Acute effects of d-amphetamine on the differential reinforcement of low-rate (DRL) schedule behavior in the rat: comparison with selective dopamine receptor antagonists

Amphetamine and it analogs have been shown to affect operant behavior maintained on the differential reinforcement of a low-rate (DRL) schedule. The aim of the present study was to investigate what specific component of the DRL response is affected by d-amphetamine. The acute effects of d-amphetamine on a DRL task were compared with those of the selective dopamine D1 and D2 receptor antagonists, SCH23390 and raclopride, respectively. Pentylenetetrazole and ketamine were also used as two reference drugs for comparison with d-amphetamine as a psychostimulant. Rats were trained to press a lever for water reinforcement on a DRL 10-s schedule. Acute treatment of d-amphetamine (0, 0.5, and 1.0 mg/kg) significantly increased the response rate and decreased the reinforcement in a dose-related fashion. It also caused a horizontal leftward shift in the inter-response time (IRT) distribution at the doses tested. Such a shifting effect was confirmed by a significant decrease in the peak time, while the mean peak rate and burse response remained unaffected. In contrast, both SCH23390 (0, 0.05, and 0.10 mg/kg) and raclopride (0, 0.2, and 0.4 mg/kg) significantly decreased the total, non-reinforced, and burst responses. The de-burst IRT distributions were flattened out as shown by the dose-related decreases in the mean peak rate for both dopamine antagonists, but no dramatic shift in peak time was detected. Interestingly, neither pentylenetetrazole (0, 5, and 10 mg/kg) nor ketamine (0, 1, and 10 mg/kg) disrupted the DRL behavioral performance. It is then conceivable that d-amphetamine at the doses tested affects the temporal regulation of DRL behavior. The effectiveness of d-amphetamine is derived from its drug action as a psychostimulant. Taken together, these data suggest that different behavioral components of DRL task are differentially sensitive to pharmacological manipulation.     

Differential effects of the pharmacological manipulation of serotonin systems on cocaine and amphetamine self-administration in rats

The effects of the administration of serotonergic drugs on infusion rates of rats self-administering cocaine and amphetamine on an FR-10 schedule of reinforcement in daily 4 hour sessions were compared. Pretreatment with fluoxetine (2.5, 5, and 10 mg/kg), an inhibitor of serotonin reuptake, significantly decreased rates of responding maintained by amphetamine, but had no effect on responding maintained by cocaine at any of the doses tested. Pretreatment with cinanserin (3, 10, and 17.5 mg/kg), a serotonergic receptor antagonist, decreased rates of amphetamine self-administration at the highest dose tested, and also had no effect on cocaine self-administration. These data suggest a differential sensitivity of cocaine and amphetamine self-administration to pharmacological manipulation of central serotonin systems. They are consistent with biochemical data which demonstrates a negative correlation between the reinforcing potency of amphetamine-like drugs, but not cocaine-like drugs and their potency at serotonin binding sites.     

Low-intensity magnetic fields alter operant behavior in rats

The present study demonstrates that operant behavior is affected by a combination of a 60-Hz magnetic field and a magnetostatic field 2.6 X 10(-5) T (about half the geomagnetic field). Rats exposed to this combination for 30 min consistently exhibited changes in the rate and pattern of responding during the differential reinforcement of low rate (DRL) component of a multiple fixed ratio (FR) DRL reinforcement schedule. By contrast, there were no measurable changes following exposure to the static field alone or to the oscillating field alone, even with a 10-fold increase in intensity (5 X 10(-5) to 5 X 10(-4) Trms). A cyclotron resonance mechanism has been suggested as a possible explanation for the observation that weak static magnetic fields modify the response of in vitro brain tissue to low-frequency magnetic fields. The choice of static field intensity Bo and frequency nu in the present study follows from the cyclotron resonance condition nu = (1/2 pi)(q/m)Bo, for singly charged lithium, an element in extensive use in the clinical treatment of affective disorders in humans. The present research is consistent with a cellular cyclotron resonance mechanism and tends to imply a functional dependence of behavior on the geomagnetic field.     

