Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0344307 (analgesia)
28,200 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Activation of the immune system in response to either infection or lipopolysaccharide (LPS) produces neurophysiological, neuroendocrine and behavioral changes. Some of the physiological consequences of LPS are mediated by endogenous opioid peptides. The following studies were designed to characterize the effects of LPS in several behavioral paradigms, and to determine the role of opioids in mediating these effects. The effects of LPS on locomotor and self-care activity were assessed in the open field test. Rats were injected with either saline or a dose of LPS (25, 50, 100, or 1000 micrograms/kg). 4 h later, the animals were placed in an open field and the numbers of line crossings, rearings and grooming episodes were counted. LPS significantly suppressed the three open field behaviors in a dose-related manner. The effect of LPS on sensitivity to pain was determined using the hot-plate and tail-flick tests. Administration of LPS (200 micrograms/kg) increased pain sensitivity in the hot plate test 30 min after drug administration, but produced a significant analgesic response 4 h after drug administration in both tests. Further characterization of LPS-induced analgesia demonstrated that it began about 2 h after and disappeared 30 h after the administration of LPS. Administration of naltrexone completely blocked the analgesic effects of LPS 4 h after its administration, but had no effect on LPS-induced suppression of activity in the open field. The effect of LPS on body temperature was biphasic, producing hypothermia at 2 h and hyperthermia at 8-30 h after its administration. Naltrexone had no effect on the body temperature changes induced by LPS.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Behavioral effects of lipopolysaccharide in rats: involvement of endogenous opioids. 792 30

Six opiate agonists were characterized by in vivo apparent pA2 analysis with respect to their discriminative stimulus, rate-decreasing and analgesic effects, by using the antagonist naltrexone. In drug discrimination experiments, rats were trained to discriminate 3.2 mg/kg of morphine from saline under a fixed-ratio 15 schedule of food reinforcement. In analgesia experiments, rat's tails were immersed into 55 degrees C water and latency for tail withdrawal was measured. Naltrexone (0.01-1.0 mg/kg) antagonized discriminative stimulus effects of all agonists, rate-decreasing effects of etorphine, morphine, fentanyl, buprenorphine and GPA 1657 [(1)-B-2'-hydroxy-2,9-dimethyl-5-phenyl-6,7-benzomorphan] and analgesic effects of etorphine, morphine, buprenorphine and GPA 1657. Analgesic effects of fentanyl and nalbuphine were not tested. Naltrexone apparent pA2 values across the three behavioral measures were etorphine (7.2-7.4 mol/kg), fentanyl (7.3-7.4 mol/kg), morphine (7.5-8.4 mol/kg), GPA 1657 (7.0-7.3 mol/kg), buprenorphine (7.5-7.7 mol/kg) and nalbuphine (7.7 mol/kg). Apparent pA2 values averaged 7.5 mol/kg and slopes of the naltrexone Schild regressions were not different from unity, suggesting that the measured behavioral effects of these agonists are mediated by mu opioid receptors. Nalbuphine also was used as an antagonist in the tail-withdrawal assay. The apparent pA2 values for nalbuphine were etorphine (4.9 mol/kg), morphine (5.9 mol/kg), GPA 1657 (5.7 mol/kg) and buprenorphine (5.5 mol/kg). Slopes of the Schild regressions differed, suggesting that nalbuphine's modest analgesic effects may have prevented proper conditions for an accurate Schild analysis.
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PMID:In vivo apparent pA2 analysis for naltrexone antagonism of discriminative stimulus and analgesic effects of opiate agonists in rats. 796 18

Morphine, U50-488, and (-)-lobeline produced dose-related shortening of a low-intensity thermally evoked tail avoidance response (LITETAR) (e.g., hyperalgesia) when microinjected into the dorsal posterior mesencephalic tegmentum (DPMT) of conscious rats. The hyperalgesic potency of (-)-lobeline was greater than either morphine or U50-488. With higher doses, morphine's hyperalgesic actions diminished and prolongation of the LITETAR (e.g., analgesia) was observed. Naltrexone produced analgesia in the DPMT that diminished with increasing dose. The hyperalgesic actions of morphine, U50-488, and (-)-lobeline further suggest the presence of kappaergic opioid and nicotinic mechanisms in the DPMT of rats. The hyperalgesic actions of U50-488, a highly specific opioid kappa-receptor agonist, strongly suggest the presence of a kappa-opioidergic hyperalgesic mechanism in the DPMT.
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PMID:Hyperalgesic and analgesic actions of morphine, U50-488, naltrexone, and (-)-lobeline in the rat brainstem. 811 22

