Effects of naloxone and fentanyl in acutely decerebrated dogs

Cardiovascular, respiratory and analgesic effects of fentanyl and naloxone were studied in normotensive acutely decerebrated dogs. Naloxone (1 mg/kg, i.v.) increased skin twitch reflex latency, mean blood pressure, pulse pressure, respiratory rate and minute volume. Fentanyl (50 μg/kg, i.v.) decreased heart rate and blood pressure while the animals were artificially ventilated. The skin twitch reflex latency was not significantly altered. Nine minutes later, naloxone (1 mg/kg, i.v.) was administered and the fentanyl-induced cardiovascular depression was reversed above the control level. The skin twitch reflex latency remained unchanged. These findings give further evidence that the endogenous opioid system plays an important role in the brainstem control of circulation and respiration. The mechanism of the anomalous analgesic response of the acutely decerebrated dog requires further investigation.     

The hyperalgesic effects of prostacyclin and prostaglandin E2.

Hyperalgesia induced in rat paws or dog knee joints by prostacyclin (PGI2) and prostaglandin E2 was measured by a modification of the Randall-Selitto method (1) or by the degree of incapacitation (2). In both species PGI2 induced an immediate hyperalgesic effect but the effect of PGE2 had a longer latency. Low doses of PGI2 caused a short lasting effect but PGE2, large doses of PGI2 or successive administration of small doses of PGI2 caused a long lasting effect. It is suggested that prostacyclin mediates rat paw hyperalgesia induced by carrageenin. The long lasting hyperalgesic effect of PGE2 and high doses of PGI2 is possibly an indirect effect caused by stimulation of a sensory nerve sensitising mechanism.     

The hyperalgesic effects of prostacyclin and prostaglandin E2

Hyperalgesia induced in rat paws or dog knee joints by prostacyclin (PGI₂) and prostaglandin E₂ was measured by a modification of the Randall-Selitto method (1) of by the degree of incapacitation (2). In both species PGI₂ induced an immediate hyperalgesic effect but the effect of PGE₂ had a longer latency. Low doses of PGI₂ caused a short lasting effect but PGE₂, large doses of PGI₂ or successive administration of small doses of PGI₂ caused a long lasting effect.It is suggested that prostacyclin mediates rat paw hyperalgesia induced by carrageenin. The long lasting hyperalgesic effect of PGE₂ and high doses of PGI₂ is possibly an indirect effect caused by stimulation of a sensory nerve sensitising mechanism.     

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.     

Polysaccharide peptides from COV-1 strain of Coriolus versicolor induce hyperalgesia via inflammatory mediator release in the mouse

Polysaccharide peptide (PSP), isolated from Coriolus versicolor COV-1, has been widely used as an adjunct to cancer chemotherapy and as an immuno-stimulator in China. In this study, the anti-nociceptive effects of PSP were investigated in two different pain models in the mouse. In the acetic acid-induced writhing model, initial studies showed that PSP decreased the number of acetic acid-induced writhing by 92.9%, which, by definition, would constitute an analgesic effect. However, further studies showed that PSP itself induced a dose-dependent writhing response. Studies on inflammatory mediator release showed that PSP increased the release of prostaglandin E2, tumor necrosis factor-alpha, interleukin-1beta, and histamine in mouse peritoneal macrophages and mast cells both in vitro and in vivo. The role of inflammatory mediator release in PSP-induced writhing was confirmed when diclofenac and dexamethasone decreased the number of writhing responses by 54% and 58.5%, respectively. Diphenhydramine totally inhibited the PSP-induced writhing. In the hot-plate test, PSP dose-dependently shortened the hind paw withdrawal latency, indicative of a hyperalgesic effect. The hyperalgesic effect was reduced by pretreatment with the anti-inflammatory drugs. In conclusion, the PSP-induced hyperalgesia was related to activation of peritoneal resident cells and an increase in the release of inflammatory mediators.     

