Interactions between the benzodiazepine receptor antagonist Ro 15-1788 (flumazepil) and the inverse agonist beta-CCE: behavioral studies with squirrel monkeys

The effects of Ro 15-1788 and ethyl-beta-carboline-3-carboxylate (beta-CCE) were studied alone and in combination on the behavioral performances of squirrel monkeys. Under one procedure, performances maintained by food were suppressed by electric shock presentation (punishment or "conflict" procedure). Under a second procedure, responding was maintained either by food or electric shock delivery under a 5-min fixed-interval schedule. Doses of beta-CCE between 0.1 and 3.0 mg/kg, i.m., produced graded decreases in punished responding which were reversed by pretreatment with Ro 15-1788 (1.0 - 10.0 mg/kg, i.m.). Low doses of beta-CCE (0.03 - 0.3 mg/kg, i.m.) increased responding of monkeys maintained by shock presentation, but did not affect food-maintained responding; higher doses of beta-CCE decreased responding under both schedules. These effects of beta-CCE are opposite those produced by the benzodiazepines under this procedure. Ro 15-1788 (1.0 mg/kg i.m.) antagonized the effects of beta-CCE, producing a shift to the right in the dose-response curves. These findings provide further support for the view that beta-CCE and Ro 15-1788 produce effects mediated by the same benzodiazepine receptor recognition site.     

Behavioral effects of benzodiazepine antagonists in chlordiazepoxide tolerant and non-tolerant rats

Rats were trained to respond under 3-min fixed-interval schedules of food presentation, and effects of the benzodiazepine-receptor ligands, flumazenil, 2-(4-methoxy-phenyl)-pyrazolo[4,3-c]quinolin-3(5H)-one (CGS 9895), 3-carbo-t-butoxy-beta-carboline (beta-CCtB), and beta-carboline-3-carboxylic acid ethyl ester (beta-CCE) were assessed before and after the induction of tolerance to chlordiazepoxide. Before daily administration of chlordiazepoxide, none of the antagonists produced appreciable effects on rates of responding up to doses of 32.0 mg/kg i.p. beta-CCE was the only antagonist studied at a higher dose (100.0 mg/kg i.p.), which decreased response rates. After 23 days of daily chlordiazepoxide administration (oral doses started at 10 and increased to 100 mg/kg/day by the 17th day), dose-effect curves for chlordiazepoxide were shifted to the right by about one-half log unit. Subjects were also more sensitive to the flumazenil, CGS 9895, and beta-CCtB, however, since these drugs produced only small effects in non-tolerant subjects, precise estimates of the degree of the shift in dose-effect curves could not be estimated. However, there were differences in the changes in the dose-effect curves induced by chlordiazepoxide tolerance. These results suggest differences in mechanism of action of antagonists in tolerant and non-tolerant subjects, and further that the sensitivity that is induced to antagonists in tolerant subjects is not conferred equally to all drugs having benzodiazepine antagonist activity.     

Behavioral effects and benzodiazepine antagonist activity of Ro 15-1788 (flumazepil) in pigeons

The selective benzodiazepine receptor antagonist, Ro 15-1788, produced behavioral effects in pigeons at doses at least 100 times lower than those previously reported to possess intrinsic pharmacological activity in mammals. In contrast to its effects in mammalian species, in pigeons, Ro 15-1788 does not exhibit partial agonist activity. Key-peck responses of pigeons were studied under a multiple fixed-interval 3-min, fixed-interval 3-min schedule in which the first response after 3-min produced food in the presence of red or white keylights. In addition, every 30th response during the red keylight produced a brief electric shock (punishment). Under control conditions, punished responding was suppressed to 30% of unpunished response levels. Ro 15-1788 (0.01 mg/kg, i.m.) increased unpunished response rates by 33% without affecting rates of punished responding. Doses of 0.1 to 1.0 mg/kg Ro 15-1788 produced dose-related decreases in both punished and unpunished responding. As is characteristic of other benzodiazepines, midazolam (0.1 and 0.3 mg/kg, i.m.) markedly increased punished responding but had little effect on rates of unpunished responding. Ro 15-1788 antagonized the increases in punished responding and also reversed the rate-decreasing effects of higher doses of midazolam. However, the effectiveness of Ro 15-1788 as a benzodiazepine antagonist was limited by its intrinsic activity: rate-decreasing doses of Ro 15-1788 were unable to completely reverse behavioral effects of midazolam. Midazolam was an effective antagonist of the behavioral effects of Ro 15-1788 (up to 0.1 mg/kg) but midazolam did not influence the rate-decreasing effects of 1.0 mg/kg Ro 15-1788 across a 100-fold dose range. In the pigeon, the behavioral effects of relatively low doses of Ro 15-1788 (0.01-0.1 mg/kg) appear to be related to benzodiazepine receptor mechanisms, whereas other systems appear to be involved in the effects of higher doses.     

