Antagonism of antinociception produced by intrathecal clonidine by ketorolac in the rat: the role of the opioid system.

The management of severe pain may require "balanced analgesia," involving the use of analgesics with different modes of action. Clonidine, an alpha(2)-adrenoreceptor agonist produces analgesia by itself as well as when given with morphine and local anesthetics. Ketorolac is indicated for the management of moderately severe acute pain and causes analgesia equivalent to morphine. This study was designed to investigate whether the addition of ketorolac promotes antinociception produced by intrathecal administration of clonidine in male Sprague-Dawley rats. Intrathecal injection of clonidine (1-30 microg) induced a dose-dependent increase in antinociception as measured by the tail flick (TF) and hot plate tests. Ketorolac alone (150-600 microg) increased the antinociception by 50%-60% only in the TF test. Ketorolac (10 microg) decreased clonidine (10 microg)-induced antinociception from 69.1% +/- 7.8% to 23.5% +/- 1. 6% (P < 0.05) in the TF test and 35.7% +/- 4.7% to 4.5% +/- 0.1% (P < 0.05) maximum possible effect in the hot plate test. Ketorolac also antagonized the effect of 30 microg of clonidine. The opioid receptor antagonist naloxone antagonized the antinociceptive effect of clonidine and ketorolac, indicating the involvement of the opioid system in the antinociception produced by clonidine or ketorolac. However, neither clonidine nor ketorolac (10(-8) to 10(-3) M) inhibited the binding of specific ligands to mu-, delta-, and kappa-opioid receptors, indicating a lack of direct interaction of clonidine and ketorolac with opioid receptors. These results suggest that intrathecal injection of ketorolac antagonizes the antinociception produced by clonidine.

Temporal and kinetic determinants of the inhibition of LDL oxidation by N-acetylcysteine (NAC).

We investigated the ability of NAC to inhibit in vitro LDL oxidation, and the effects of the timing of NAC addition, repeated additions of NAC, and the presence of preoxidized LDL, on the oxidation reaction. NAC inhibited in vitro LDL oxidation induced by copper sulfate, 2,2'-azobis(2-amidinopropane) dihydrochloride, and UV light, and protected LDL against depletion of antioxidant vitamins. Glutathione was similarly effective against copper-mediated LDL oxidation. NAC's effectiveness was inversely related to the timing of its addition. Sequential NAC additions prolonged the lag phase more effectively than initial addition of the same total dose. NAC reduced CD formation during the oxidation of native LDL by oxidized LDL. NAC's effectiveness as an inhibitor of in vitro LDL oxidation is dependent on the temporal sequence of the oxidation reaction, sequential additions, and the presence of previously oxidized LDL.

Inhibition of LDL oxidation by a new estradiol receptor modulator compound LY-139478, comparative effect with other steroids.

Oxidation of low-density lipoprotein (LDL) is postulated to be essential for the development of atherosclerosis. LY-139478 is a new non-steroidal potent estrogen analog, but its effects on in vitro LDL oxidation have not been completely elucidated. We investigated the ability of LY-139478 to inhibit in vitro copper sulfate-mediated LDL oxidation using several methods, including conjugated diene (CD) accumulation, relative electrophoretic mobility on agarose gel, thiobarbituric acid-reactive substances (TBARS) assay, and superoxide anions scavenging activity. The antioxidative potential of LY-139478 was compared to testosterone (T), 17-alpha-estradiol (17alphaE), 17-beta-estradiol (17betaE), dehydroepiandrosterone (D), and dehydroepiandrosterone-3-sulfate (DS). LY-139478 was superior to 17alphaE and 17betaE in prolonging the lag phase and decreasing the slope and peak concentration of the conjugated diene accumulation, decreasing the rate of migration of LDL on agarose gel electrophoresis, and inhibiting the production of melonyldialdehyde (MDA) in the TBARS assay. T, D and DS were ineffective in all three assays. It was previously shown that when native LDL is oxidized by previously oxidized LDL (secondary oxidation) the lag phase is lost (Schnitzer et al. Free Rad Res 1995;23:137). LY-139478 was at least 15-fold more effective than 17alphaE, and 17betaE in slowing the propagation phase and reducing CD accumulation in this secondary oxidation, with 50% inhibition at 10 microM and 98% inhibition at 100 microM. However, none restored the lag phase. T, D and DS were ineffective. Superoxide anion generation was inhibited only by DS at high doses (500 microM). These results demonstrate that LY-139478 is an effective inhibitor of LDL oxidation and is superior to natural steroidal hormones, including 17betaE, in protecting against primary and secondary LDL oxidation.

