Drug-induced circling preference in rats

Drugs of abuse, such as phencyclidine (PCP), methamphetamine (METH), and cocaine (COC) are known to affect several behaviors in rats, such as motor activity, stereotypy, and circling. In this study, we evaluated whether these drugs produce circling preferences in the presence or absence of unilateral 6-hydroxydopamine (6-OHDA)-induced lesions of the caudate nucleus. Adult male CD rats were lesioned with 10 μg 6-OHDA/site. Animals were dosed with PCP (15 mg/kg, ip), its congener, (+) MK-801 (0.15 mg/kg, ip), METH (2 mg/kg, ip), COC (60 mg/kg, ip), or apomorphine (0.2 mg/kg, ip). circling preference was recorded in control and lesioned rats for 2 h before animals were sacrificed to determine monoamine levels by HPLC/EC. In control animals, administration of these drugs produced 60–70% left circling. In, lesioned animals, these drugs produced 78–90% ipsilateral (toward the lesion) circling, except apomorphine, which produced 60–80% contralateral (away from the lesion) circling. Dopamine (DA) and its metabolites 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) concentrations significantly decreased ipsilaterally in lesioned caudate nucleus (CN) and substantia nigra (SN). However, no significant changes were observed in nucleus accumbens (NA) and olfactory tubercles (OT). These data demonstrate that drugs of abuse like PCP, its congener (+) MK-801, METH, and COC produce a greater preference to turn toward the left than the right, a finding similar to that found in human psychosis. Since 6-OHDA lesions enhanced the circling bias and depleted DA and its metabolites DOPAC and HVA, it also suggests that the dopaminergic system may be involved in the circling behavior.     

The role of nigral projections to the thalamus in drug-induced circling behaviour in the rat

Unilateral injection of 6-hydroxydopamine (6-OHDA) into the ascending nigrostriatal pathway caused contraversive circling to apomorphine and ipsiversive circling to amphetamine respectively. An electrolesion of the ventromedial thalamic nucleus on the same side as the 6-OHDA lesion reduced apomorphine-induced circling, but not that to amphetamine. An electrolesion of the ventromedial thalamic nucleus on the side opposite to the 6-OHDA lesion reduced amphetamine circling but not that to apomorphine. Bilateral electrolesions of the ventromedial thalamic nucleus reduced neither apomorphine- nor amphetamine-induced circling. Electrolytic lesions of the parafascicular thalamic nucleus did not reduce apomorphine- or amphetamine-induced circling in animals with a unilateral 6-OHDA lesion of the nigrostriatal pathway. Knife cuts rostral and dorsal to the substantia nigra did not attenuate circling induced by injection of muscimol into the substantia nigra. Circling due to activition of nigral output pathways can be mediated by descending nigro-reticular pathways.     

Effects of training on biochemical and functional properties of rodent neonatal heart

This study was undertaken to determine biochemical and functional (in vivo) adaptations of the rodent neonatal heart in response to a training program of endurance running. Ten day-old rats were progressively trained on a treadmill (final intensity, 21 m/min, 30% grade, 1 h/day) until 75 days of age. The training program induced 14, 57, and 24% increases in relative heart mass, skeletal muscle citrate synthase activity, and whole-body maximal O2 uptake, respectively (P less than 0.05). Cardiac myosin (ATPase) and Ca2+-regulated myofibril ATPase were both reduced by approximately 15% in trained vs. sedentary animals (P less than 0.05). In the majority of trained hearts examined, the myosin isozyme profile reflected an estimated 14 +/- 3% shift toward the V3 or low ATPase isozyme. Left ventricular functional indices during submaximal exercise, derived from a fluid-filled indwelling cannula, indicated that the trained animals maintained similar left ventricular (LV) systolic pressure, LV + the time derivative of pressure, and systemic arterial mean blood pressure compared with their sedentary counterparts. These functional parameters were maintained even though the trained animals performed with lower submaximal exercise heart rate. These findings suggest that maximal exercise capacity can be enhanced in neonatal rats even though the biochemical potential for ATP degradation in the cardiac contractile system is lowered. We speculate that the trend to maintain the myosin isozyme pattern further in the direction of the V3 isozyme in the trained neonatal rat heart may reflect a means to economize cross-bridge cycling while maintaining normal levels of ventricle performance at a given submaximal work load.     