Influence of protective drugs on the elevation of extracellular potassium ion concentration in the brain during ischaemia

Influence of drugs on the changes of extracellular potassium ion concentration in the brain during total cerebral ischaemia was investigated. The aorta of the dogs was clamped twice with an intermittent reperfusion period of 60 min. In control experiments no significant difference was found in the elevation of extracellular potassium ion concentration of the brain during the first and second clampings. In the present study drugs were administered 10 min prior the second aorta occlusion. Verapamil in a dose of 0.125 mg/kg proved to be ineffective. Piridoxilate in a dose of 10 mg/kg and piracetam in a dose of 100 mg/kg delayed to a small extent the potassium outflow. The following drugs enhanced significantly the duration before the steep increase of potassium ion outflow: phenytoin in a dose of 10 mg/kg by 31.8 sec (p less than 0.01), ethyl-butyl-thiobarbital in a dose of 15 mg/kg by 30.2 sec (p less than 0.05), and lidocaine in a dose of 100 mg/kg by 115.8 sec (p less than 0.01). Comparing present results to our earlier data (obtained after 50 sec ischaemia) it can be concluded, that these protective influences become more effective during longer ischaemic period (2-5 min), when lidocaine, phenytoin and ethyl-butyl-thiobarbital were used. Moreover, in spite of the observation seen during shorter ischaemia, even piridoxilate and piracetam exerted some degree of protective effect. No such effect of verapamil could be detected in the present experimental model.     

Antipunishment effects of acute and repeated administration of phencyclidine and NPC 12626 in rats.

The effects of phencyclidine (PCP) and NPC 12626 on punished responding were examined using a modified Geller-Seifter procedure in rats. Both drugs are known to antagonize N-methyl-D-aspartate (NMDA) receptor mediated neurotransmission, albeit at different sites on the NMDA receptor complex. Rats were trained to lever press for food reinforcement under a multiple schedule, with responding in one component reinforced under a fixed-interval 60-sec schedule, while each response in the other component resulted in both food and brief electric shock. Both PCP and NPC 12626 produced selective increases in punished responding, although the effects were not as large as those produced by chlordiazepoxide. Repeated daily administration of each of these drugs for 6 days resulted in increases in punished responding during different portions of the treatment. A 5 mg/kg dose of chlordiazepoxide produced increases over the last 2 days of administration. PCP (2 mg/kg) produced an increase only during the second session, whereas NPC 12626 (30 mg/kg) produced increases for all but the first and fifth days of the 6-day regimen. Both competitive and noncompetitive NMDA antagonists can have antipunishment effects in this model.     

Similar effects of a beta-carboline and of flumazenil in negatively and positively reinforced learning tasks in mice.

Methyl beta-carboline-3-carboxylate (beta-CCM) and flumazenil (Ro15-1788) are known to be respectively an inverse agonist and an antagonist of the central benzodiazepine-receptor. Surprisingly, these two drugs have shown a similar enhancing effect in a negatively reinforced multiple-trial brightness discrimination task in mice. Thus, to evaluate the role of anxiety in this task, the action of these two drugs were compared in the same learning task with a positive or a negative reinforcement. Mice were trained for sessions of ten trials per day for six consecutive days. The sessions during the first three days took place after administration of beta-CCM (0.3 mg/kg), flumazenil (15 mg/kg) or vehicles of these drugs. A negative reinforcement (electric foot-shock) was used in a first experiment, and a positive one (food reward) in a second experiment. Results showed that, whatever the reinforcement, the two drugs enhance learning in a brightness discrimination task. The hypothesis is that flumazenil could have an inverse agonist profile in learning tasks. The question remains as to whether the flumazenil enhancing learning process results from increased arousal and/or anxiogenic factors, or from a negative modulatory influence of endogenous diazepam-like ligands for benzodiazepine receptors.     

Operant performance following tail-pinch in the rat: effects of d-amphetamine

To extend the investigation of tail-pinch induced behavioral changes, rats performing on a differential reinforcement of low rates of 10 sec (DRL10), a fixed-interval of 60 sec (F160), and a fixed-ratio of 20 (FR20) schedules were exposed to a paper clip applied to the tail. While a 10 min tail-pinch conducted 1 hr before operant sessions significantly altered the DRL10 behavior, this stressor had little effect on either F160 or FR20 responding. Marked DRL10 behavior performance changes following tail-pinch included increases in the number of lever presses, decreases in the number of the reinforcers, and disruption in the frequency distribution of inter-response times (IRT). These DRL10 operant deficits were diminished when the subject received a tail-pinch pretreatment followed by d-amphetamine treatment (0.2 and 2.0 mg/kg). In combination with biochemical data from others, the present results suggest that catecholamine systems are involved in modulation of DRL10 behavior following tail-pinch.     