Effect of chronic treatment with morphine, midazolam and both together on dynorphin(1-13) levels in the rat.

We have recently reported that midazolam, a benzodiazepine receptor agonist that is also a short acting anesthetic and analgesic drug, can produce analgesia and decrease morphine tolerance and dependence in the rat by interacting with the opioidergic system. This study was designed to investigate the chronic effect of midazolam and/or morphine on the levels of dynorphin(1-13) in the pituitary gland, different brain regions, spinal cord and peripheral tissues of the rat. Four sets of animals were used: (I) saline-saline; (II) midazolam (0.03, 0.3 or 3.0 mg/kg, body wt., i.p.)-saline; (III) saline-morphine (10.0 mg/kg, body wt., s.c.); and (IV) midazolam-morphine (0.03, 0.3 or 3.0 mg/kg midazolam + 10.0 mg/kg morphine) groups. The first saline or midazolam injection was given i.p. and after 30 min, the second injection of saline or morphine was given s.c. daily for 11 days. Animals were sacrificed on the 11th day, 60 min after the last injection and dynorphin(1-13) was measured in indicated tissues by radioimmunoassay method. The midazolam treated animals showed a significant decrease in dynorphin(1-13) levels in the cortex, cerebellum, cervical region of spinal cord, heart and adrenals, and a significant increase in the hypothalamus, striatum and lumbar region of the spinal cord. The morphine treated animals showed a significant decrease in dynorphin(1-13) levels in the pituitary gland, hypothalamus, hippocampus, striatum, cerebellum, pons, medulla, kidneys, adrenals and spleen, and a significant increase only in the lumbar region of the spinal cord. When both drugs were injected together there was no effect on pituitary gland, kidneys and spleen. These drugs antagonize each other's effect on dynorphin(1-13) in the hypothalamus, striatum, cerebellum, pons, medulla and heart. However, the midazolam-morphine combination significantly increases dynorphin(1-13) levels in the hippocampus, cortex, midbrain, cervical and lumbar regions of the spinal cord, and adrenals. These results suggest the involvement of dynorphin(1-13) in the inhibition of morphine-induced tolerance and dependence by midazolam in the rat. These results may also help us in understanding the intrinsic mechanisms involved in narcotic tolerance and dependence.

Met-enkephalin alteration in the rat during chronic injection of morphine and/or midazolam.

We have recently reported that the short-acting anesthetic and analgesic drug midazolam can produce analgesia and decrease morphine tolerance and dependence in the rat by interacting with the opioid system. This study was designed to investigate the effect of midazolam, morphine, and both together on met-enkephalin levels in the rat. Male Sprague-Dawley rats were divided into four groups: (1) saline-saline; (2) saline-morphine; (3) midazolam-saline, and (4) midazolam-morphine groups. First, a saline or midazolam injection was given intraperitoneally and after 30 min a second injection of saline or morphine was given subcutaneously once daily for 11 days. Animals were sacrificed on the 11th day 60 min after the last injection to measure met-enkephalin by radioimmunoassay. Morphine tolerant animals showed a significant increase in met-enkephalin levels in the cortex (137%) and midbrain (89%), and a significant decrease in met-enkephalin levels in the pituitary (74%), cerebellum (34%) and medulla (72%). Midazolam treated animals showed a significant decrease in met-enkephalin levels in the pituitary (63%), cortex (39%), medulla (58%), kidneys (36%), heart (36%) and adrenals (43%), and a significant increase in met-enkephalin levels in the striatum (54%) and pons (51%). When morphine and midazolam were injected together, midazolam antagonized the increase in met-enkephalin levels in cortex and midbrain region and the decrease in met-enkephalin level in the medulla region observed in morphine tolerant animals. These results indicate that morphine tolerance and dependence is associated with changes in the concentration of met-enkephalin in the brain. Midazolam may inhibit morphine tolerance and dependence by reversing some of the changes induced in met-enkephalin levels in brain by morphine in morphine tolerant and dependent animals.