Drug-induced circling after unilateral 6-hydroxydopamine lesions of the nigro-striatal pathway is mediated via the midbrain periaqueductal grey and adjacent reticular formation (angular complex)

Unilateral 6-hydroxydopamine (6OHDA) lesions of the nigrostriatal pathway resulted in contraversive rotation to apomorphine and ipsiversive rotation to amphetamine. Electrolytic lesioning of the nucleus reticularis gigantocellularis or kainic acid lesions of the nucleus tegmenti pedunculopontis on the same side as the 6OHDA lesion did not reduce apomorphine- or amphetamine-induced circling. An electrolesion of the angular complex (periaqueductal grey and adjacent reticular formation) on the same side as the 6OHDA lesion reduced apomorphine-induced circling and increased amphetamine-induced circling. Bilateral electrolesions of the angular complex reduced both apomorphine- and amphetamine-induced rotation. The decrease in rotation was due to a loss of postural asymmetry while locomotor hyperactivity was maintained. A unilateral kainic acid lesion of the angular complex alone caused weak ipsiversive rotation which was enhanced by apomorphine and amphetamine. When a unilateral kainic acid lesion of the angular complex was made on the same side as a prior 6OHDA lesion, both apomorphine and amphetamine induced ipsiversive rotation. The area of the angular complex is critically involved in the mediation of drug-induced circling in unilaterally 6OHDA lesioned rats and in particular the postural component.     

Unilateral Activation of Caudate Tyrosine Hydroxylase During Voluntary Circling Behavior

We trained rats to circle for a sucrose water reward and found that this behavior is associated with a unilateral increase in the activity of caudate tyrosine hydroxylase, the rate-limiting enzyme for dopamine synthesis. The increase in tyrosine hydroxylase activity occurs in caudate contralateral to the circling direction and the change is transient, increasing during the first 20 min of circling but then plateauing and falling as turning slows. Enhanced synthetic capacity is followed by increases in the contents of dopamine and dihydroxyphenylacetic acid in the contralateral caudate nucleus. These observations are the first evidence for specific activation of a neurotransmitter synthetic enzyme during voluntary motor behavior.     

Normal rats trained to circle show asymmetric caudate dopamine release

Caudate catecholamine release was monitored by bilateral $\text{in}$$\text{vivo}$ electrochemical electrodes in male Sprague-Dawley rats trained to circle for sucrose/water reward. Baseline release of dopamine was equal from both sides of caudate. When reinforced circling began, 33 ± 4 percent greater catechol release occured from the caudate contralateral to the circling direction. As turning subsided, differential release returned to basal levels. Further evidence that the catecholamine metabolism was affected by turning was obtained by direct measurement of caudate dopamine and DOPAC at selected time points. Concentration data showed relative increases in dopamine and DOPAC in the contralateral caudate. These data provide evidence that dopamine is released asymmetrically from caudate in unlesioned rats during voluntary behavior.     

Reverse tolerance to amphetamine of mice bearing unilateral striatal lesions: effect upon the circling response to apomorphine

When mice bearing unilateral lesions of the striatum receive weekly doses of amphetamine, their circling responses increase with successive doses, i.e., they become reverse tolerant (1). The present work was undertaken to ascertain whether presynaptic dopaminergic changes might underlie this phenomenon. This was approached by observing whether the response to a direct dopaminergic agent would be affected by the development of reverse tolerance to amphetamine. The circling responses of unilaterally electrothermally lesioned mice to apomorphine, 0.4 mg/kg s.c., increased significantly after four weekly 4 mg/kg s.c. doses of d-amphetamine. The responses to apomorphine of mice not exposed to amphetamine declined over the same interval. The conclusion drawn is that presynaptic effects are not likely to underlie the phenomenon of reverse tolerance.     

Association between the behavioral and neurochemical effects of amphetamine: Hemispheric asymmetry study

Effects of amphetamine on concentrations of dopamine, norepinephrine and serotonin in several monoamine-containing cell body and terminal regions were examined left and right separately in rats. Results suggest that amphetamine reduced the L-R asymmetry of most of these measures, and this effect is more significant in the cell body than in the terminal regions. Behaviorally, amphetamine also decreased L-R asymmetry of the spontaneous turning behavior in rats and this latter effect is most closely associated with the reductions of dopamine and norepinephrine asymmetries in the substantia nigra and reduction of norepinephrine asymmetry in the locus coeruleus.     

