Andrew H. Tang

Protection from cerebral ischemia by U-50,488E, a specific kappa opioid analgesic agent

U-50,488E is a novel analgesic agent with a specific agonist property on the kappa opioid receptor. It is found to protect against the lethal effect of temporary bilateral carotid occlusion (BCO) in Mongolian gerbils and rats of the Fischer strain. Pretreatment with U-50,488E in gerbils before 7 min of BCO reduced the development of behavioral hyperactivity and preserved the hippocampal neurons from ischemic death. This protective effect of U-50,488E resided predominantly in the levo-enantiomer which is also more potent as a kappa analgesic. Two other kappa opioid analgesics, ethylketocyclazocine and bremazocine, shared the effects of U-50,488E in the gerbils. Naloxone and dynorphin 1-13, on the other hand, were without protective effects in the same ischemic model. The ischemic protective effects of U-50,488E may involve the kappa opioid receptor.

Comparison of subcutaneous and spinal subarachnoid injections of morphine and naloxone on analgesic tests in the rat

Small catheters were chronically implanted subdurally in the rat so that repeated microinjections could be made into the subarachnoid space at the lumbar area. Morphine, injected intrathecally (i.th.) produced analgesia as measured by the tail-flick test at doses 1100 of those by the subcutaneous (s.c.) route. Analgesia from i.th. morphine was reversed by either i.th. or s.c. injected naloxone. The dose of naloxone by the i.th. route was about 130 of that by the s.c. route. However, i.th. injection was no more effective than s.c. injection of naloxone in reversing analgesia produced by s.c. injection of morphine. When [3H]-labelled naloxone was injected s.c. or i.th. in the above experiment of morphine antagonism, there was a more rapid entry of the labelled material in the brain by the i.th. route of administration. The results raise questions on the relative importance of the spinal mechanism of analgesia produced by s.c. injections of morphine. Analgesia was also measured by the tail-shock vocalization test in which morphine producd a dose-dependent elevation of shock threshold at s.c. doses above those prolonging tail-flick latencies. Morphine injected i.th. at doses above those which elevated tail-flick latency produced hypersensitivity, hyper-reflexia, and convulsive seizure of the hindquarters. The spinal analgesic effect of morphine, when administered localy, appears to have a low ceiling of efficacy.

Behavioral effects of a novel kappa opioid analgesic, U-50488, in rats and rhesus monkeys

U-50488 [trans-3,4-dichloro-N-(2-(1-pyrrolidinyl)cyclohexyl)-benzeneacetamide] is a structurally novel analgesic reported to have specific kappa opioid receptor agonist properties. Potent antinociceptive activity was demonstrated in rhesus monkeys and the effect was reversed by naloxone. The overt behavioral effects of U-50488 at supra-analgesic doses more closely resembled those of ethylketocyclazocine (EKC) than morphine. In monkeys trained to discriminate a 10-μg/kg dose of EKC from saline, the stimulus effects generalized completely to U-50488 and other kappa agonists (e.g., bremazocine, cyclazocine), but not to the pure mu agonists. Like the other kappa agonists, U-50488 produced diuresis in monkeys by a naloxone-sensitive mechanism. In drug-naive rats offered continuous opportunity to self-administer drugs IV, most rats self-administered morphine or EKC, but none of the rats self-administered U-50488 at a rate above that of a group offered saline. Rats with continuous IV infusion of U-50488 for 3 weeks exhibited few abstinence signs and no weight loss when challenged with an injection of naloxone or after abrupt cessation of drug infusion. These experimental results support the previous reports in mice that U-50488 is a very selective kappa opioid agonist in rats and rhesus monkeys.

Reversal of scopolamine-induced amnesia and alterations in energy metabolism by the nootropic piracetam: implications regarding identification of brain structures involved in consolidation of memory traces

Pretreatment with scopolamine, 3 mg/kg, prevented the acquisition of a passive avoidance task in rats. These amnesic effects of scopolamine could largely be overcome by treatment with 100 mg/kg of the nootropic drug piracetam. In order to identify the brain structures involved, the effects of these drugs on regional energy metabolism were measured throughout the brain, utilizing Sokoloffs 2-deoxyglucose autoradiographic procedures. Scopolamine, 3 mg/kg, reduced glucose utilization in several areas of the cerebral cortex. These effects were largest in the parietal and temporal cortices. Other areas affected included the sensorimotor and cingulate cortices, the ventral and lateral thalamus, and the dendritic neuropil of the CA1, CA2, and CA3 regions of the hippocampus. The regional depressions in glucose metabolism observed following scopolamine treatment in the rat had some resemblance to depressions in glucose metabolism reported for Alzheimers disease patients in positron emission tomography studies. Piracetam, 100 mg/kg, did not alter the energy metabolism of any of the 41 brain regions examined. However, this dose of piracetam completely reversed the scopolamine-induced depressions in the hippocampus. Piracetam partially but significantly reversed the scopolamine effects in the cingulate cortex. It is concluded that the data provide support for the hippocampal-cholinergic theory of memory as originally formulated by Meyers and Domino in 1964 and give insight into the mechanisms by which nootropics work.

