelectric activity in the distal colon was increased during the infusion of an endogenous kappa opioid agonist, dynorphin (DYN). All of these effects were prevented by naloxone pretreatment. During in vitro studies using extraluminal force transducers, fentanyl, U 50 488 H and DSLET inhibited spontaneous contractions of the proximal colon, but U 50 488 H and DSLET caused a substantial increase in the motility of the distal colon. The observed motor responses in the proximal and distal colon following opioid agonist administration indicate that the control of these two intestinal segments may be different. It is suggested that the stimulatory effect of dynorphin on the distal colon is peripherally-mediated while inhibition of the whole colon by opioid agonists regardless of subtypes seems to be centrally-mediated.     

Effect of naloxone on analgesia induced by food deprivation

Naloxone (4 mg/kg) or saline was administered to animals under food deprived and non-deprived conditions prior to testing pain sensitivity in the tail flick test. Food deprived animals exhibited significantly elevated latencies in comparison to latencies observed under non-deprived conditions. This analgesia was diminished by treatment with the opiate receptor antagonist, naloxone. These findings suggest that analgesia induced by food deprivation is mediated in part by opiate receptor systems.