A study was undertaken to investigate the relationship between morphine-induced analgesia and immunosuppression after acute administration. In male CD1 mice, morphine (10.0-100.0 mg/kg s.c.) produced a U-shaped immunosuppressive dose-effect curve on splenic natural killer (NK) activity. Morphine also induced dose-related analgesia, as measured by an increase in tail-flick latency during thermal application; these analgesic effects were antagonized by naltrexone (1.0-10.0 mg/kg). In addition, morphine-induced suppression of splenic NK activity was antagonized in a dose-dependent manner and, at one dose of naltrexone (10.0 mg/kg), splenic NK activity was augmented. To investigate further the relationship between naltrexone antagonism of morphine-induced analgesia and immunomodulation, single doses of morphine (10.0-100.0 mg/kg) were administered to mice pretreated with naltrexone (0.01-10.0 mg/kg) or saline. A dose of 10.0 mg/kg of morphine produced 35% of the maximal possible effect in the analgesia study and no immunosuppression, whereas a dose of 32.0 mg/kg produced a maximal analgesic effect and significant suppression of NK activity. Naltrexone blocked morphine-induced analgesia and immunosuppression in a dose-dependent fashion. Moreover, the combination of 1.0 mg/kg of naltrexone and 32.0 mg/kg of morphine elevated splenic NK activity. A large dose of morphine (100.0 mg/kg) elicited full analgesia and had no effect on splenic NK activity in saline- or naltrexone-pretreated mice. Collectively, these results support the view that, in mice, morphine-induced analgesia and immunosuppression are mediated through a common opioid receptor type.
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PMID:Naltrexone antagonizes the analgesic and immunosuppressive effects of morphine in mice. 818 37

Supraspinal opioid analgesia is mediated in part by connections between the midbrain periaqueductal gray (PAG) and rostral ventral medulla (RVM) which includes the nuclei raphe magnus and reticularis gigantocellularis. Serotonergic 5HT2 and 5HT3 receptor subtypes appear to participate in this pathway since general and selective serotonergic antagonists microinjected into the RVM significantly reduced morphine analgesia elicited from the PAG. Since both an enkephalinergic pathway between the PAG and RVM and intrinsic enkephalinergic cells in the RVM exist, the present study evaluated the abilities of general (naltrexone), mu-selective (beta-funaltrexamine: B-FNA) and delta 2-selective (naltrindole) opioid receptor subtype antagonists microinjected into the RVM to alter morphine (2.5 micrograms) analgesia elicited from the PAG as measured by the tail-flick and jump tests. Mesencephalic morphine analgesia was significantly reduced after pretreatment in the RVM with naltrexone (1-10 micrograms), B-FNA (0.5-5 micrograms) or naltrindole (0.5-5 micrograms). Naltrexone in the RVM failed to alter basal nociceptive thresholds and none of the opioid antagonists were effective in reducing mesencephalic morphine analgesia when they were microinjected into placements lateral or dorsal to the RVM. These data indicate that mu and delta 2 opioid receptors in the RVM modulate the transmission of opioid pain-inhibitory signals from the PAG.
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PMID:Medullary mu and delta opioid receptors modulate mesencephalic morphine analgesia in rats. 825 87