Discriminative stimulus properties of oxazepam in the pigeon

Five pigeons were trained to discriminate IM injections of oxazepam (4.0 mg/kg) from vehicle with responding maintained under a fixed-ratio 30 schedule of food delivery. Under test conditions, responding increased in a dose-dependent manner in all pigeons after the administration of other benzodiazepines including diazepam (0.01-1.0 mg/kg), temazepam (0.01-3.0 mg/kg), halazepam (0.1-56.0 mg/kg), and midazolam (0.1-1.0 mg/kg) as well as the barbiturate pentobarbital (2.0-8.0 mg/kg) and the non-benzodiazepine anxiolytic CL 218,872 (1.0-8.0 mg/kg). At the higher doses of each of these compounds, over 80% of responding occurred on the oxazepam-appropriate key. Cocaine (0.5-4.0 mg/kg), bupropion (3.0-56.0 mg/kg) and nortriptyline (3.0-56.0 mg/kg) failed to substitute for oxazepam even at doses that decreased rates of responding. The discriminative stimulus (DS) effects of the lowest doses of oxazepam and CL 218,872 that produced 100% drug-appropriate responding were blocked by the benzodiazepine antagonist Ro 15-1788. This antagonism was reversed by increasing the dose of the agonists. The DS effects of diazepam were antagonized partially by Ro 15-1788 (3 of 5 pigeons), and the antagonism was reversed by higher doses of diazepam in two of these pigeons. The DS effects of pentobarbital were antagonized by Ro 15-1788 in 2 of 5 pigeons, but the blockade was not reversed by higher pentobarbital doses.     

Effects of corticotropin-releasing factor (CRF), tuftsin and dermorphin on behavior of squirrel monkeys maintained by different events

The effects of intracerebroventricular (ICV) administration of ovine CRF (0.1–30.0 μg/kg), dermorphin (0.3–30.0 μg/kg) and tuftsin (10–3000 μg/kg) were examined in squirrel monkeys trained to respond under a multiple 3-min fixed-interval schedule of food presentation and either shock presentation or stimulus-shock termination. Initial administration of the 41-amino acid polypeptide CRF increased food-maintained responding by 150–200% in 2 of 3 subjects. However, no other doses tested affected response rates, a result that may have been due to the rapid development of tolerance. The tetrapeptide tuftsin selectively increased responding maintained by food presentation at doses that decreased shock-maintained responding. The heptapeptide dermorphin selectively increased food-maintained responding when responding in the other component of the multiple schedule was maintained by shock presentation. When responding was maintained by a multiple food, stimulus-shock termination schedule, dermorphin decreased response rates in both components. Dermorphin's rate increases were blocked by the opiate antagonist naloxone, indicating that dermorphin's actions were mediated through the opiate receptor. These results indicate that the behavioral effects of tuftsin, dermorphin, and perhaps CRF, depend on the manner in which responding is controlled by its consequences. While the actions of tuftsin and dermorphin are believed to be mediated through the opiate system, the behavioral effects observed in primates appear different from the effects of morphine under similar schedule conditions.     