Effect of chronic treatment with morphine, midazolam, and both together on beta-endorphin levels in the rat.

We have recently reported that a short-acting anesthetic and analgesic drug midazolam can produce analgesia and decrease morphine tolerance and dependence in the rat by interacting with the opioid system. This study was designed to investigate the effect of midazolam, morphine, and both together on beta-endorphin levels in the rat. Male Sprague-Dawley rats were divided into four groups: (1) saline-saline; (2) saline-morphine; (3) midazolam-saline, and (4) midazolam-morphine groups. First, saline or midazolam injection was given IP and after 30 min a second injection of saline or morphine was given subcutaneously once daily for 11 days. Animals were sacrificed on 11th day 60 min after the last injection, to measure beta-endorphin by radioimmunoassay. Saline-morphine-treated animals showed a significant increase in beta-endorphin levels in the cortex, pons, medulla, lumbar spinal cord, adrenals, and spleen, and a decrease only in its level in pituitary. Midazolam-saline-treated animals showed a significant increase in beta-endorphin levels only in the medulla, and a decrease in its levels in hippocampus, striatum, and adrenals. Saline-morphine-treated animals did not show any changes in plasma beta-endorphin, but animals treated with midazolam-saline had a significant decrease in plasma beta-endorphin. In rats treated with morphine and midazolam together, beta-endorphin levels in cortex, lumbar spinal cord, and spleen decreased to the similar levels observed in rats treated with saline-saline; in pons and cervical spinal cord the levels were even lower than that found in saline-saline group. The decrease in pituitary beta-endorphin in morphine-midazolam-treated rats was due to morphine's own activity, whereas the decrease in plasma beta-endorphin in hippocampus in the morphine-midazolam group was a synergistic effect of morphine and midazolam. The beta-endorphin level in adrenal glands in the morphine-midazolam-treated animals was not different from that found in rats treated with morphine alone but was still higher than that in the saline-saline group. In general, it appears that chronic treatment with morphine stimulates the beta-endorphinergic system. A concomitant treatment with midazolam abolishes the stimulatory effect of morphine on the beta-endorphinergic system. These results may help us in understanding the intrinsic mechanisms involved in narcotic tolerance and dependence.

Effect of morphine-induced catalepsy, lethality, and analgesia by a benzodiazepine receptor agonist midazolam in the rat.

Previously we have shown that intrathecal administration of midazolam can increase or decrease morphine-induced antinociception, depending upon relative concentration of these drugs by modulating spinal opioid receptors, and it also can inhibit morphine-induced tolerance and dependence in the rat. Now we report that midazolam also influences catalepsy, lethality, and analgesia induced by morphine in the rat. In the acute treatment, animals were first treated with saline or midazolam (0.03 to 30.0 mg/kg, b.wt., IP), and 30 min later with a second injection of saline or morphine (1.0 to 100.0 mg/kg, b.wt., SC). The catalepsy was measured 60 min after the second injection and lethality was checked after 24 h. Midazolam injection increased the morphine-induced catalepsy and lethality. In the chronic treatment, animals were injected with two injections daily for 11 days. The first injection consisted of saline or midazolam (0.03 to 3.0 mg/kg, b.wt., IP), and 30 min later with a second injection of saline or morphine (10.0 mg/kg, b.wt., IP) was given. Lethality, antinociception, and body weight were measured. Chronic morphine treatment also increased lethality in a dose-dependent manner. Chronic treatment with midazolam and morphine increased the antinociception on day 11, as measured in the tail-flick and hot-plate tests. Midazolam administration also prevented the morphine-induced weight loss. These results suggest a strong interaction between midazolam and morphine in altering catalepsy, lethality, and analgesia in rat.