Sex and estrous cycle differences in the behavioral effects of high-strength static magnetic fields: role of ovarian steroids

Advances in magnetic resonance imaging are driving the development of higher-resolution machines equipped with high-strength static magnetic fields (MFs). The behavioral effects of high-strength MFs are largely uncharacterized, although in male rats, exposure to 7 T or above induces locomotor circling and leads to a conditioned taste avoidance (CTA) if paired with a novel taste. Here, the effects of MFs on male and female rats were compared to determine whether there are sex differences in behavioral responses and whether these can be explained by ovarian steroid status. Rats were given 10-min access to a novel saccharin solution and then restrained within a 14-T magnet for 30 min. Locomotor activity after exposure was scored for circling and rearing. CTA extinction was measured with two-bottle preference tests. In experiment 1, males were compared with females across the estrous cycle after a single MF exposure. Females circled more and acquired a more persistent CTA than males; circling was highest on the day of estrus. In experiment 2, the effects of three MF exposures were compared among intact rats, ovariectomized females, and ovariectomized females with steroid replacement. Compared with intact rats, ovariectomy increased circling; estrogen replacement blocked the increase. Males acquired a stronger initial CTA but extinguished faster than intact or ovariectomized females. Thus the locomotor circling induced by MF exposure was increased in females and modulated by ovarian steroids across the estrous cycle and by hormone replacement. Furthermore, female rats acquired a more persistent CTA than male rats, which was not dependent on estrous phase or endogenous ovarian steroids.     

Caffeine-phenylethylamine combinations mimic the amphetamine discriminative cue

Although caffeine-phenylethylamine combinations are widely available as over-the-counter medications or as "legal" stimulants, little information is available concerning their behavioral pharmacology or abuse potential. In the present study, rats were trained in a food-reward, two-lever operant drug discrimination paradigm to differentially respond after saline or 0.5 mg/kg amphetamine injections. Tests for generalization to the amphetamine cue indicated only modest amphetamine-lever responding at various doses of caffeine alone or at various doses of ephedrine/phenylpropanolamine (PPA) combinations, but complete generalization to the training cue was found with higher doses of the triple combination (caffeine, ephedrine, and PPA) or with caffeine-ephedrine or caffeine-PPA combinations. All drugs produced response rate decreases at higher doses. These data clearly indicate that certain "legal" stimulants mimic the amphetamine cue and suggest that caffeine may interact additively with phenylethylamines to produce the cue.     

Fluoxetine-induced attenuation of amphetamine self-administration in rats

Daily injections of fluoxetine (5.0 mg/kg i.p.) to rats trained to self-administer intravenous d-amphetamine produced marked decreases in drug intake on three successive days of treatment. After fluoxetine injections were stopped, the number of daily amphetamine self-injections was still significantly reduced for an additional 2 days. When trained amphetamine self-administration animals were placed in an apparatus which delivered i.v. saline with each lever press, increased self-injection is observed. Acute fluoxetine injection did not alter this response. However, if fluoxetine is given prior to amphetamine exposure for 1 day and animals are then tested for the saline response, lever pressing activity is significantly reduced. These data might suggest that 5-hydroxytryptaminergic neurons mediate some aversive or negative reinforcing property of amphetamine. If true, this finding could be exploited clinically in cases of human psychomotor stimulant addiction.     

The effect of alcoholization on the behavioral reactions of rats in an 8-arm radial maze

The influence of 20% alcohol consumption on training of low-active rats in 8-arm radial maze was studied. One group of animals was trained before and the other group after the alcoholization. All the animals acquired the conditioned reaction in the radial maze. However, the behavioral difference between the groups consisted in spatially-motor asymmetry. The rats trained before the alcohol consumption had less stereotyped behavior and more distinctly preferred to enter the maze arms at the angle of 45 degrees than the animals trained after the alcohol consumption. After the alcohol consumption, rats more frequently refused from behavioral task performance in comparison with the animals trained after the alcoholization. The influence of alcohol consumption of learning and memory in low-active rats is discussed.     