The ability of the competitive opioid antagonist, naltrexone, to protect opioid receptors from inactivation by the nonequilibrium antagonists, beta-funaltrexamine (beta-FNA) and nor-binaltorphimine (nor-BNI), was examined in vivo. Male rats were injected SC with 10 mg/kg naltrexone or saline, 30 min before being injected intracisternally (IC) with water, 10 micrograms beta-FNA, or 1.0 or 10 micrograms nor-BNI. The rats were tested for analgesic responses to either U69,593 (nor-BNI groups) or morphine (beta-FNA groups), on a 50 degrees C hot plate, 24 h later. Morphine produced dose-related increases in the latency to paw lick in rats that received water (IC) (mean ED50 = 3.2 mg/kg). Little or no analgesia occurred after 1.0-30 mg/kg of morphine in animals that had received saline (SC) and 10 micrograms beta-FNA (IC) 24 h earlier. Pretreatment with 10 mg/kg naltrexone attenuated the antagonist effects of beta-FNA (morphine ED50 = 10.8 mg/kg). U69,593 also produced analgesia in animals that received water (IC) (ED50 = 0.97 mg/kg). This analgesia was dose-dependently blocked by nor-BNI for up to 7 days. Naltrexone did not inhibit the actions of nor-BNI. Thus, naltrexone prevented inactivation of mu receptors by beta-FNA but not inactivation of kappa receptors by nor-BNI, suggesting that antagonist interactions with mu receptors are different from those with kappa receptors.
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PMID:Naltrexone in vivo protects mu receptors from inactivation by beta-funaltrexamine, but not kappa receptors from inactivation by nor-binaltorphimine. 830 60

The effects of ethylketazocine, U-50,488, morphine and (-)-nicotine administered both i.p. and into the mid-fourth ventricle of intact rats were investigated using a conventional high intensity tail-flick reflex and one evoked with a lower intensity thermal stimulus. The sensitivity of the low intensity thermally evoked tail avoidance reflex was several times that of a high intensity tail-flick reflex in detecting the analgesic activity of morphine and yielded valid assays and relative potencies between morphine (1), EKC (18.76) and U-50,488 (0.23) when the drugs were administered ip. When the opioid drugs were administered into the fourth ventricle they produced a dose-related shortening of the latency of the low intensity thermally evoked tail avoidance reflex. (-)-Nicotine, when administered into the mid-fourth ventricle, produced analgesia in low doses and hyperalgesia in high doses. Naltrexone and mecamylamine, when administered into the fourth ventricle, produced a dose-related analgesia. Doses of naltrexone and mecamylamine which antagonize maximally hyperalgesic doses of (-)-nicotine and ethylketazocine did not produce analgesia; however, larger doses produced analgesia. These observations suggest that analgesic doses do not involve prototypic kappa opioidergic or nicotinic mechanisms. These data confirm the existence of a medullary hyperalgesic center which may have both mu and kappa opioidergic as well as nicotinic mechanisms. Furthermore, these data indicate that this medullary hyperalgesic mechanism may have spontaneous or evoked tone and provide an explanation for the analgesic action of naltrexone and mecamylamine.
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PMID:Pharmacologic characteristics of a medullary hyperalgesic center. 838 37

Effects of naltrexone administered intravenously on the pharmacological actions and kinetics of morphine in serum following intravenous administration of morphine were determined in male Sprague-Dawley rats. A 10 mg/kg dose of morphine produced an analgesic response as measured by the tail flick test. Morphine also produced a hyperthermic effect. Naltrexone dose (0.625-2.5 mg/kg)-dependently antagonized the analgesic and hyperthermic effects of morphine. The effect of naltrexone (0.625 and 2.5 mg/kg) on the pharmacokinetic parameters area under the serum morphine concentration time curve (AUC0-->infinity), serum levels of morphine extrapolated to zero time (Cmax), half-life (t1/2), mean residence time (MRT), total body clearance (Clt), and volume of distribution at steady state (Vss) of morphine in serum was determined. Naltrexone (0.625 mg/kg) significantly increased AUC0-->infinity, Cmax, t1/2 MRT, but decreased the Vss, elimination rate constant (k) and Clt. The higher dose of naltrexone (2.5 mg/kg) produced an increase in the Cmax value of morphine in the serum, but the other pharmacokinetic parameters were unaffected. Since increased morphine concentrations in serum produced by naltrexone cannot explain its antagonistic effects on analgesia and hyperthermia, it is concluded that naltrexone produces its effects by blocking opiate receptors at the appropriate sites. The increases in serum morphine levels by naltrexone may be related to displacement of morphine from protein binding sites and inhibition of morphine metabolism by glucuronyl transferase. This study for the first time demonstrates that in the rat, when morphine and naltrexone are given concurrently, although serum levels of morphine increase, pharmacological effects of morphine are antagonized.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of naltrexone on pharmacodynamics and pharmacokinetics of intravenously administered morphine in the rat. 844 58