Calotropis procera latex-induced inflammatory hyperalgesia--effect of antiinflammatory drugs

The milky white latex of plant Calotropis procera produces inflammation of the skin and mucous membranes on accidental exposure. It produces edema on local administration due to the release of histamine and prostaglandins and is associated with hyperalgesia. In the present study we have evaluated the antiedematous and analgesic activity of antiinflammatory drugs against inflammatory response induced by dried latex (DL) of C procera in rat paw edema model. An aqueous extract of DL of C procera was injected into the subplantar surface of the rat paw and the paw volume was measured by a plethysmometer at 0, 1, 2, 6, 12, and 24 hours. Concomitantly the hyperalgesic response was also evaluated by motility test, stair climbing ability test, dorsal flexion pain test, compression test, and observing the grooming behavior. The inhibitory effect of diclofenac and rofecoxib on edema formation and hyperalgesic response was compared with cyproheptadine (CPH). DL-induced edema formation was maximum at 2 hours that was associated with decreased pain threshold, functional impairment, and grooming. Treatment with antiinflammatory drugs and CPH significantly attenuated the edematous response and grooming, increased the pain threshold, and improved functional parameters. Both antiinflammatory and antiserotonergic drugs significantly inhibited the hyperalgesia associated with DL-induced paw edema. Rofecoxib was found to be superior than diclofenac and was as effective as CPH in ameliorating the hyperalgesia. However, it was found to be less effective than CPH in attenuating edema formation.     

Antagonism of the effects of pentobarbital in the chronic spinal dog by naltrexone

Some of the actions of pentobarbital in the chronic spinal dog were antagonized by naltrexone. Pentobarbital depressed the flexor reflex and the level of consciousness, and these actions of pentobarbital were partially antagonized by naltrexone. Naltrexone alone did not alter these functions. Pentobarbital also increased the latency of the skin twitch reflex, decreased pupillary diameter and depressed pulse and respiratory rates. The data are consistent with the hypothesis that some of the actions of pentobarbital may be mediated through functional systems involving the ? receptor.     

III - Prostaglandin hyperalgesia: relevance of the peripheral effect for the analgesic action of opioid-antagonists

Morphine injected into the rat cerebral ventricles had a marked analgesic effect, while no effect was observed with pentazocine and naloxone or nalorphine caused a strong hyperalgesia. Administered systemically (IP) naloxone and nalorphine caused a transitory analgesia followed by a long lasting hyperalgesic effect; morphine and pentazocine showed only an analgesic effect. It was concluded that the site of analgesic action of opioid-antagonists is peripheral rather than central. The peptidase-resistant enkephalin-analog, BW 180c, which does not cross the blood brain barrier, caused a marked analgesia by IP administration to paws made hyperalgesic by PGE2 or carrageenin. It is suggested that agents derived from morphine, morphine-antagonists, enkephalins or cGMP devoid of central effect but having a strong peripheral effect may constitute a new class of safer analgesics.     

III - Prostaglandin hyperalgesia: Relevance of the peripheral effect for the analgesic action of opioid-antagonists

Morphine injected into the rat cerebral ventricles had a marked analgesic effect, while no effect was observed with pentazocine and naloxone or nalorphine caused a strong hyperalgesia. Administered systemically (IP) naloxone and nalorphine caused a transitory analgesia followed by a long lasting hyperalgesic effect; morphine and pentazocine showed only an analgesic effect. It was concluded that the site of analgesic action of opioid-antagonists is peripheral rather than central. The peptidase-resistant enkephalin-analog, BW 180c, which does not cross the blood brain barrier, caused a marked analgesia by IP administration to paws made hyperalgesic by PGE₂ or carrageenin. It is suggested that agents derived from morphine, morphine-antagonists, enkephalins or cGMP devoid of central effect but having a strong peripheral effect may constitute a new class of safer analgesics.     

The effect of heat conditioning of the primary area before and after induction of hyperalgesia by topical/intradermal capsaicin or by controlled heat injury

The aim of the present study was to test the effect of heat conditioning before and after the induction of hyperalgesia. Three different methods were used for induction of hyperalgesia, topical capsaicin, intradermal capsaicin injection, and a controlled heat injury. The vascular (blood flow and skin temperature) and sensory changes (area of secondary hyperalgesia and ongoing pain) associated with the cutaneous hyperalgesia were compared. Each experiment consisted of two randomized sessions separated by at least 2 days. In one session, pre-conditioning of the skin by heat was performed 30 min before the induction of hyperalgesia using a probe at 45°C for 5 min in the center of the expected primary hyperalgesic area. After the induction of hyperalgesia, heat conditioning was performed twice in the center of the primary hyperalgesic area using a temperature of 2°C above the present individual pain threshold. On the contra-lateral arm, no heat conditioning was applied while hyperalgesia was induced using the same method. This session was evaluated as a control. The preconditioning induced an increased skin temperature in the primary area for both topical capsaicin and the controlled heat injury. Postconditioning caused increased blood flow in the secondary hyperalgesic area for the topical capsaicin method and increased blood flow in the primary hyperalgesic area for the controlled heat injury method. However, conditioning with heat in an attempt to increase the C-fiber input did not have any effect on the ongoing pain ratings and sensory test results in any of the methods. The results of the present study suggest that there is still a need for a better experimental model with more stable allodynia both between sessions and between subjects while at the same time minimizing discomfort to the volunteer.     