Training-induced bradycardia and intrinsic heart rate in rats

After 10 weeks of treadmill training, female Sprague-Dawley rats had developed a bradycardia at exercise on submaximal work loads. This bradycardia was also present after autonomic denervation and in isolated perfused heart preparations. The heart weight/body weight ratio was increased in these trained animals compared to untrained littermates. Sympathectomized, trained rats developed the same degree of cardiac hypertrophy, but their heart rate after denervation and in the isolated heart was the same as in sympathectomized, untrained rats. It is concluded that the bradycardia of trained and thereafter denervated animals seen in this and a previous investigation represents an adaptation within the heart itself, since it was present in the isolated heart. These results thus provide further evidence for a non-neural component in training-induced bradycardia. Since the trained sympathectomized rats had a cardiac hypertrophy but no reduction of intrinsic heart rate, it seems likely that the myocardial mass is of minor importance for the level of intrinsic heart rate.     

Training Rats to Voluntarily Dive Underwater: Investigations of the Mammalian Diving Response

Underwater submergence produces autonomic changes that are observed in virtually all diving animals. This reflexly-induced response consists of apnea, a parasympathetically-induced bradycardia and a sympathetically-induced alteration of vascular resistance that maintains blood flow to the heart, brain and exercising muscles. While many of the metabolic and cardiorespiratory aspects of the diving response have been studied in marine animals, investigations of the central integrative aspects of this brainstem reflex have been relatively lacking. Because the physiology and neuroanatomy of the rat are well characterized, the rat can be used to help ascertain the central pathways of the mammalian diving response. Detailed instructions are provided on how to train rats to swim and voluntarily dive underwater through a 5 m long Plexiglas maze. Considerations regarding tank design and procedure room requirements are also given. The behavioral training is conducted in such a way as to reduce the stressfulness that could otherwise be associated with forced underwater submergence, thus minimizing activation of central stress pathways. The training procedures are not technically difficult, but they can be time-consuming. Since behavioral training of animals can only provide a model to be used with other experimental techniques, examples of how voluntarily diving rats have been used in conjunction with other physiological and neuroanatomical research techniques, and how the basic training procedures may need to be modified to accommodate these techniques, are also provided. These experiments show that voluntarily diving rats exhibit the same cardiorespiratory changes typically seen in other diving animals. The ease with which rats can be trained to voluntarily dive underwater, and the already available data from rats collected in other neurophysiological studies, makes voluntarily diving rats a good behavioral model to be used in studies investigating the central aspects of the mammalian diving response.     

Effect of estrogens on apomorphine-induced circling behavior in the rat.

The effect of administration of estrogens parenterally for 1 week was tested on apomorphine-induced circling in a group of castrated female rats with a lesion of the left entopednucluar nucleus. We observed a significant decrease in the number of turns per minute in estrogen-treated animals as compared with controls. Our tentative explanation is that estrogens decrease the sensitivity of dopamine receptors in the striatum.     

The circling mouse (C57BL/6J-cir) has a 40-kilobase genomic deletion that includes the transmembrane inner ear (tmie) gene

The circling mouse (C57BL6-cir) shows deafness and circling behavior in homozygotes. The mutation is transmitted with 100% penetrance by an autosomal recessive gene on chromosome 9. In the present study, we characterized the circling mutation as a 40-kilobase deletion that includes the transmembrane inner ear (tmie) gene. The tmie gene was first identified because its mutation causes deafness and circling behavior in spinner mice. We suggest that the genomic deletion of circling mice is a different, but allelic, mutation to that of spinner mice. In addition, during general behavioral investigations for complementation tests of the 2 strains, we found that circling and spinner mice may differ in their behavioral responses to a new environment.     

Influence of training in the dark or light phase on physiologic and metabolic parameters of Wistar rats submitted to aerobic exercise

Light and dark phase training may influences rodents’ physiologic parameters because these animals have nocturnal habits. Thus, we verify the effects of the training in different photoperiods on metabolism and corporal composition of rats. Eighteen rats were divided into three groups – G1: non-trained; G2: trained in the light phase; G3: trained in the dark phase. Rats were allowed to swim for 60 min, five times per week during six weeks. Trained animals presented a smaller weight gain and fat percentage in carcass. Rats of G3 increased gastrocnemius relative weight. The adipocyte diameter of G3 rats was smaller than the other groups. The levels of the total cholesterol, low-density proteins, and triacylglycerols were decreased in animals of G2 while the glycemia was increased. Training in light phase provided more alterations in the blood biochemical profile while the training in the dark increased the gastrocnemius weight and decreased the diameter of the adipocyte.     