Methionine-enkephalin concentrations in discrete brain regions, spinal cord, pituitary gland and peripheral tissues of U-50,488H-tolerant and abstinent rats.

Effects were determined of chronic administration and withdrawal of a highly selective kappa-opioid receptor agonist, U-50,488H, on methionine-enkephalin levels in central and peripheral tissues of male Sprague-Dawley rats. Rats were rendered tolerant to and physically dependent on U-50,488H by twice daily injections of 25 mg/kg of this compound for 5 days. Rats deemed abstinent were injected with this drug for 4 days and sacrificed on 5th day. Methionine-enkephalin concentration increased in the hippocampus of U-50,488H-tolerant-dependent rats, whereas in abstinent rats, its level was elevated only in the hypothalamus. Levels of methionine-enkephalin in the pituitary gland of U-50,488H-tolerant-dependent or abstinent rats were unchanged. Among peripheral tissues, methionine-enkephalin concentration decreased in the adrenal gland of U-50,488H-tolerant-dependent rats. In the U-50,488H-abstinent rats, methionine-enkephalin concentration was elevated in the heart. In tissues of morphine- and U-50,488H-tolerant-dependent and abstinent rats methionine-enkephalin concentrations were affected differentially, suggesting inherent differences in mu- and kappa-opiate-mediated tolerance-dependence and abstinence processes.

beta-Endorphin-like immunoreactivity in discrete brain regions, spinal cord, pituitary gland and peripheral tissues of U-50,488H-tolerant and -abstinent rats.

The effect was determined of trans-3,4-dichloro-N-methyl-N-[2-(1-pyrrolidinyl)cyclohexyl]benzene- acetamide methane sulfonate (U-50,488H), a kappa opioid agonist, -induced tolerance dependence and abstinence on the levels of beta-endorphin in discrete brain regions, spinal cord, pituitary gland, plasma and peripheral tissues of male Sprague-Dawley rats. The brain regions examined were hypothalamus, hippocampus, amygdala, midbrain, corpus striatum, pons-medulla and cortex. The peripheral tissues included kidneys, spleen, adrenals and heart. Rats were made tolerant dependent on U-50,488H by intraperitoneal injections of the drug (25 mg/kg) twice a day for 4 days. Vehicle-injected rats served as controls. Rats that were labeled as tolerant dependent were injected with U-50,488H (25 mg/kg) on day 5 and killed 1 hr later, whereas those labeled as abstinent were killed without injection of the drug. Rats serving as controls were injected with the vehicle. Tolerance to the analgesic and hypothermic effects of U-50,488H developed, as evidenced by a decrease in the intensity of responses in chronic U-50,488H-treated compared with chronic vehicle-treated rats. In U-50,488H-tolerant rats, the concentration of beta-endorphin was increased in hippocampus, corpus striatum, pituitary gland, plasma, kidneys and adrenals compared with vehicle-injected controls. In U-50,488H-abstinent rats, the concentration of beta-endorphin was increased in pons-medulla and amygdala, whereas the concentration of beta-endorphin did not change in the pituitary gland, plasma and peripheral tissues. In general, chronic treatment with a kappa opioid agonist results in increases in the concentration of beta-endorphin in specific tissues.(ABSTRACT TRUNCATED AT 250 WORDS)

Regional distribution of neuropeptide processing endopeptidases in adult rat brain.