Mimosa pudica may possess antidepressant actions in the rat.

In Mexico, aqueous extracts from dried leaves of Mimosa puolica are employed to alleviate depression. In this study, the behavioral actions of aqueous extracts of M. pudica at various concentrations were tested. Rats having received saline (0.9%; 0.30 ml; I.P.), clomipramine, desipramine or several dosages of aqueous extracts from M. pudica (ml = 2.0 mg/kg; m2 = 4.0 mg/kg; m3 = 6.0 mg/kg; m4 = 8.0 mg/kg) during a 30-day period were submitted to the forced swimming test and to the test for differential reinforcement of low rates of response at 72 sec (DRL-72s). Any possible anxiolytic action resulting from several doses (ml = 2.0 mg/kg; m2 = 4.0 mg/kg; m3 = 6.0 mg/kg; m4 = 8.0 mg/kg) of extracts of M. pudica were compared with those caused by diazepam (1.3 mg/kg, I.P.) in the elevated plus-maze test. Results showed that clomipramine (1.25 mg/kg, I.P.), desipramine (2.14 mg/kg, I.P.) and M. pudica (6.0 mg/kg and 8.0 mg/kg, I.P.) reduced immobility in the forced swimming test and increased the rate of reinforcers received in the DRL-72s test; these data suggest that M. pudica produces antidepressant effects in the rat. Diazepam increased the open-arms exploration time in the elevated plus-maze test, but M. pudica did not show any comparable action at any tested dose. M. pudica therefore produced an antide-pressant-like profile similar to two tricyclic antidepressants.     

Activation of 5-HT1A receptors in the medullary raphe reduces cardiovascular changes elicited by acute psychological and inflammatory stresses in rabbits

The present strategy for the prevention of excessive sympathetic neural traffic to the heart relies on the use of beta-blockers, drugs that act at the heart end of the brain-heart axis. In the present study, we attempted to suppress cardiac sympathetic nerve activity by affecting the relevant cardiomotoneurons in the brain using the selective serotonin-1A (5-HT(1A)) receptor agonist 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT). In conscious, unrestrained rabbits, instrumented for recordings of heart rate, arterial pressure, or cardiac output, we provoked increases in cardiac sympathetic activity by psychological (loud sound, pinprick, and air jet) or inflammatory (0.5 microg/kg iv lipopolysaccharide) stresses. Pinprick and air-jet stresses elicited transient increases in heart rate (+50 +/- 7 and +38 +/- 4 beats/min, respectively) and in mean arterial pressure (+16 +/- 2 and +15 +/- 3 mmHg, respectively). Lipopolysaccharide injection caused sustained increases in heart rate (from 210 +/- 3 to 268 +/- 10 beats/min) and in arterial pressure (from 74 +/- 3 to 92 +/- 4 mmHg). Systemically administered 8-OH-DPAT (0.004-0.1 mg/kg) substantially attenuated these responses in a dose-dependent manner. Drug effects were prevented by a selective 5-HT(1A) receptor antagonist, WAY-100635 (0.1 mg/kg iv). Similarly to systemic administration, microinjection of 8-OH-DPAT (500 nl of 10 mM solution) into the medullary raphe-parapyramidal region caused antitachycardic effects during stressful stimulation and during lipopolysaccharide-elicited tachycardia. This is the first demonstration that activation of 5-HT(1A) receptors in the medullary raphe-parapyramidal area causes suppression of neurally mediated cardiovascular changes during acute psychological and immune stresses.     