Effects of thyrotropin-releasing hormone (TRH) and MK-771 on behavior of squirrel monkeys controlled by noxious stimuli

The effects of TRH (0.1-30 mg/kg) and an enzyme-resistant analogue, MK-771 (0.1-10 mg/kg), were characterized in squirrel monkeys on responding maintained in the presence of different visual stimuli by a multiple 3-min fixed-interval (FI), 30-response fixed-ratio (FR) schedule of stimulus-shock termination or by a multiple 5-min FI schedule of food or shock presentation. Under the termination schedule, the first response at the end of 3 min in the FI component or the completion of the 30-response requirement in the FR component terminated the visual stimulus in the presence of which shocks occurred (escape schedule). Under the schedule of food or shock presentation, the first response at the end of the 5-min FI produced food in the presence of red stimulus lights or shock in the presence of white lights. TRH and MK-771 produced large, dose-related increases in responding maintained under the FR stimulus-shock termination schedule whereas these peptides produced smaller increases or did not affect responding under the FI schedule. TRH and MK-771 also produced marked increases in responding maintained by shock presentation at doses that did not alter or decreased food-maintained responding in the same subject. Thus, performances maintained by noxious stimuli are uniquely sensitive to the rate-increasing effects of TRH and MK-771. These findings suggest that the behavioral effects of the neuropeptides, TRH and MK-771, can depend on the specific consequences of behavior and, as such, the effects of these substances are determined by many of the same variables that determine the effects of other behaviorally-active drugs.     

Potentiation of the behavioral effects of pentobarbital, chlordiazepoxide and ethanol by thyrotropin-releasing hormone

Effects of pentobarbital, chlordiazepoxide and ethanol were studied alone and in combination with thyrotropin-releasing hormone (TRH), IM, on punished behavior. Key-peck responses of pigeons were maintained by food presentation under a fixed-interval 3-min schedule in which every 30th response produced shock. Moderate doses of pentobarbital, chlordiazepoxide and ethanol increased punished responding to 150-200% of control values while the higher doses of these drugs almost completely eliminated responding. TRH (0.01-1 mg/kg) had little effect on punished responding and 3 mg/kg produced 50% decreases. Although the lower doses of TRH were without effect when given alone, doses of 0.03 mg/kg and greater markedly potentiated the rate-increasing effects of pentobarbital, chlordiazepoxide and ethanol. Increases in punished responding of 350% were obtained with combinations of TRH and these drugs. The rate-decreasing effects of the sedative-hypnotic and anxiolytic compounds were not reversed by TRH. Potentiation of the behavioral effects of sedative-hypnotic and anxiolytic drugs by TRH suggests that TRH may play an important role in modulating the behavioral effects of these compounds and that combinations of neuroactive peptides with certain psychotherapeutic agents may be of some therapeutic value.     

Discriminative stimulus,antagonist, and rate-decreasing effects of cyclorphan: Multiple modes of action

The discriminative effects of cyclorphan were studied in pigeons trained to discriminate 0.32 mg/kg ethylketazocine, 1.8 mg/kg cyclazocine, or 32 mg/kg naltrexone from saline. A fourth group of pigeons was administered 100 mg/kg/day morphine and trained to discriminate 0.1 mg/kg naltrexone from saline. Cyclorphan produced dose-related ethylketazocine-appropriate responding that reached a maximum of 83% of the total session responses at 0.3 mg/kg. Higher cyclorphan doses produced less ethylketazocine-appropriate responding. In pigeons trained to discriminate cyclazocine from saline, maximum drug-appropriate responding of greater than 90% occured at 5.6–10.0 mg/kg cyclorphan. In narcotic-naive pigeons trained to discriminate 32 mg/kg naltrexone from saline, cyclorphan produced a maximum of less than 50% drug-appropriate responding. In contrast, in pigeons chronically administered morphine and trained to discriminate 0.1 mg/kg naltrexone from saline, 1.0 mg/kg cyclorphan resulted in 100% drug-appropriate responding. In pigeons responding under a multiple fixed-interval, fixed-ratio schedule of food delivery, cyclorphan produced a complete dose-related reversal of the rate-decreasing effects of 10 mg/kg morphine, the maximally effective antagonist doses being 1.0–3.2 mg/kg. Higher cyclorphan doses (10 mg/kg) resulted in response rate decreases that were not reversed by naloxone (1 mg/kg). Thus, cyclorphan has discriminative effects that are similar to those of both ethylketazocine and, at 20-fold higher doses, cyclazocine. In addition, in morphine-treated pigeons, cyclorphan, across the same range of doses that produce ethylketazocine-appropriate responding, has discriminative effects that are similar to those of naltrexone, an effect that is probably related to the antagonist action of the drug.     

