Jeffrey N. Carlson

Effects and aftereffects of ibogaine on morphine self-administration in rats

Ibogaine, a naturally occurring alkaloid, has been claimed to be effective in treating addition to opiate and stimulant drugs. As a preclinical test of this claim, the present study sought to determine if ibogaine would reduce the intravenous self-administration of morphine in rats. Ibogaine dose dependently (2.5-80 mg/kg) decreased morphine intake in the hour after ibogaine treatment (acute effect) and, to a lesser extent, a day later (aftereffect); while the acute effect could be attributed to abnormal motor behavior (whole body tremors), the aftereffect occurred at a time when ibogaine should have been entirely eliminated from the body and when there was no obvious indication of ibogaine exposure. In some rats, there was a persistent decrease in morphine intake for several days or weeks after a single injection of ibogaine; other rats began to show such persistent changes only after two or three weekly injections whereas a few rats were apparently resistant to prolonged aftereffects. Aftereffects could not be attributed to a conditioned aversion. Although ibogaine also depressed responding acutely in rats trained to bar-press for water, there was no evidence of any aftereffect a day or more later; the interaction between ibogaine and morphine reinforcement was therefore somewhat specific. Further studies are needed to characterize the nature of the ibogaine-morphine interaction as well as to determine if ibogaine also affects the self-administration of other drugs.

Effects of iboga alkaloids on morphine and cocaine self-administration in rats: relationship to tremorigenic effects and to effects on dopamine release in nucleus accumbens and striatum

Ibogaine, a naturally occurring alkaloid, has been claimed to be effective in treating addiction to opioid and stimulant drugs and has been reported to decrease morphine and cocaine self-administration in rats. The present study sought to determine if other iboga alkaloids, as well as the chemically related harmala alkaloid harmaline, would also reduce the intravenous self-administration of morphine and cocaine in rats. Because both ibogaine and harmaline induce tremors, an effect that may be causally related to neurotoxicity in the cerebellar vermis, the temorigenic activities of the other iboga alkaloids were assessed. Lastly, in view of the involvement of the dopaminergic mesolimbic system in the actions of drugs of abuse, the effects of some of the iboga alkaloids on extracellular levels of dopamine and its metabolites in the nucleus accumbens and striatum were determined. All of the tested alkaloids (i.e., ibogaine, tabernanthine, R- and S-coronaridine, R- and S-ibogamine, desethylcoronaridine, and harmaline) dose-dependently (2.5-80 mg/kg) decreased morphine and cocaine intake in the hour after treatment; decreases in morphine and cocaine intake intake were also apparent the day after administration of some but not all of these alkaloids (i.e., ibogaine, tabernanthine, desethylcoronaridine, and the R-isomers of coronaridine and ibogamine). In some rats, there were persistent decreases in morphine or cocaine intake for several days after a single injection or after two or three weekly injections of one or another of these alkaloids; R-ibogamine produced such effects more consistently than any of the other alkaloids.(ABSTRACT TRUNCATED AT 250 WORDS)

Side and region dependent changes in dopamine activation with various durations of restraint stress

Exposure to various mild stressors has been shown to result in the activation of dopamine containing neuronal systems projecting to the medial prefrontal cortex (PFC), to a lesser extent the nucleus accumbens septi/olfactory tubercle (NAS) and, in a few studies, the striatum. It has also been shown that dopamine (DA) systems on different sides of the PFC are successively activated as stressors are prolonged. We have therefore examined the effects of variation in the duration of a restraint stressor (15, 30 and 60 min) on region and side dependent alterations in DA utilization in the PFC, NAS and striatum. Increases in the concentrations of the DA metabolites 3,4-dihydroxyphenylacetic acid (DOPAC) and/or homovanillic acid (HVA) or in their ratios with DA were seen in all regions examined with the largest effects occurring in the PFC and lesser effects in the NAS and striatum. In each region, the magnitude of these effects varied with time of restraint exposure. In the PFC, lateralized alterations in HVA and DA were seen over time with effects progressing from a left greater than right involvement at 15 min to a right greater than left involvement at 60 min. These results are discussed with reference to side and region dependent effects on brain DA systems as stressors are prolonged and the implications they may have for lateralized regional brain activity associated with stressor precipitated psychiatric disease.