I - Prostaglandin hyperalgesia, a cAMP/Ca2+ dependent process.

Prostaglandins stimulate cAMP increase in several biological systems including CNS. The possible participation of a cAMP/Ca2+ related mechanism in prostaglandin induced hyperalgesia in the rat paw, as measured by a modification of the Randall-Selitto method was investigated. A serie of agents was administered in the paw in an attempt to change either Ca2+ or cyclic AMP concentration at the nociceptive terminations. PGE2, dibutyryl cyclic AMP, isoprenaline, noradrenaline, adrenaline, Ca2+ionophore (A23187), BaCl2 caused a dose dependent hyperalgesia. The hyperalgesic effect of these substances was enhanced by methyl-xanthines. Cyclic GMP as well as agents which interfere with Ca2+ influx (verapamil and lanthanum) were local analgesics in normal and hyperalgesic paws.     

Comparison of dipyrone/propofol versus fentanyl/propofol anaesthesia during surgery in rabbits

In this study, the investigation of the intraoperative effects of dipyrone (metamizol) on heart rate (HR), mean arterial pressure (MAP) and analgesic efficacy in rabbits is described for the first time. This was carried out to evaluate the cardiovascular stability achieved using dipyrone compared with fentanyl. In this prospective study, 17 female New Zealand White rabbits were randomly allocated to either one of two groups: dipyrone/propofol (DP) or fentanyl/propofol (FP). Anaesthesia was induced in both groups using propofol to effect (4.0-8.0 mg/kg intravenously) until the swallowing reflex was lost for intubation. After induction, anaesthesia was maintained with continuous infusion of propofol 1.5-1.7 mg/kg/min intravenously. Analgesics were then injected in defined boluses of either dipyrone 65 mg/kg or fentanyl 0.0053 mg/kg. After surgical tolerance, defined as loss of the ear pinch reflex and loss of the anterior and posterior pedal withdrawal reflex, was achieved, two surgical procedures were performed. The surgical procedures (implantation of either a pacemaker or an electrocardiogram transmitter), both require a comparable level of analgesic depth. During and after surgery, clinical variables, such as MAP, HR, peripheral arterial oxygen saturation (SpO?) and end-tidal CO? (P(E')CO?) were recorded simultaneously every 2 min. Eight time points were chosen for comparison: baseline, surgical tolerance (ST), values at 10, 20 and 30 min after reaching ST, values at the end of propofol infusion (EI) and data at 10 and 20 min after EI. Both FP and DP combinations provided effective anaesthesia and analgesia in rabbits. In both groups a significant decrease of HR and MAP was measured. The results of this study indicate that the non-opioid drug dipyrone produces similar analgesic and even better cardiovascular effects by trend in rabbits. Therefore we conclude that dipyrone in combination with propofol can be used as an alternative to FP for intraoperative analgesia.     

Cannabinoids and pain responses: a possible role for prostaglandins

The principal metabolite of delta 1-THC, delta 1-THC-7-oic acid exhibits significant analgesic action in the mouse hot plate test. The parent delta 1-THC has a similar effect when measured at later time points; however, 10 min after drug administration, a pronounced hyperalgesia is seen. This hyperalgesia can be inhibited by prior administration of either indomethacin or delta 1-THC-7-oic acid, presumably because of their ability to inhibit eicosanoid synthesis. Administration of prostaglandin E2 (PGE2), at doses that were a small fraction of the delta 1-THC given, resulted in a strong hyperalgesic response. Unlike delta 1-THC, the metabolite does not produce a cataleptic state in the mouse, which eliminates this as a basis for the hot plate response. The evidence presented is consistent with a mechanism in which the metabolite inhibits eicosanoid synthesis whereas the parent drug elevates tissue levels of prostaglandins.     

