Publications

In adolescence, high levels of drinking over short episodes (binge drinking) is commonly seen in a proportion of the population. Because adolescence is an important neurodevelopmental period, the effects of binge drinking on brain and behavior has become a significant health concern. However, robust animal models of binge drinking in rats are still being developed and therefore further efforts are needed to optimize paradigms for inducing maximal self-administration of alcohol. In the present experiment, 1-h limited-access self-administration sessions were instituted to model excessive drinking behavior in adolescent and adult Wistar rats. In addition to age, the involvement of sex and phase within the light/dark cycle (i.e., drinking in the light or dark) on sweetened 5% ethanol intake were also evaluated over 14 limited-access sessions using a between-groups design. The results of the experiment showed that over 14 limited-access sessions, sweetened ethanol intake (g/kg) was significantly higher for adolescents compared to adults. Females were also found to drink more sweetened ethanol as compared to males. Additionally, drinking in the light produced a robust increase in sweetened ethanol intake (g/kg) in adolescents, as compared to adults during the light phase and as compared to both adolescent and adult rats drinking in the dark. Furthermore, the increase in ethanol consumption observed in adolescents drinking during the light phase was dissociable from sweetened solution intake patterns. These results identify that age, sex, and time of day all significantly influence consumption of sweetened ethanol in Wistar rats. Knowledge of these parameters should be useful for future experiments attempting to evaluate the effects of self-administered ethanol exposure in adult and adolescent rats.

The purpose of this study was to test the hypothesis that blockade of alpha1-adrenergic receptors may suppress the excessive ethanol consumption associated with acute withdrawal in ethanol-dependent rats. Following the acquisition and stabilization of operant ethanol self-administration in male Wistar rats, dependence was induced in half the animals by subjecting them to a 4-week intermittent vapor exposure period in which animals were exposed to ethanol vapor for 14h/day. Subsequent to dependence induction, the effect of alpha1-noradrenergic receptor antagonist prazosin (0.0, 0.25, 0.5, 1, 1.5, and 2.0mg/kg IP) was tested on operant responding for ethanol in vapor-exposed and control rats during acute withdrawal. In ethanol-dependent animals, prazosin significantly suppressed responding at the 1.5 and 2.0mg/kg doses, whereas only the 2.0mg/kg dose was effective in nondependent animals, identifying an increase in the sensitivity to prazosin in dependent animals. Conversely, at the lowest dose tested (0.25mg/kg), prazosin increased responding in nondependent animals, which is consistent with the effect of anxiolytics on ethanol self-administration in nondependent animals. None of the doses tested reliably affected concurrent water self-administration. These results suggest the involvement of the noradrenergic system in the excessive alcohol drinking seen during acute withdrawal in ethanol-dependent rats.

BACKGROUND: Despite evidence showing persistent changes in N-methyl-D-aspartate (NMDA)-receptor function following ethanol (EtOH) exposure, the contribution of NMDA systems to the long-term neurophysiological consequences of adolescent EtOH exposure is unclear. The aims of this study were the following: (1) to determine whether adolescent EtOH exposure produces neurophysiological changes after a prolonged withdrawal period in adult rats and (2) to assess protracted alterations in neurophysiological responses to the NMDA antagonist MK-801 in adult rats exposed to EtOH during adolescence.

METHODS: Adolescent male Wistar rats were exposed to EtOH vapor for 12 h/d for 5 weeks. The effects of MK-801 (0.0 to 0.1 mg/kg, intraperitoneally) on the electroencephalogram (EEG) and auditory event-related potentials (ERPs) were assessed after 8 weeks of abstinence from EtOH.

RESULTS: Experiments in aim 1 revealed that adolescent EtOH exposure reduced EEG variability in the frontal cortex in the 4 to 6 Hz band but had no effect on cortical and hippocampal EEG power and ERPs. Experiments in aim 2 showed that MK-801 significantly reduced EEG power in the parietal cortex (4 to 6 Hz, 6 to 8 Hz, 8 to 16 Hz, 16 to 32 Hz) and hippocampus (16 to 32 Hz) and EEG variability in the parietal cortex (6 to 8 Hz, 16 to 32 Hz) following adolescent EtOH exposure. MK-801 produced a significant decrease in hippocampal EEG variability (4 to 6 Hz, 8 to 16 Hz, 16 to 32 Hz) in control, but not in EtOH-exposed rats. MK-801 reduced frontal P1 ERP amplitude and latency in response to the rare tone in EtOH-exposed rats compared to controls. In contrast, MK-801 significantly reduced P3 ERP amplitude and latency in control, but not in EtOH-exposed rats.

CONCLUSIONS: The effects of MK-801 on hippocampal EEG variability and P3 ERP amplitude and latency are significantly attenuated after a prolonged withdrawal period following adolescent EtOH exposure. However, the inhibitory effects of MK-801 on cortical and hippocampal EEG power were enhanced in rats exposed to EtOH during adolescence. Taken together, these data suggest protracted changes in NMDA systems following adolescent EtOH exposure.