Selective enhancement of dopamine utilization in the rat prefrontal cortex by food deprivation.

Previous studies have indicated that food deprivation exerts various effects on brain neurotransmitters and that mild stress causes a selective enhancement of dopamine activity in the rat medial prefrontal cortex. In the present study it was found that in rats 24 h of food deprivation produced an increase in levels of the dopamine metabolite 3,4-dihydroxyphenylacetic acid in the medial prefrontal cortex but not in the nucleus accumbens or caudate-putamen. This selective increase in mesocortical dopamine activity is comparable to that found with mild footshock stress exposure and indicates that food deprivation may function as a stressor.

Left and right 6-hydroxydopamine lesions of the medial prefrontal cortex differentially alter subcortical dopamine utilization and the behavioral response to stress

The effects of left and right prefrontal cortical dopamine (DA) depletion on circling behavior, stress-escape behavior and subcortical DA function were examined in rats exhibiting left or right turning biases. 6-Hydroxydopamine lesions of the medial prefrontal cortex (PFC) caused significant DA depletions when assessed in separate studies at 3 days and 3-4 weeks. However, depletions were smaller at 3-4 weeks and there was a significant increase in DA concentration on the left side following right lesions. Significant increases in striatal DA content were observed following lesions of either side at 3-4 weeks, but not at 3 days. No changes in DA concentration were observed in the nucleus accumbens septi (NAS). Left circling rats significantly increased their circling behavior following right sided lesions and showed disrupted footshock-escape behavior following left sided lesions. Performance of the footshock-escape task exerted an effect on striatal and NAS DA utilization as indicated by the ratio of 3,4-dihydroxyphenylacetic acid (DOPAC) to DA. The effects of footshock on NAS DA utilization were greater following left PFC lesions as compared to the right lesion and sham conditions. These lesion effects were also greater in left- than in right-turning animals. The data indicate that an intrinsic asymmetry in brain DA systems interacts with left and right PFC lesions to differentially determine subcortical DA function and behaviors that it subserves.

Sedative and anxiolytic effects of zopiclone's enantiomers and metabolite

We evaluated racemic zopiclone, its (S)- and (R)-enantiomers and a metabolite, (S)-desmethylzopiclone, for their actions on locomotor activity, rotarod performance, the elevated plus maze and the Vogel conflict test of anxiety, and electroconvulsive shock-induced seizures duration. Zopiclone and its (R)- and (S)-enantiomers reduced locomotor activity, and zopiclone and its (S)-enantiomer disrupted rotarod performance at 10 mg/kg. (S)-desmethylzopiclone did not alter these measures at doses of less than 200 mg/kg. (S)-desmethylzopiclone altered plus maze performance at the lowest dose of all the zopiclone derivatives tested, caused a dose-related effect on the Vogel conflict test and caused a dose-related reduction of electroconvulsive shock-induced seizure durations. The data indicate that (S)-desmethylzopiclone can bring about an anxiolytic effect without a substantial degree of central nervous system depression, and suggest that the agent may be particularly useful clinically in the treatment of anxiety.

Food deprivation alters dopamine utilization in the rat prefrontal cortex and asymmetrically alters amphetamine-induced rotational behavior

The effects of 24 and 48 h of food deprivation on changes in the activity of dopaminergic (DAergic) neurons and D-amphetamine-induced rotational behavior were studied in male and female Long-Evans rats. Food deprivation selectively altered 3,4-dihydroxyphenylacetic acid (DOPAC) in the medial prefrontal cortex (PFC) but not in the nucleus accumbens or striatum: PFC DOPAC was significantly increased and decreased bilaterally after 24 and 48 h of food deprivation, respectively. Left greater than right hemispheric asymmetries were seen for DOPAC and DOPAC/DA in the control animals. In a separate experiment, 24 h of food deprivation enhanced right rotational behavior, while 48 h significantly increased left rotational behavior. The results are discussed in terms of food deprivations effects on mesocortical DAergic neurons, previous work on cortical modulation of striatal function and how these effects on rotational behavior may be determined by brain asymmetry.