In addition to brainstem sites of action, analgesia can be elicited following amygdala microinjections of morphine and mu-selective opioid agonists. The present study examined whether opioid analgesia elicited by either morphine or beta-endorphin in the amygdala could be altered by either the general opioid antagonist, naltrexone, the mu-selective antagonist, beta-funaltrexamine (BFNA) or the delta 2 antagonist, naltrindole isothiocyanate (Ntii) in the periaqueductal gray (PAG). Both morphine (2.5-5 micrograms) and beta-endorphin (2.5-5 micrograms) microinjected into either the baso-lateral or central nuclei of the amygdala significantly increased tail-flick latencies and jump thresholds in rats. The increases were far more pronounced on the jump test than on the tail-flick test. Placements dorsal and medial to the amygdala were ineffective. Naltrexone (1-5 micrograms) in the PAG significantly reduced both morphine (tail-flick: 70-75%; jump: 60-81%) and beta-endorphin (tail-flick: 100%; jump: 93%) analgesia elicited from the amygdala, indicating that an opioid synapse in the PAG was integral for the full expression of analgesia elicited from the amygdala by both agonists. Both BFNA (68%) and Ntii (100%) in the PAG significantly reduced morphine, but not beta-endorphin analgesia in the amygdala on the tail-flick test. Ntii in the PAG was more effective in reducing morphine (60%) and beta-endorphin (79%) analgesia in the amygdala on the jump test than BFNA (15-24%). Opioid agonist-induced analgesia in the amygdala was unaffected by opioid antagonists administered into control misplacements in the lateral mesencephalon, and the small hyperalgesia elicited by opioid antagonists in the PAG could not account for the reductions in opioid agonist effects in the amygdala. These data indicate that PAG delta 2, and to a lesser degree, mu opioid receptors are necessary for the full expression of morphine and beta-endorphin analgesia elicited from the amygdala.
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PMID:Opioid antagonists in the periaqueductal gray inhibit morphine and beta-endorphin analgesia elicited from the amygdala of rats. 900 99

The present study examined the effect of in vivo antisense oligodeoxynucleotide treatment on naltrexone (NTX)-induced functional supersensitivity and mu-opioid receptor up-regulation in mice. On day 1 mice were implanted S.C. with a NTX or placebo pellet and injected I.T. and I.C.V. with dH2O or oligodeoxynucleotides. The oligodeoxynucleotides were designed so that they were either perfectly complementary to the first 18 bases of the coding region of mouse mu-opioid receptor mRNA, or had one (Mismatch-1) or four (Mismatch-4) mismatches. On days 3, 5, 7, and 9, mice were again injected I.T. and I.C.V. with dH2O or one of the oligodeoxynucleotides. After the final injections on day 9, placebo and NTX pellets were removed, and 24 h later mice were tested for morphine analgesia or sacrificed for saturation binding studies ([3H]DAMGO). Naltrexone increased the analgesic potency of morphine in dH2O treated mice by approximately 70%. In binding studies, NTX significantly increased density of brain (approximately 60%) and spinal cord (approximately 140%) mu-opioid receptors without affecting affinity. The mu-opioid antisense and the oligodeoxynucleotide with one mismatch (Mismatch-1) significantly reduced the potency of morphine by approximately twofold in placebo-treated mice. The oligodeoxynucleotide with four mismatches (Mismatch-4) did not significantly alter morphine potency. When placebo-treated mice were treated with either the antisense to the mouse mu-opioid receptor, Mismatch-4 or Mismatch-1 there were no significant changes in the density of mu-opioid receptors. Thus, mu-opioid antisense significantly reduced morphine potency without changing mu-opioid receptor density. When NTX and oligodeoxynucleotide treatments were combined, there was no change in NTX-induced supersensitivity and mu-opioid receptor upregulation. These data suggest that opioid antagonist-induced supersensitivity and upregulation of mu-opioid receptors does not involve changes in gene expression.
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PMID:The effect of mu-opioid receptor antisense on morphine potency and antagonist-induced supersensitivity and receptor upregulation. 912 24


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