Many peptide hormone and neuropeptide precursors undergo post-translational processing at mono- and/or dibasic residues. An enzymatic activity capable of processing prodynorphin at a monobasic processing site designated 'dynorphin converting enzyme' has been previously reported in rat rain and bovine pituitary. In this study the distribution of dynorphin converting enzyme activity in ten regions of rat brain has been compared with the distribution of subtilisin-like processing enzymes and with the immuno-reactive dynorphin peptides. The distribution of dynorphin converting enzyme activity generally matches the distribution of immuno-reactive dynorphin B-13 in most but not all brain regions. The regions that are known to have a relatively large number of immuno-reactive dynorphin-neurons also contain high levels of dynorphin converting enzyme activity. The distribution of dynorphin converting enzyme activity does not match the distribution of subtilisin-like processing enzyme or carboxypeptidase E activities. Taken together the data support the possibility that the dynorphin converting enzyme is involved in the maturation of dynorphin, as well as other neuropeptides, and peptide hormones.

Sodium ions modulate differentially the effect of a benzodiazepine agonist on rat spinal mu-, delta- and kappa-opioid receptors.

Midazolam, a benzodiazepine receptor agonist, when injected intrathecally either enhances or decreases antinociception produced by intrathecal administration of morphine in rats. Furthermore, midazolam inhibits binding of several opioid ligands to spinal opioid receptors in vitro [Rattan et al, Anesth Analg 1991;73:124-131]. This study was designed to investigate the effect of midazolam on binding of mu-, delta- and kappa-ligands to rat spinal opioid receptors in the presence of sodium ions which differentially modulate binding of opioid agonists and antagonists. Sodium ions (50-1,000 mmol/l) selectively increased the specific binding of [3H]naloxone but decreased binding of opioid agonists such as [3H]DAGO (Tyr-D-Ala-Gly-Methyl-Phe-Gly-ol-enkephalin) to mu-receptors, [3H]DSTLE (Tyr-D-Ser-Gly-Phe-Leu-Thr-enkephalin) to delta-receptors and [3H]EKC (ethylketocyclazocine) to kappa-receptors in rat spinal cord in vitro. Midazolam (1-100 mumol/l) inhibited the binding of [3H]naloxone, [3H]DAGO, [3H]DSTLE and [3H]EKC. Sodium ions (100 mmol/l) antagonized the inhibition of binding of [3H]naloxone and [3H]DSTLE by midazolam by increasing IC50 values for midazolam. However, sodium ions potentiated the inhibition of binding of [3H]DAGO by midazolam by decreasing IC50 value for midazolam and had a mixed effect on binding of [3H]EKC in the presence of midazolam. Scatchard analysis performed in the presence of sodium ions and/or midazolam confirmed the specific effects of sodium ions as well as midazolam on the Bmax and KD of mu-, delta-, and kappa-receptors. These results suggest for the first time that sodium ions play an important role in the modulation of spinal opioid receptors by benzodiazepines. Sodium ions potentiate the inhibition of DAGO binding but antagonize the inhibition of naloxone and DSTLE binding by midazolam in rat spinal cord.

Inhibition of morphine-induced tolerance and dependence by a benzodiazepine receptor agonist midazolam in the rat.

We investigated whether midazolam administration influenced morphine-induced antinociception and tolerance and dependence in the rat. Antinociception was assessed by the tail-flick (TF) and the hot-plate test (HP 52 degrees C). Morphine tolerance developed after daily single injections of morphine for 11 days. The effect of midazolam on morphine-induced antinociception and tolerance was assessed by giving daily injections of various doses of midazolam for 11 days. The first injection of saline or midazolam was given intraperitoneally and 30 min later morphine (10 mg/kg body weight) was administered subcutaneously. Antinociception was monitored by measuring TF and HP latencies 60 min after the second injection. Midazolam was injected at four different concentrations: 0.03, 0.1, 0.3, and 3 mg/kg body weight. Chronic administration of morphine resulted in the development of tolerance to antinociception in both TF and HP tests, with rats exhibiting baseline antinociception on Day 9. Animals treated with midazolam alone showed little antinociception on Days 3-9. However, midazolam administration in morphine-treated animals attenuated morphine-induced tolerance to antinociception on Days 1-11 as measured by the tail-flick test. Midazolam also decreased the jumping behavior following naloxone injections in morphine-dependent rats. These results suggest that midazolam may prolong the effects of morphine by delaying morphine-induced development of tolerance to antinociception. Midazolam also attenuated a decrease in weight gain induced by chronic injections of morphine.