Differences in spontaneous and amphetamine-induced rotational behavior, and in sensitization to amphetamine, among Sprague-Dawley derived rats from different sources

Nocturnal rotational behavior was found to vary severalfold among Sprague-Dawley derived rats obtained from seven different breeders; net rotations per night (18 hours) varied from 5.0 to 31.0 in males and from 6.2 to 42.4 in females. Rats from three sources were tested twice (a week between tests) for rotation induced by d-amphetamine. Rats from two sources showed evidence of sensitization to d-amphetamine, there being significantly greater rotation in response to the second dose than in response to the first dose; the d-amphetamine-induced rotational behavior of rats from the third source did not significantly change from one week to the next. However, the latter rats had a greater initial response to the first dose of d-amphetamine than did rats from the other two breeders. Further analysis revealed that, among rats from all three breeders, rats rotating weakly in response to d-amphetamine on the first test tended to rotate more on the second test whereas rats rotating strongly in response to d-amphetamine on the first test tended to rotate less on the second test. This relationship was found to apply to previously collected data as well and was discussed with reference to a proposed mechanism involving asymmetry in sensitization to d-amphetamine-induced release of striatal dopamine. Interindividual differences among seemingly similar experimental subjects appear to contribute importantly to reported differences in results among laboratories.

Enhanced cocaine self-administration in adult rats prenatally exposed to cocaine

Rats that had been prenatally exposed to either cocaine or saline were examined as adults using continuous reinforcement (FR1) cocaine self-administration. Initially these rats were water-deprived and trained to bar-press for water; no differences across prenatal treatments were observed during this training phase. After complete rehydration and implantation of an intravenous cannula into the external jugular vein, animals were introduced to cocaine self-administration with a nocturnal and subsequent 3 h exposure. During daily test sessions rats were allowed to self-administer cocaine for 1 h/day. Prenatal cocaine exposure led to a marked and stable enhancement of the rates of self-administration for up to 13 days, the longest time point examined. These results suggest that prenatal cocaine exposure can alter cocaine reinforcement in adult animals.

Neurochemical predisposition to self-administer morphine in rats

Using in vivo microdialysis, this study attempted to determine whether a neurochemical predisposition to self-administer morphine could be identified. Extracellular levels of dopamine and its metabolites were measured bilaterally in the mesocorticolimbic and nigrostriatal systems of naive rats that were subsequently trained to self-administer morphine intravenously. There were several significant relationships between dopamine metabolite 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) levels and rates of morphine self-administration during both acquisition and asymptotic phases of testing. DOPAC and HVA levels in the striatum were inversely correlated with self-administration rates during the asymptotic phase whereas hemispheric asymmetries in striatal metabolite levels were inversely correlated with self-administration during the acquisition phase. DOPAC and HVA levels in in the right but not in the left side of the medial prefrontal cortex were positively correlated with self-administration rates during the acquisition phase; right/left asymmetries in cortical metabolite levels were also correlated with acquisition rates. There were no significant relationships between neurochemical indices and rates of bar-pressing for water. These results suggest that the normal variability in drug seeking behavior is at least in part attributable to individual differences in the organization and activity of brain dopamine systems. Furthermore, different mechanisms appear to be responsible for the initiation and maintenance of morphine intake: DA release in the nucleus accumbens appears to be a critical component of both mechanisms; DA release in the striatum appears to modulate maintenance and, in relationship to striatal lateralization, modulate initiation; DA release in the right but not in the left medial prefrontal cortex appears to be an important predictor of initiation.