L-histidine attenuates the effects of pentazocine on rewarding brain-stimulation

Previous research has indicated that the antihistamine tripelennamine potentiates the threshold lowering effects of pentazocine on brain stimulation reward, a model of drug-induced euphoria. To determine the importance of histamine in this interaction, we studied the effects of co-administration of L-histidine and pentazocine on the threshold for brain stimulation reward. Pentazocine (2.5-10.0 mg/kg) lowered the threshold for rewarding stimulation to the medial forebrain bundle-lateral hypothalamus in male F344 rats. L-histidine (500 and 750 mg/kg) by itself had no significant effects, yet antagonized the threshold lowering effects of pentazocine. These doses of L-histidine are known to significantly raise brain histamine concentrations. Our results suggest that histamine may play a tonic inhibitory role, at least in part, on the neural systems responsible for the reinforcing properties of pentazocine.     

Dopamine receptor antagonists reverse amphetamine-induced behavioral alteration on a differential reinforcement for low-rate (DRL) operant task in the rat

Previous studies have shown that amphetamine significantly alters operant responding on the behavior maintained on a schedule of differential reinforcement of low-rate (DRL). As such, behavioral deficiency of DRL responding has been observed by the drug-induced increase of non-reinforced responses and a leftward shift of inter-response time (IRT) curve on DRL responding in the rat. However, the neurochemical basis for amphetamine-induced DRL behavioral alternations remain to be elucidated. The present study was then designed to examine whether the effects of amphetamine were dependent on dopamine-subtyped receptors, this was carried out by the co-administration of the selective D1 and D2 receptor antagonists, SCH23390 and raclopride respectively. Rats were first trained to perform on DRL 10-sec task and then divided into four groups, which received separate types of double injections before the behavioral session. The four groups were the saline control group, the amphetamine alone group, the dopamine antagonist alone group, and the combination of [corrected] amphetamine and dopamine antagonist group. The saline control group performed DRL responding in an efficient manner with a major index for the peak time of the IRT curve, which was fairly localized within the 10-sec bin throughout the test phase. The subjects injected with amphetamine (1 mg/kg) significantly shortened IRT that led to a leftward shift of IRT curve, which was further revealed by a decreased peak time without significant effectiveness on the peak rate and burst response. Even though the group given SCH23390 or raclopride alone showed profound disruption on DRL behavior by flattening the IRT curve, the co-administration of amphetamine with SCH23390 or raclopride reversed the aforementioned amphetamine-induced behavioral deficiency on DRL task. Together, these results suggest that the dopamine D1 and D2 receptors are involved and important to the temporal regulation of DRL response under psychostimulant drug treatment. Furthermore, this highlights the involvement of the brain dopamine systems in the temporal regulation of DRL behavior performance.     

Naloxone attenuation of the effect of cocaine on rewarding brain stimulation

Antagonism of the threshold lowering effect of cocaine for brain stimulation reward by naloxone was investigated. Rats with bipolar electrodes implanted in either the median forebrain bundle (MFB) or the ventral tegmental area (VTA) were trained on a rate-independent threshold procedure. Effective threshold lowering doses of cocaine (10-15 mg/kg i.p.) were determined for each subject. A moderate dose of naloxone (4 mg/kg i.p.) effectively blocked the threshold lowering action of the cocaine. Lower (2 mg/kg) and higher (8 mg/kg) doses of naloxone attenuated but did not completely block the cocaine effect. These results provide further evidence for a catecholamine/endogenous opioid interaction in central reward.     

Regional Heterogeneity of Nicotine Effects on Neurotransmitters in Rat Brains <Emphasis Type="Italic">in vivo</Emphasis> at Low Doses