The effect of U-50,488H tolerance-dependence and abstinence on the levels of dynorphin (1-13) in brain regions, spinal cord, pituitary gland and peripheral tissues of the rat.

Male Sprague-Dawley rats were rendered tolerant to and physically dependent on U-50,488H, a kappa-opiate agonist, by injecting 25 mg/kg of the drug intraperitoneally twice a day for 4 days. Two sets of rats were used. Rats labeled as tolerant-dependent were injected with U-50,488H (25 mg/kg) 1 h before sacrificing on day 5, whereas the abstinent rats were sacrificed on day 5 without the injection of U-50,488H. Of all the tissues on day 5 without the injection of U-50,488H. Of all the tissues examined, the pituitary gland had the highest level of dynorphin (1-13), whereas the heart had the lowest level. The levels of dynorphin (1-13) increased in the hypothalamus, hippocampus and pons/medulla of U-50,488H tolerant-dependent rats, whereas in abstinent rats the levels of dynorphin (1-13) were elevated only in the midbrain. The levels of dynorphin (1-13) in the pituitary gland of U-50,488H tolerant-dependent or abstinent rats were unchanged. In peripheral tissues, the levels of dynorphin (1-13) in the heart of U-50,488H tolerant-dependent rats were increased. In the abstinent rats they were elevated in the adrenals, spleen, and the heart but were decreased in the kidneys. Compared to morphine tolerant-dependent and abstinent rats, significant differences in the levels of dynorphin (1-13) in tissues of 50,488H tolerant-dependent and abstinent rats were observed and may explain many pharmacological differences in the mu- and kappa-opiate induced tolerance-dependence and abstinence processes.

The effect of morphine tolerance dependence and abstinence on immunoreactive dynorphin (1-13) levels in discrete brain regions, spinal cord, pituitary gland and peripheral tissues of the rat.

The effect of morphine tolerance dependence and protracted abstinence on the levels of dynorphin (1-13) in discrete brain regions, spinal cord, pituitary gland and peripheral tissues was determined in male Sprague-Dawley rats. Of all the tissues examined, the highest level of dynorphin (1-13) was found to be in the pituitary gland. Among the brain regions and spinal cord examined, the levels of dynorphin (1-13) in descending order were: hypothalamus, spinal cord, midbrain, pons and medulla, hippocampus, cortex, amygdala and striatum. The descending order for the levels of dynorphin (1-13) in peripheral tissues was: adrenals, heart and kidneys. In morphine tolerant rats, the levels of dynorphin (1-13) increased in amygdala but were decreased in pons and medulla. In morphine abstinent rats, the levels of dynorphin (1-13) were increased in amygdala, hypothalamus and hippocampus. The levels of dynorphin (1-13) were increased in pituitary but decreased in spinal cord and remained so even during protracted abstinence. The levels of dynorphin (1-13) in the peripheral tissues of morphine tolerant rats were unaffected. However, in the heart and kidneys of morphine abstinent rats, the levels of dynorphin (1-13) were increased significantly. It is concluded that both morphine tolerance and abstinence modify the levels of dynorphin (1-13) in pituitary, central and peripheral tissues. Morphine abstinence differed from non-abstinence process in that there were additional changes (increases) in the levels of dynorphin (1-13) in brain regions (hypothalamus and hippocampus) and peripheral tissues (heart and kidneys) and may contribute to the symptoms of the morphine abstinence syndrome.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of spinal opioid receptors in the antinociceptive interactions between intrathecal morphine and bupivacaine.