Protection from ischemia-induced cerebral edema in the rat by U-50488H, a kappa opioid receptor agonist

U-50488 is a specific kappa opioid agonist which produces in rats water diuresis resulting in an elevation of plasma osmolarity. Pretreatment with U-50488H (the methanesulfonate salt) in Fisher rats prior to 4 h of bilateral carotid occlusion prevented the development of edema in the forebrain, and the effect was greater than that from pentobarbital anesthesia. An additional injection of an antidiuretic hormone which prevented the plasma hyperosmolarity also significantly reduced the anticerebral edemic effects of U-50488H. The plasma osmotic effect, however, may not completely account for the ischemic protection produced by U-50488H.

3-Phenyl-Substituted Imidazo[1,5-a]quinoxalin-4-ones and Imidazo[1,5-a]quinoxaline Ureas That Have High Affinity at the GABAA/Benzodiazepine Receptor Complex†

A series of imidazo[1,5-alpha]quinoxalin-4-ones and imidazo[1,5-alpha]quinoxaline ureas containing substituted phenyl groups at the 3-position was developed. Compounds within the imidazo[1,5-alpha]quinoxaline urea series had high affinity for the GABAA/benzodiazepine receptor complex with varying in vitro efficacy, although most analogs were partial agonists as indicated by [35S]TBPS and Cl- current ratios. Interestingly, a subseries of piperazine ureas was identified which had biphasic efficacy, becoming more antagonistic with increasing concentration. Analogs within the imidazo[1,5-alpha]quinoxalin-4-one series had substantially decreased binding affinity as compared to the quinoxaline urea series. These compounds ranged from antagonists to full agonists by in vitro analysis, with several derivatives having roughly 4-fold greater intrinsic activity than diazepam as indicated by Cl- current measurement. Numerous compounds from both series were effective in antagonizing metrazole-induced seizures, consistent with anti-convulsant properties and possible anxiolytic activity. Most of the quinoxaline ureas and quinoxalin-4-ones were active in an acute electroshock physical dependence side effect assay in mice precluding further development.

Both competitive and non-competitive antagonists of N-methyl-D-aspartic acid disrupt brightness discrimination in rats.

Rats were trained to avoid or escape electric shocks in a symmetrical Y-maze by choosing to enter the brighter of two arms. Pretreatment with phencyclidine-like compounds disrupted brightness discrimination with greatly increased spontaneous locomotor activity between trials. The competitive antagonists of NMDA, 2-amino-7-phosphonoheptanoate (AP7) or 3-(+/-)-2-carboxypiperazin-4-yl)propyl-1-phosphonic acid (CPP) also disrupted brightness discrimination when injected into the cerebral ventricles, with no increase in movements between trials. The results suggest that the competitive antagonists of NMDA may impair sensory and cognitive functions in a manner similar to that produced by the phencyclidine-like compounds.

Behavior maintained under second-order schedules of intravenous morphine injection in squirrel and rhesus monkeys.

Under second-order schedules of morphine injection, high rates of responding by squirrel and rhesus monkeys were maintained when morphine was injected intravenously only at the end of each session. Every 30th key-pressing response during a 60-min interval produced a 2-s light; the first 30-response component completed after 60 min produced both the light and intravenous injection of morphine. A mean rate of approximately one response per second was maintained by doses of morphine ranging from 0.75–1.5 mg/kg. A pause in responding after each light presentation was followed by rapid responding until the light was produced again; pauses became shorter as the 60-min interval progressed. When brief light presentations were omitted, but morphine was still injected, response rates decreased and patterns of responding were altered. When saline injections were substituted for morphine injections, but the brief light was still presented, responding decreased markedly within three to five sessions and patterns of responding were altered.

Amnesia produced by intracerebroventricular injections of hemicholinium-3 in mice was prevented by pretreatment with piracetam-like compounds.

Intracerebroventricular (ICV) injections of hemicholinium-3 (HC-3) to mice before the training trial in a passive avoidance task produced an amnesic effect at the 24-hour retention test. Pretreatment by IP injection of piracetam, etiracetam, or pramiracetam, 30 minutes before HC-3 injections antagonized the amnesic effects of HC-3. Pretreatment with choline was not effective. The depletion of cerebral acetylcholine by the HC-3 injection was not prevented by piracetam or etiracetam.

Pharmacology of U-91356A, an agonist for the dopamine D2 receptor subtype

U-91356A [(R)-5,6-dihydro-5-(propylamino)4H-imidazo[4,5,1-ij]quinolin -2-(1H)-one, monohydrochloride], bound with highest affinity to the dopamine D2 receptor subtype, although it also bound with somewhat lower affinities to the dopamine D3 and D4, as well as the 5-HT1A receptor subtypes. In addition to depressing dopamine synthesis and turnover, injection of U-91356A increased striatal acetylcholine concentrations. U-91356A also depressed firing rates of dopamine neurons. In mice, this compound stimulated cage climbing and locomotor activity in reserpinized animals; it also antagonized D-amphetamine-stimulated locomotor activity. It produced contralateral turning in rats with unilateral lesions of the substantia nigra. These data are consistent with roles for the dopamine D2 receptor subtype as a dopamine autoreceptor and as a stimulatory, postsynaptic dopamine receptor.