Inhibition of Calotropis procera latex-induced inflammatory hyperalgesia by oxytocin and melatonin

The latex of the wild growing plant Calotropis procera produces inflammation of the skin and mucous membranes upon accidental exposure. On local administration it elicits an intense inflammatory response due to the release of histamine and prostaglandins that is associated with hyperalgesia. In the present study we have evaluated the anti-inflammatory and antinociceptive activity of oxytocin and melatonin against rat paw edema induced by dried latex (DL) of C procera and compared it with that against carrageenan-induced paw edema. Aqueous extract of DL of C procera or carrageenan (1%) was injected into the subplantar surface of the rat paw and the paw volume was measured at 0, 1, 2, 3, 4, 6, 10, and 24 hours. The associated hyperalgesic response and functional impairment were also evaluated concomitantly by dorsal flexion pain test, motility test, and stair climbing ability test. The inhibitory effect of oxytocin and melatonin on edema formation and hyperalgesic response was compared with dexamethasone. DL-induced edema formation was maximum at 2 hours and was associated with decreased pain threshold and functional impairment. Treatment with melatonin significantly attenuated the edematous response while both oxytocin and melatonin increased the pain threshold and improved functional parameters. Both oxytocin and melatonin significantly inhibited the hyperalgesia associated with DL-induced paw edema. Oxytocin was found to be as effective as melatonin in ameliorating the hyperalgesic response. However, it was found to be less effective than melatonin in attenuating edema formation.     

Production of Hyperalgesic Prostaglandins by Sympathetic Postganglionic Neurons

Prostaglandin E2 and prostacyclin (prostaglandin I2) produce hyperalgesia in animals and humans. Because there is evidence that prostaglandins contribute to pain maintained by sympathetic nervous system activity, we evaluated whether sympathetic postganglionic neurons synthesize these hyperalgesic prostaglandins, and whether production of prostaglandins by these neurons can contribute to sensitization of primary afferent nociceptors. Intradermal injection of arachidonic acid but not linoleic acid, in the rat hindpaw, produces a decrease in mechanical nociceptive threshold. This hyperalgesic effect is prevented by indomethacin, an inhibitor of prostaglandin synthesis or by prior surgical removal of the lumbar sympathetic chain. To test the hypothesis that sympathetic postganglionic neurons are the source of prostaglandins, we measured production of prostaglandin E2 and 6-keto-prostaglandin F1 alpha (the stable metabolite of prostacyclin) by homogenates of adult rat sympathetic postganglionic neurons from superior cervical ganglia. These homogenates produced significant amounts of prostaglandin E2 and 6-keto-prostaglandin F1 alpha, and most of this production is eliminated by neonatal administration of 6-hydroxydopamine which selectively destroys sympathetic postganglionic neurons. These results demonstrate that sympathetic postganglionic neurons produce prostaglandins, and supports further the hypothesis that the release of prostaglandins from sympathetic postganglionic neurons contributes to the hyperalgesia associated with sympathetically maintained pain.     

A cellular mechanism for the bidirectional pain-modulating actions of orphanin FQ/nociceptin

Orphanin FQ/nociceptin (OFQ/N) and its receptor share substantial structural features and cellular actions with classic opioid peptides and receptors, but have distinct pharmacological profiles and behavioral effects. Currently there is an active debate about whether OFQ/N produces hyperalgesia or analgesia. Using a well-defined brainstem pain-modulating circuit, we show that OFQ/N can cause either an apparent hyperalgesia by antagonizing mu opioid-induced analgesia or a net analgesic effect by reducing the hyperalgesia during opioid abstinence. It presumably produces these two opposite actions by inhibiting two distinct groups of neurons whose activation mediates the two effects of opioid administration. OFQ/N antagonism of the hyperalgesia may have significance for the treatment of opioid withdrawal and sensitized pain.     