In studies on the clinical management of pain, a combination of morphine and bupivacaine is more effective than either of them alone in producing analgesia. The present study was designed to examine the effect of bupivacaine on morphine-induced antinociception as measured by the tail-flick test in the rat. To understand the basis of this interaction, the effect of bupivacaine on the binding of opioid ligands to their spinal opioid receptors in the rat also was investigated. Intrathecal administration of 5, 20, or 50 micrograms bupivacaine significantly potentiated the antinociception produced by intrathecal administration of 10 micrograms morphine. There was more than a 10-fold increase in the area under the curve (AUC0-60 min) for morphine-induced antinociception in the presence of bupivacaine. At higher doses of morphine (20 micrograms), bupivacaine was not very effective, increased AUC0-60 min for antinociception by only about 25%, and in fact significantly decreased the total duration of morphine-induced antinociception. Radioreceptor assays done with rat spinal cord membrane preparations revealed that bupivacaine (0.1-10 nM) inhibited the binding of specific ligands to mu-receptors but increased the binding to delta- and kappa-receptors. The authors conclude that the facilitation of morphine-induced antinociception by bupivacaine may be associated with a conformational change in the spinal opioid receptors induced by bupivacaine. Although increasing the binding of morphine to kappa-opioid receptors is the most prominent effect, the binding of opioid ligands to all spinal receptors is inhibited at high doses of bupivacaine.

The neurotoxic actions of ibotenic acid on cholinergic and opioid peptidergic systems in the central nervous system of the rat.

The neurotoxic effects produced by ibotenic acid (IA) induced chemical lesions of the central nervous system (CNS) cholinergic system were examined on the opioid peptidergic system in adult rats. Forebrain cholinergic systems were bilaterally lesioned by the infusion of IA (1 or 5 micrograms/site) into the nucleus basalis magnocellularis (NBM). One week after the injections, the animals were sacrificed, and activities of acetylcholinesterase (AChE), choline acetyltransferase (ChAT) and concentrations of beta-endorphin (beta-End) and Met-enkephalin (Met-Enk) were measured in different brain regions. Animals treated with IA showed a decrease in the activity of ChAT (-24%), AChE (-36%) and beta-End level (-33%) in the frontoparietal cortex (FC). For the first time we report that these changes were associated with a compensatory increase in the activity of ChAT (+27%), AChE (+25%), beta-End level (+66%) in the remaining part of the cortex, i.e. cortex devoid of frontal cortex (C-FC). Met-enkephalin level increased by 59% in the frontoparietal cortex and did not change in the cortex devoid of frontal cortex upon IA treatment. These results suggest that IA treatment results in changes in the activity of cortical ChAT and AChE, and beta-End level in the same direction. Injection of IA in the NBM did not cause a change in the activity of ChAT or AChE in other brain regions such as hippocampus, striatum or midbrain. In addition to cortex devoid of frontal cortex, midbrain also showed a significant increase in the beta-End level in the IA treated animals. However, pituitary beta-End decreased in the neurotoxin treated animals.(ABSTRACT TRUNCATED AT 250 WORDS)

GM1 ganglioside enhances cholinergic parameters in the brain of senescent rats.

GM1 ganglioside and nerve growth factor both promote the recovery of injured central cholinergic neurons in young animals. Brain cholinergic activity declines with aging and nerve growth factor has been shown to correct cholinergic deficits in senescent animals. We have administered GM1, to young (three months old) or senescent (22-24 months old) rats and evaluated acetylcholine and choline content, choline acetyltransferase and acetylcholinesterase activity as well as choline uptake in striatum, hippocampus and frontal cortex. For some studies, nerve growth factor was administered alone or together with GM1. Our results indicate that cholinergic neurochemical parameters are decreased in some brain areas of senescent animals and that both GM1 and nerve growth factor can enhance their recovery.

Increased methionine-enkephalin levels in genetically epileptic (tg/tg) mice.