In our recent studies on nicotine-induced changes in neurotransmitters in brain areas associated with cognitive function using a nicotine dose of 0.5 mg/kg administered subcutaneously to conscious freely moving rats, we found changes in dopamine, norepinephrine, and serotonin, and their metabolites, in the areas examined. For the present report we examined changes in these neurotransmitters following administration of lower nicotine doses, to test regional differences in nicotine response and possible threshold levels for some effects of nicotine. The doses used were 0.15 mg/kg and 0.03 mg/kg nicotine administered subcutaneously. Nicotine levels in the brain reached peak values in less than 10 min and decreased with a half-life of about 60 min (0.15 mg/kg) or 30 min (0.03 mg/kg) to values below detection limits (1 ng/g), by the later time points of the 0.03 mg/kg experiments. Nicotine-induced dopamine (DA) increase (and increase in DA metabolites) and decrease in 5-HT levels at 0.15 mg/kg were significant in the cortex, less so in the hippocampus. Norepinephrine (NE) increase at 0.15 mg/kg was much less significant than found previously at 0.5 mg/kg. At a low nicotine dose (0.03 mg/kg), the significant changes observed were a decrease in 5-HT in the hippocampus and small increases of DA and NE in the prefrontal cortex and of NE in the medial temporal cortex. In the nucleus accumbens DA, NE, and 5-HT and their metabolites in the ventral tegmental area, mostly DA and metabolites were increased. We conclude that in areas of cognitive function nicotine-induced DA changes are more concentration dependent than changes in NE or 5-HT, and that there are regional differences in neurotransmitter changes induced by nicotine, with NE changes detectable only in the cortex and 5-HT changes only in the hippocampus at a low nicotine dose, indicating significant regional variation in sensitivity to nicotine-induced neurotransmitter changes in brain areas associated with cognitive function. The decrease in 5-HT shows that nicotine also has indirect effects caused by neurotransmitters released by nicotine. The effects of low nicotine dose are more significant in areas of reward function, indicating differences in sensitivity between cognitive and reward functions.     

Inhibition of acetylcholinesterase in the gut inhibits schedule-controlled behavior in the rat

Rats were trained to press a lever under a multiple Fixed-Ratio 25 Fixed-Interval 50-second schedule of food reinforcement. Subcutaneous injection of soman, 80 micrograms/kg, suppressed responding under both schedules and inhibited acetylcholinesterase (AChE) in the brain. AChE activity in the gastrointestinal tract was not significantly inhibited. In contrast, i.p. injection of either soman (10-40 micrograms/kg), neostigmine (75 micrograms/kg) or DFP (350 micrograms/kg) caused marked suppression of behavior and AChE activity of the gut, without affecting brain AChE. These doses caused marked increases in peristaltic activity and likely caused gastrointestinal spasm. Injection of DFP, 500 micrograms/kg, s.c., inhibited AChE in both the brain and gut. The results indicate that inhibition of AChE in the gastrointestinal tract by certain anticholinesterase agents may be involved in the behavioral effects attributed to these drugs.     

Opioid antinociception and positive reinforcement are mediated by different types of opioid receptors

Fentanyl (FEN) and diprenorphine's (DIPR) potentials for analgesia and reinforcement were assayed using rats. Analgesia was measured by the classic tail-flick test. The test germane to opioid reinforcement involved measuring pressing rates for direct electrical stimulation of the lateral hypothalamus and ventral tegmental area. FEN, as does morphine and heroin, produced strong analgesia and enhanced pressing rates for brain stimulation. DIPR produced no analgesia and antagonized FEN's analgesia. DIPR, at doses antagonizing FEN's analgesia, enhanced pressing for brain stimulation. DIPR's enhancement of pressing was antagonized by naloxone (100 micrograms/kg). When FEN and DIPR were given concurrently, pressing for brain stimulation was not reduced and was greater than after FEN alone was given. These data support a conclusion that different types of receptors are associated with opioid analgesia and reinforcement.     

Effects of ethanol on punished and nonpunished responding under conditions of equated reinforcement rates and similar response rates

Lever pressing by pairs of rats was maintained under random-ratio (first subject) and yoked-interval (second subject) schedules of food presentation. The inter-reinforcement intervals generated under the ratio schedule comprised the interval values for the second (yoked) subject. This arrangement yielded nearly equivalent rates of food presentation for each subject pair. For the first rat of each pair a random-ratio schedule of shock presentation was added to the ratio schedule of food presentation. This manipulation resulted in similar rates of punished (first rat) and nonpunished (second rat) responding within subject pairs. Ethanol administration (0.25–1.5 g/kg) generally resulted in dose-related decreases in both punished and nonpunished responding. In general, punishment-specific effects were not obtained. These results suggest that ethanol may not be as effective as chlordiazepoxide or pentobarbital in increasing punished responding even when the effects of baseline response and reinforcement rates are controlled.     