Effects of the alpha 1-adrenergic agonist cirazoline on locomotion and brown adipose tissue thermogenesis in the rat.

Anorexia is induced by injection of alpha 1-adrenergic receptor agonists into the hypothalamic paraventricular nucleus (PVN) in rats. Of the agonists tested to date, cirazoline is the most potent when administered either into the PVN or systemically. The present experiments assess the effects of systemically administered cirazoline, at doses that suppress food intake, on dopamine and norepinephrine systems as evident in locomotion and stereotypy and in the induction of brown adipose tissue (BAT) thermogenesis. In Experiment 1, adult male rats were treated with either vehicle (0) or 0.05, 0.1, 0.2 or 0.4 mg/kg cirazoline (IP) prior to 30 minutes assessment of horizontal and vertical locomotion and stereotypy in Omnitech activity chambers. Horizontal activity and stereotypy were significantly suppressed at 0.05 mg/kg cirazoline but these effects waned at higher cirazoline doses. In Experiment 2, interscapular BAT temperature in adult male rats was monitored for 30 minutes after injection (IP) of either vehicle or 0.4 mg/kg cirazoline. Cirazoline, at 0.4 mg/kg did not influence BAT temperature whereas a positive control treatment (phenylpropanolamine: 40 mg/kg) rapidly increased BAT temperature during a 15 minute period after injection. These results suggest that cirazoline-induced anorexia is not the result of competing motor responses and that this drug, at a dose that produces maximal suppression of feeding, does not alter BAT thermogenesis.     

The effects of naloxone,diprenorphine, and diazepam on responding suppressed by pre-shock and pre-food stimuli

The lever-pressing of rats was reinforced with food according to a variable-interval 1-min schedule. In one group, occasional illumination of cue lights for 30-sec periods was followed by a brief electric shock; responding was suppressed during these periods. Naloxone (0.01–10 mg/kg) did not change the degree to which responding was suppressed during the pre-shock stimulus. Diprenorphine (0.1–10 mg/kg) slightly attenuated suppression, and diazepam (1.0–3.0 mg/kg) increased responding during the stimulus to normal levels. These results confirm that opiate antagonists do not always enhance the effects of shock on behavior. In a second group, occasional illumination of the cue lights for 20-sec periods was followed by delivery of free food pellets. Responding was also suppressed during the pre-food stimulus. Neither naloxone nor diprenorphine had any effect on response rate during this stimulus. In contrast to the results of earlier studies using benzodiazepines, diazepam (1.0–3.0 mg/kg) produced a marked attenuation of response suppression during the pre-food stimulus.     

Linagliptin improves insulin sensitivity and hepatic steatosis in diet-induced obesity

Linagliptin (TRADJENTA?) is a selective dipeptidyl peptidase-4 (DPP-4) inhibitor. DPP-4 inhibition attenuates insulin resistance and improves peripheral glucose utilization in humans. However, the effects of chronic DPP-4 inhibition on insulin sensitivity are not known. The effects of long-term treatment (3-4 weeks) with 3 mg/kg/day or 30 mg/kg/day linagliptin on insulin sensitivity and liver fat content were determined in diet-induced obese C57BL/6 mice. Chow-fed animals served as controls. DPP-4 activity was significantly inhibited (67-89%) by linagliptin (P<0.001). Following an oral glucose tolerance test, blood glucose concentrations (measured as area under the curve) were significantly suppressed after treatment with 3 mg/kg/day (-16.5% to -20.3%; P<0.01) or 30 mg/kg/day (-14.5% to -26.4%; P<0.05) linagliptin (both P<0.01). Liver fat content was significantly reduced by linagliptin in a dose-dependent manner (both doses P<0.001). Diet-induced obese mice treated for 4 weeks with 3 mg/kg/day or 30 mg/kg/day linagliptin had significantly improved glycated hemoglobin compared with vehicle (both P<0.001). Significant dose-dependent improvements in glucose disposal rates were observed during the steady state of the euglycemic-hyperinsulinemic clamp: 27.3 mg/kg/minute and 32.2 mg/kg/minute in the 3 mg/kg/day and 30 mg/kg/day linagliptin groups, respectively; compared with 20.9 mg/kg/minute with vehicle (P<0.001). Hepatic glucose production was significantly suppressed during the clamp: 4.7 mg/kg/minute and 2.1 mg/kg/minute in the 3 mg/kg/day and 30 mg/kg/day linagliptin groups, respectively; compared with 12.5 mg/kg/minute with vehicle (P<0.001). In addition, 30 mg/kg/day linagliptin treatment resulted in a significantly reduced number of macrophages infiltrating adipose tissue (P<0.05). Linagliptin treatment also decreased liver expression of PTP1B, SOCS3, SREBP1c, SCD-1 and FAS (P<0.05). Other tissues like muscle, heart and kidney were not significantly affected by the insulin sensitizing effect of linagliptin. Long-term linagliptin treatment reduced liver fat content in animals with diet-induced hepatic steatosis and insulin resistance, and may account for improved insulin sensitivity.     