A spinal site mediates opiate analgesia in frogs

The application of acetic acid to the hind leg of a frog will induce a spinally mediated wiping reflex only if the acetic acid concentration is above a certain threshold. By using this reflex as the basis of a test for nociception, we show that morphine sulfate is a potent analgesic in the frog when injected into the lumbar area of the spinal cord. Significant analgesia is induced within 5 min after injection of as little as 0.0316 μg of morphine sulfate. Low doses of morphine sulfate (0.0316 or 0.1 μg) induce analgesia which dissipates within 1 h while for higher doses (0.316, 1.0 or 3.16 μg) the analgesia persists for at least 3 h. The analgesic effect of 0.316 μg of morphine sulfate is completely blocked by naloxone HCl at either 0.158 or 0.316 μg. Animals receiving naloxone alone (0.316 μg) appear to be slightly hyperalgesic compared to saline injected controls but this effect is not significant.     

Molecular interaction in the mouse PAG between NMDA and opioid receptors in morphine-induced acute thermal nociception

Previous evidence demonstrates that low dose morphine systemic administration induces acute thermal hyperalgesia in normal mice through μOR stimulation of the inositol signaling pathway. We investigated the site of action of morphine and the mechanism of action of μOR activation by morphine to NMDA receptor as it relates to acute thermal hyperalgesia. Our experiments show that acute thermal hyperalgesia is blocked in periaqueductal gray with the μOR antagonist CTOP, the NMDA antagonist MK801 and the protein kinase C inhibitor chelerythrine. Therefore, a site of action of systemically administered morphine low dose on acute thermal hyperalgesic response appears to be located at the periaqueductal gray. At this supraspinal site, μOR stimulation by systemically morphine low dose administration leads to an increased phosphorylation of specific subunit of NMDA receptor. Our experiments show that the phosphorylation of subunit 1 of NMDA receptor parallels the acute thermal hyperalgesia suggesting a role for this subunit in morphine-induced hyperalgesia. Protein kinase C appears to be the key element that links μOR activation by morphine administration to mice with the recruitment of the NMDA/glutamatergic system involved in the thermal hyperalgesic response.     

Sign-reversal during persistent activation in mu-opioid signal transduction

A concept of signal transduction in biological systems specifies that any instantaneous input is appreciated by its departure from the moving average of past activity. The concept provides an adequate account of the occurrence of both the one-directional (e.g. analgesic) effects induced by opioid receptor activation, and of the contra-directional (e.g. hyperalgesic) effects that can be observed when activation is discontinued. Following this transduction concept, the numerical simulations reported here revealed, remarkably, that under some parametric conditions, the input's effect may reverse even as input is maintained at a constant magnitude. In in vitro conditions that are proximal to the signal transduction that occurs when an opioid agonist binds to the G-protein coupled opioid receptor, the effects of opioid receptor activation were monitored by measuring time-dependent Ca(2+) responses in CHO-K1 cells transfected with a mu-opioid receptor and G(alpha 15) protein. The results indicate morphine to produce an initial increase in intracellular Ca(2+) concentration followed by a decrease below basal level. The occurrence of a sign-reversal was confirmed in native conditions of receptor-to-G protein coupling; the continuous in vivo infusion over a 2-week period of 0.31 mg rat(-1)day(-1) of fentanyl initially caused an increase of the mechanical threshold to induce a pain response (i.e. analgesia) that was followed by a decrease (i.e. hyperalgesia). The findings indicate that with opioid signaling systems, transduction mechanisms operate that may cause the sign of the effect to reverse not only when activation is discontinued but also whilst it is maintained at a constant magnitude.     

Influence of centrally administered peptides on ear withdrawal from heat in the rabbit

Certain neuropeptides previously linked to stress and implicated in CNS control of analgesia/algesia were tested using a recently developed analgesiometric model, the rabbit ear-withdrawal test. The latency to ear withdrawal increased in a dose-related manner after β-endorphin was injected intracerebroventricularly (IVC). Intermediate doses (0.5 and 1.0 μg) of adrenocorticotropic hormone (ACTH) caused hyperalgesia as indicated by decreases in latency. Corticotropin-releasing factor (CRF, 0.5 and 1.0 μg) also caused significant hyperalgesia late in the testing period. -Melanocyte stimulating hormone (-MSH, 0.25–2.0 μg), a molecule that shares the first 13 amino acid sequence with ACTH, and somatostatin (0.25–2.0 μg), caused no significant change in latency. However, 1.0 μg doses of each peptide antagonized the analgesic effect of β-endorphin (1.0 μg) in the following order of potency: ACTH = -MSH > CRF > somatostatin. The results support the idea that CNS peptides that are released during stress can exert opposing actions on acute pain, even though they may cause little effect alone.