Disruptive effects of lateral hypothalamic stimulation on the lick-interrupt cycle in rats

Consummatory licking at a water spout was compared with licking at a dry spout maintained by electrical hypothalamic stimulation in the same rats. Both forms of licking, recorded photoelectrically, were maintained on a fixed ratio 8 schedule. Duration of reinforcement delivery was equated [300 ms]. A computer analysis of the temporal distribution of licks in each 1024 ms period from onset of reinforcement revealed that lateral hypothalamic stimulation decreased the occurrence of licking and disrupted the normally synchronous pattern of this behaviour. An analysis of the effects of delivering lateral hypothalamic stimulation contingent on water-maintained licking revealed that this effect of stimulation was clearly current-dependent. It is proposed that differences in licking rates maintained by water and by electrical hypothalamic stimulation, respectively, are due to response interference in the latter case. This interference effect is also proposed to be a major factor underlying higher reward thresholds for self-stimulation when licking is the operant response.     

Immediate post-exposure effects of high-peak-power microwave pulses on operant behavior of Wistar rats.

Behavioral effects of high-peak-power microwave pulses on Wistar rats were studied by operant schedules. Each of twelve rats that had been trained to press a lever to receive food pellets was assigned randomly in groups of four to three different schedules of reinforcement: fixed-ratio (FR), variable-interval (VI), and differential-reinforcement-of-low-rates (DRL). After achieving a steady baseline performance, each animal was exposed for 10 min to 1.25-GHz microwave radiation at 1-MW peak-power (10-microseconds pulse width). Each pulse produced a peak whole-body SA and SAR of 2.1 J/kg and 0.21 MW/kg. Total doses (SAs) were set to 0.50, 1.5, 4.5, and 14 kJ/kg by adjusting the pulse-repetition rate. The corresponding time-averaged whole-body SARs were 0.84, 2.5, 7.6, and 23 W/kg. A microwave-transparent animal holder was used to keep the animal's body axis parallel to the E-field. Exposures at the highest dose caused an average colonic temperature rise of 2.5 degrees C and these animals failed to respond at all for about 13 minutes after the exposure. Their colonic temperatures had decreased to 1.1 degrees C, or less, above their pre-exposure (normal) temperature level when they began to respond. The FR and VI animals failed to reach their baseline levels of performance thereafter, while those on the DRL schedule displayed variable effects. No behavioral effects were found at the lower dose levels. It is concluded that the behavioral perturbations produced by pulsed microwave irradiation were thermal in nature.     

Behavioral testing of antidepressant compounds: an analysis of crossover design for correlated binary data

The differential reinforcement of low-rate 72 seconds schedule (DRL-72) is a standard behavioral test procedure for screening potential antidepressant compounds. The protocol for the DRL-72 experiment, proposed by Evenden et al. (1993), consists of using a crossover design for the experiment and one-way ANOVA for the statistical analysis. In this paper we discuss the choice of several crossover designs for the DRL-72 experiment and propose to estimate the treatment effects using either generalized linear mixed models (GLMM) or generalized estimating equation (GEE) models for clustered binary data.     

Neuroleptic-like properties of cholecystokinin analogs: distinctive mechanisms underlying similar behavioral profiles depending on the route of administration

Rats were trained to discriminate vehicle injections from intraperitoneal injections of 3 micrograms/kg caerulein, a cholecystokinin (CCK) neuropeptide analog. The reward that reinforced correct choices was an electrical brain stimulation self-administered by bar pressing. Dose-response quantitative generalization was obtained by using 1 and 2 micrograms/kg caerulein. Qualitative generalization to the vehicle occurred after injecting 10, 20 and 200 micrograms/kg unsulfated CCK-8, 10, 20 and 200 micrograms/kg CCK-4, 5 micrograms/kg CCK-8 and 1 microgram/kg caerulein, neurotensin or bombesin and 200 micrograms/kg apomorphine or 320 micrograms/kg amphetamine. Total generalization to the caerulein cue was obtained with 20 micrograms/kg sulfated CCK-8 or gastrin 2-17, 25 micrograms/kg somatostatin, 50 micrograms/kg haloperidol and 2 mg/kg chlorpromazine. The previous 5 mg/kg injection of an antiemetic drug such as chlorhydrate of trimethobenzamide did not eliminate the discriminative properties of a subsequent injection of caerulein. Our data thus tend to show that IP injection of caerulein produces effects similar to those of IP neuroleptics.