Recent experimental data indicate that endogenous brain ligands for the opioid receptors such as enkephalins, beta-endorphin (beta-End) and dynorphin (Dyn) may be involved in both generalized and partial seizures. The "tottering" (tg/tg) mouse provides an electrophysiological representation of generalized spontaneous human epilepsy. These mice exhibit behavioral absence seizures with accompanying spike-wave discharges. Methionine-enkephalin (M-Enk), beta-End and Dyn levels in various regions of brain were measured by radioimmunoassay (RIA) in 15-18-week-old tg/tg and control (+/+) mice to elucidate the relation between seizures and the opioid system. beta-End and Dyn levels were similar in tg/tg and +/+ mice. However, M-Enk levels were significantly increased in the striatum, cortex, pons and medulla of the tg/tg mice. Our data suggest that in the tottering mouse model of generalized epilepsy there is an alteration of enkephalinergic pathways and not of the endorphinergic or dynorphinergic pathways.

Differential effects of intrathecal midazolam on morphine-induced antinociception in the rat: role of spinal opioid receptors.

The antinociceptive effects of an intrathecally administered benzodiazepine agonist midazolam, alone and in combination with morphine, were examined in the rat by using the tail-flick test. The duration of antinociceptive effect produced by midazolam was significantly less (P less than 0.05) than that produced by morphine. Low doses of midazolam (10 micrograms) and morphine (10 micrograms) produced a synergistic effect in prolonging antinociceptive effect. However, at higher doses (20 or 30 micrograms), these drugs reduced the extent of antinociception produced by each other. Naloxone administration prevented antinociception produced by these drugs, indicating interactions between midazolam and opioid receptors. Midazolam had dual effects on the binding of opioid ligands to the spinal opioid receptors. At low dose, it potentiated the displacement of [3H]naloxone by morphine. At higher doses, midazolam inhibited the binding of opioid ligands to their spinal receptors in the following order: kappa greater than delta greater than mu. These results indicate that differential antinociceptive effects of midazolam on morphine-induced antinociception involve interaction of this benzodiazepine with spinal opioid receptors.

Modulation of mu, kappa and delta opioid receptors in the rat brain by isoflurane and enflurane.

This study was done to investigate whether inhalational anesthetics modulated the binding of specific ligands to opioid receptors in the brain of the rat. The effect of isoflurane and enflurane on the binding of specific ligands to various subtypes of opioid receptors in vitro was studied. Isoflurane inhibited the binding of [3H]naloxone to opioid receptors by 50% in the spinal cord, midbrain and cortex at 22, 49 and 50 mM, respectively. Enflurane was more potent than isoflurane in inhibiting the binding of [3H]naloxone. Scatchard analysis of the binding of [3H]naloxone, done in the presence of therapeutic level (5 mM) of isoflurane, suggested that it did not affect the KD (1.3 nM) but decreased the Bmax by 41% in the cortex. Isoflurane and enflurane, at large doses (30-50 mM), inhibited the binding of [3H]ethylketo-cyclazocine (EKC) to kappa receptors in midbrain, cortex and spinal cord. At a smaller dose (5 mM), they increased the binding of EKC in spinal cord. The binding of the analogs of enkephalin [3H]DSTLE(Tyr-D-Ser-Gly-Phe-Leu-Thr-enkephalin) to delta receptors and [3H]DAGO (Tyr-D-Ala-Gly-Methyl-Phe-Glyol-enkephalin) to mu receptors in the midbrain and cortex was inhibited by isoflurane at a significantly smaller concentration than the binding of [3H]naloxone, indicating that the binding of peptides was more susceptible to the inhibition by inhalational anesthetics than the binding of alkaloids, such as naloxone or EKC. These results suggest that the modulation of opioid receptors by inhalational anesthetics is a function of both the nature of the ligand and the tissue used for the receptor binding.(ABSTRACT TRUNCATED AT 250 WORDS)