Metkephamid effects on operant behavior

Intravenous injections of high doses of metkephamid (20 and 40 mg/kg) decreased responding by pigeons under a multiple fixed-ratio, fixed-interval schedule of grain presentation. Naloxone antagonized in a dose-related manner the suppression of behavior produced by 40 mg/kg of metkephamid. Daily maintenance on large doses (30 and 60 mg/kg PO) of dl-methadone produced a slight shift of the dose-effect curve of metkephamid to the right. The data suggest that the behavioral effects of metkephamid are due to an action at a mu-opioid receptor.     

Effects of thyrotropin-releasing hormone (TRH) and MK-771 on schedule-controlled behavior of squirrel monkeys, rabbits and pigeons

The effects of TRH (0.001-10.0 mg/kg) and a more potent TRH analog, MK-771 (0.001-5.6 mg/kg), were studied on comparable schedule-controlled performances of squirrel monkeys, rabbits and pigeons. Responding was maintained in the presence of different stimuli by a multiple fixed-ratio (FR), fixed-interval (FI) schedule of food presentation (monkeys and pigeons) or 0.25% saccharin solution (rabbits). Generally, TRH and MK-771 produced decreases in responding under both schedules and in all three species. TRH and MK-771 were roughly equipotent in the squirrel monkey, whereas in the pigeon and rabbit MK-771 was approximately 20 times more potent than TRH in decreasing responding to 50 percent of control levels. The duration of action of doses of TRH and MK-771 that reduced responding to 50 percent of control was approximately 3 hr in the squirrel monkey; recovery of performance occurred twice as fast under the FR schedules. With the pigeon, TRH effects that produced 50 percent decreases in responding lasted over 6 hours, whereas behaviorally comparable doses of MK-771 lasted about 4 hours. With few exceptions, TRH and MK-771 appear to produce similar effects of schedule-controlled behavioral performances of the squirrel monkey, rabbit and pigeon. Compared to the effects of other behaviorally-active substances under these procedures, TRH and MK-771 exert a distinctive array of effects.     

Acute and chronic effects of FR-149175, a beta 3-adrenergic receptor agonist, on energy expenditure in Zucker fatty rats

Clinical therapies for both obesity and obese non-insulin-dependent diabetes mellitus require maintenance of reduced body weight after the initial successful reduction resulting from calorie control, exercise, or medication. Although beta(3)-adrenergic receptor (beta(3)-AR) agonists have been shown to stimulate whole body energy expenditure and lipid mobilization, whether stimulatory effects on oxygen consumption and lipolysis are influenced by chronic exposure to agonists has not been fully characterized. We therefore examined the acute and chronic effects of FR-149175, a selective beta(3)-AR agonist, on whole body oxygen consumption in genetically obese Zucker fatty rats. Chronic treatment with FR-149175 caused a decrease in both body weight gain and white fat pad weight at doses that induced lipolysis in acute treatment (1 and 3.2 mg/kg p.o.). Single administration of FR-149175 (0.1, 1, and 3.2 mg/kg p.o.) dose dependently increased whole body oxygen consumption. Repetitive administration did not cause attenuation of the thermogenic response at lower doses (0.1 and 1 mg/kg 2 times daily), whereas the highest dose (3.2 mg/kg 2 times daily) induced a progressive increase in oxygen consumption. PCR analyses of retroperitoneal white adipose tissue indicated little or no change in beta(3)-AR mRNA levels. Uncoupling protein 1 gene expression increased at 1 mg/kg, and drastic upregulation was detected at 3.2 mg/kg. FR-149175 also increased HSL mRNA levels in a dose-related manner, whereas there was no effect on genes involved in beta-oxidation. These results support that the thermogenic effect of beta(3)-AR agonists is not attenuated by chronic exposure to agonists.     