Dopamine and Serotonin Metabolism in Brain Sites Ipsi- and Contralateral to Direction of Conditioned Turning in Rats

Concentrations of dopamine, serotonin, and some of their metabolites were analyzed by means of HPLC in brain samples obtained from rats operantly conditioned to turn in circles to obtain water reinforcement. In experiment 1 using Wistar rats, no differences in the levels of transmitters or metabolites were detected between brain samples (frontal cortex, ventral striatum, dorsal striatum, septum, amygdala, substantia nigra) from the hemispheres located ipsi- and contralateral to the direction of turning. A higher dopamine metabolism (indicated by higher metabolite/transmitter ratios) in ventral striatum, dorsal striatum, and amygdala was found after 15 min than after 5 min of turning in both hemispheres. A higher dopamine metabolism was found in water-deprived rats compared to nondeprived rats independently of whether or not deprived rats were trained to turn for water reinforcement. In two additional experiments, no differences in dopamine metabolism were found between the ipsi- and contralateral striatum of Wistar rats after 25 min and Sprague-Dawley rats after 10 min of operantly conditioned turning. The present results confirm that dopamine metabolism can change with different behavioral or physiological states; they do not support the hypothesis that conditioned turning is correlated with asymmetrical changes in the metabolism of dopamine or serotonin in the brain.     

Operant conditioning of rat navigation using electrical stimulation for directional cues and rewards

Operant conditioning is often used to train a desired behavior in an animal. The contingency between a specific behavior and a reward is required for successful training. Here, we compared the effectiveness of two different mazes for training turning behaviors in response to directional cues in Sprague-Dawley rats. Forty-three rats were implanted with electrodes into the medial forebrain bundle and the left and right somatosensory cortices for reward and cues. Among them, thirteen rats discriminated between the left and right somatosensory stimulations to obtain rewards. They were trained to learn ipsilateral turning response to the stimulation of the left or right somatosensory cortex in either the T-maze (Group T) or the maze (Group W). Performance was measured by the navigation speed in the mazes. Performances of rats in Group T were enhanced faster than those in Group W. A significant correlation between performances during training and performance in final testing was observed in Group T starting with the fifth training session while such a correlation was not observed in Group W until the tenth training session. The training mazes did not however affect the performances in the final test. These results suggest that a simple maze is better than a complicated maze for training animals to learn directions and direct cortical stimulation can be used as a cue for direction training.     

A novel and neurotoxic tetrahydroisoquinoline derivative in vivo: formation of 1,3-dimethyl-1,2,3,4-tetrahydroisoquinoline, a condensation product of amphetamines, in brains of rats under chronic ethanol treatment

Repeated amphetamine administration to rats under chronic ethanol intoxication resulted in the formation of 1,3-dimethyl-1,2,3,4-tetrahydroisoquinoline (1,3-DiMeTIQ), a novel metabolite of amphetamines. 1,3-DiMeTIQ was quantified with a sensitive, specific assay using gas chromatography-mass spectrometry. It was not found in the brains of rats given repeated amphetamine administration but no ethanol. The chronic ethanol-intoxicated rats subjected to repeated amphetamine administration exhibited behavioral abnormalities, such as repeated convulsions and curving of the back. 1,3-DiMeTIQ contents were markedly higher in the brain or plasma of rats manifesting abnormal behavior in comparison with those in rats behaving normally. Thus, the 1,3-DiMeTIQ content in the rat brain seems to have some relationship with behavioral abnormalities. This study also confirmed that 1,3-DiMeTIQ can cross the blood-brain barrier in the rat. Intraperitoneal 1,3-DiMeTIQ injections to rats caused behavioral symptoms similar to those observed in rats with chronic ethanol intoxication and repeated amphetamine administration. The effect of toxic doses of 1,3-DiMeTIQ on dopaminergic and serotonergic metabolism in the whole rat brain was also investigated.