Reversal of morphine, methadone and heroin induced effects in mice by naloxone methiodide

Opioid overdose, which is commonly associated with opioid induced respiratory depression, is a problem with both therapeutic and illicit opioid use. While the central mechanisms involved in the effects of opioids are well described, it has also been suggested that a peripheral component may contribute to the effects observed. This study aimed to further characterise the effects of the peripherally acting naloxone methiodide on the respiratory, analgesic and withdrawal effects produced by various opioid agonists. A comparison of the respiratory and analgesic effects of morphine, methadone and heroin in male Swiss-Albino mice was conducted and respiratory depressive ED(80) doses of each opioid determined. These doses (morphine 9 mg/kg i.p., methadone 7 mg/kg i.p., and heroin 17 mg/kg i.p.) were then used to show that both naloxone (3 mg/kg i.p.) and naloxone methiodide (30-100 mg/kg i.p.) could reverse the respiratory and analgesic effects of these opioid agonists, but only naloxone precipitated withdrawal. Further investigation in female C57BL/6J mice using barometric plethysmography found that both opioid antagonists could reverse methadone induced decreases in respiratory rate and increases in tidal volume. Its effects do not appear to be strain or sex dependent. It was concluded that naloxone methiodide can reverse the respiratory and analgesic actions of a variety of opioid agonists, without inducing opioid withdrawal.     

Ketazocines and morphine: effects on gastrointestinal transit after central and peripheral administration

The mu agonist, morphine, and the prototype kappa agonists, ketocyclazocine and ethylketocyclazocine (EK), were studied for their effects on gastrointestinal transit. Following s.c. administration, both morphine (0.3-3 mg/kg) and ketocyclazocine (0.3-10 mg/kg) antagonized transit of an opaque marker through the small intestines of mice. Morphine (0.1-1 microgram) was also effective after intracerebroventricular (icv) administration in mice whereas ketocyclazocine (0.3-30 micrograms) was not. Similarly, while both morphine (0.3-5 mg/kg) and EK (0.6-10 mg/kg) slowed transit after s.c. injection to rats, only morphine (1-10 micrograms), but not EK (0.3-300 micrograms), was active following icv administration. Icv infusion of the mu benzomorphan, phenazocine (10-100 micrograms), slowed transit in a dose-related manner. These results indicate that there may be an anatomically distinct distribution of receptors for benzomorphan kappa agonists in both the mouse and rat, with these opiate receptors not being located near the lateral cerebral ventricles. The difference in efficacy between morphine and ketazocines in slowing gastrointestinal transit after icv administration to rodents suggests that (a) inactivity in this endpoint is a characteristic of benzomorphan kappa compounds and (b) the model may serve as a useful screen when establishing in vivo profiles of kappa agonists in mice and rats.     

Discriminative stimulus properties of stereoisomers of cyclazocine in phencyclidine-trained squirrel monkeys

Squirrel monkeys were trained to discriminate 0.16 mg/kg phencyclidine (PCP) from saline in a two-layer drug discrimination task on a fixed-ratio 32 schedule of food presentation. After reliable discriminative control of lever choice was established, dose-response determinations for generalization to the training dose of PCP were made with several doses of PCP, a racemic mixture of cyclazocine and the pure (+)- and (-)-isomers of cyclazocine. Only PCP and the (+)-isomer produced dose-dependent PCP-appropriate responding. Neither the racemic mixture nor (-)-cyclazocine produced over 25% PCP-appropriate responding at any of the doses tested. (+)-Cyclazocine was eight times less potent than PCP in producing drug-lever appropriate responding. (-)-Cyclazocine was about 30 times more potent than PCP and over 200 times more potent than (+)-cyclazocine in overall response rate suppression. The potency of the racemic mixture for response-rate suppression was consistent with an additive effect of the isomers. Neither the PCP-lever appropriate responding produced by (+)-cyclazocine nor the response-rate suppression produced by (-)-cyclazocine were antagonized by naloxone. Thus, racemic cyclazocine is composed of two isomers with differing behavioral effects. The (-)-isomer is more potent, and the (+)-isomer has more specificity for PCP-like effects.     

Effects of methamphetamine on response rate: a microstructural analysis

Key pecking in pigeons was maintained under a multiple random-interval (RI) 1-min, RI 4-min schedule of food presentation. Several doses (0.3-5.6 mg/kg) of methamphetamine were administered, and effects on overall response rates and on the microstructure of responding were characterized. In three of the four pigeons, methamphetamine dose-dependently decreased overall response rate in both components; in the fourth pigeon, intermediate doses increased response rates. Log-survivor analyses did not produce the clear "broken-stick" pattern previously reported with rats [Shull, R.L., Gaynor, S.T., Grimes, J.A., 2001. Response rate viewed as engagement bouts: effects of relative reinforcement and schedule type. J. Exp. Anal. Behav. 75, 247-274]. A fine-grained analysis of inter-response times (IRTs) revealed clear bands of responding around certain IRT durations. Methamphetamine tended to decrease the frequency of IRTs in the shorter bands and increase the frequency of IRTs across all bins greater than 2s. These results suggest that (a) survivor analyses may not extend to pigeon key pecking, (b) microstructural analyses can reveal order not evident with overall response rate, and (c) a detailed analysis of responding might prove more useful than summary measures in characterizing drug effects on behavior.     

3-carboethoxy-beta-carboline (beta-CCE) elicits electroencephalographic seizures in rats: reversal by the benzodiazepine antagonist CGS 8216

Intravenous administration of 3-carboethoxy-beta-carboline (beta-CCE, 10 mg/kg) to rats resulted in multiple bursts of rhythmic waves (2-4 second duration, 5-7 Hz) with amplitudes of 100-250 microV. Pretreatment of animals with the benzodiazepine receptor antagonists CGS 8216 prevented the electroencephalographic seizures elicited by beta-CCE. This dose of CGS 8216 did not produce any electroencephalographic abnormalities when administered alone. These observations suggest that the electroencephalographic seizures elicited by beta-CCE are mediated via an interaction with benzodiazepine receptors. An in vitro study of the rate of degradation of beta-CCE and 3-carbomethoxy-beta-carboline (beta-CCM) in rat plasma demonstrated that the rate of degradation of the former compound was three times more rapid than the latter. These observations, taken together with previous studies demonstrating that parenteral administration of beta-CCM elicits tonic and clonic seizures, suggests that pharmacokinetic factors may be involved in defining the pharmacologic profile of beta-carboline-3-carboxylic acid esters.     

Discriminative and aversive properties of beta-carboline-3-carboxylic acid ethyl ester, a benzodiazepine receptor inverse agonist, in rhesus monkeys

Rhesus monkeys were trained to discriminate injections of saline from those of beta-carboline-3-carboxylic acid ethyl ester (beta-CCE), a compound that binds to the benzodiazepine receptor, but often has actions opposite to those of the benzodiazepines. A benzodiazepine agonist midazolam and low doses of a specific benzodiazepine antagonist, Ro 15-1788, reversed the discriminative effects of beta-CCE. Higher doses of Ro 15-1788 produced stimulus effects similar to beta-CCE. In a separate experiment, monkeys responded to terminate intravenous infusions of beta-CCE, but not midazolam. This aversive effect of beta-CCE was reversed by Ro 15-1788. The behavioral effects of beta-CCE in these non-human primates are consistent with other data that have shown it to act on benzodiazepine receptors, and support the hypothesis that beta-CCE can be considered an inverse agonist at this receptor.