Although adolescent ethanol (EtOH) exposure has been associated with long-lasting changes in brain function, little is known as to whether EtOH exposure during adolescence alters sleep and cortical arousal. This study examined protracted alterations in sleep in adult rats exposed to EtOH during adolescence. Adolescent male Wistar rats were exposed to EtOH vapor for 12 h/day for 5 weeks. Cortical electroencephalograms were obtained during 4-h recording sessions after 5 weeks of withdrawal from EtOH. Adolescent EtOH exposure significantly reduced the mean duration of slow-wave sleep (SWS) episodes and the total amount of time spent in SWS in EtOH-exposed rats, compared to controls. Spectral analysis revealed that adolescent EtOH exposure significantly increased cortical peak frequencies during SWS in the 2-4, 4-6, and 6-8 Hz bands. Taken together, our findings suggest that chronic EtOH exposure in adolescent rats reduces measures of SWS, an effect also seen as part of normal aging. Although the cellular and molecular mechanisms mediating the consequences of EtOH exposure on the aging process are not known, the similarities between adolescent EtOH exposure and aging merits further investigation.

The rewarding properties of centrally administered ethanol (EtOH) were examined using a conditioned place preference (CPP) test. Male rats subjected to bilateral intracerebroventricular (icv) infusions of EtOH (0-240 nmol) produced a dose-dependent preference for the drug-paired environment that was potentiated by concurrent intravenous (iv) administration of heroin (0.025 mg/kg). The role of mesolimbic dopamine (DA) pathways in the development of EtOH reward was then examined by challenging EtOH-treated rats with bilateral intra-accumbens shell applications of a DA receptor antagonist. Fluphenazine (10 or 50 microg/side), infused immediately prior to daily place conditioning trials, was found to reliably attenuate the development of CPPs produced by icv EtOH administration. When fluphenazine was administered into the nucleus accumbens shell prior to the final test trial only (i.e., in already conditioned rats), intra-accumbens shell DA receptor blockade was found to prevent the expression of CPPs produced by icv EtOH. In summary, rats form reliable learned preferences for EtOH-paired locations (CPPs) that are potentiated by iv heroin and whose acquisition and expression rely on intact DA functionality within the nucleus accumbens.

Alcoholism is a complex disorder influenced by interactions between genetic and environmental risk factors. This study examined the influence of isolate housing on ethanol intake in alcohol-preferring (P) and non-alcohol-preferring (NP) rats. Rats were isolate-housed or pair-housed for 8 weeks when between 45 and 96 days old. Ethanol drinking was assessed using a 24-hr preference test (10% ethanol vs. water) and 20-min limited access tests. A behavioral test battery was used to assess anxiety-like, depressive-like, acoustic startle, and motor behavior. Isolate housing increased home cage drinking in both lines and increased limited access drinking selectively in P rats. Isolation also reduced swim test immobility and prepulse inhibition in P rats and increased locomotor stereotypies in NP rats. Taken together, these data demonstrate that LinexEnvironment interactions influence the effects of isolation. Furthermore, isolation selectively increased ethanol intake in high drinking P rats. This effect was not correlated with changes in other behaviors. Selective enhancement of limited access ethanol drinking in P rats may represent a model whereby genetic liability to excessive drinking is enhanced by specific environmental exposures.

BACKGROUND: Gamma-aminobutyric acid-B (GABA(B)) receptor agonists have been shown to suppress operant self-administration of ethanol in nondependent rats. However, little work has focused on the effects of GABA(B) receptor agonists on self-administration of ethanol in dependent animals.

METHODS: In the present experiment, the GABA(B) receptor agonist baclofen was tested for the ability to modulate both fixed- (FR) and progressive-ratio (PR) responding for ethanol in rats while nondependent and subsequently after ethanol dependence induction. Following the acquisition and stabilization of baseline operant ethanol self-administration and after dependence induction, baclofen [0.0, 0.5, 1, 2, and 4 mg/kg, intraperitoneal (IP)] was tested on FR-1 responding for ethanol. The ability of baclofen (2.0 mg/kg) to affect responding under a PR schedule of reinforcement was also evaluated. Dependence was induced in the animals by subjecting them to a 1-month intermittent vapor-exposure period in which animals were exposed to ethanol vapor for 14 h/d. Following the 1-month period, the vapor-exposed animals resumed FR-1 and PR baclofen drug testing (doses as described above) in the operant chambers at a time point corresponding to the animals being 6 hours into withdrawal (i.e., 6 hours after the ethanol vapor had been discontinued for that day).

RESULTS: Baclofen (0.0, 0.5, 1, 2, and 4 mg/kg, IP) dose-dependently decreased ethanol self-administration in both nondependent and dependent rats on a FR schedule of reinforcement. However, the dose of baclofen that significantly reduced responding for ethanol was shifted to the left in the ethanol vapor-exposed animals, indicating an increased sensitivity to baclofen in animals that were chronically exposed to ethanol. When tested using a PR schedule of reinforcement, there was a significant increase in the breakpoint for the vapor-exposed animals (i.e., the animals were willing to work more in a dependent state). Baclofen (2.0 mg/kg, IP) suppressed intake for both nondependent and dependent animals.

CONCLUSIONS: Ethanol dependence produced increased self-administration of ethanol as reflected in increased ethanol intake and increased responding on a PR schedule of reinforcement. As baclofen suppressed ethanol self-administration and showed evidence of increased potency in dependent animals, the present experiment suggests that the GABA(B) receptor could be a potential pharmacotherapeutic target for the treatment of chronic alcoholism.

The present experiment was designed to replicate and extend previous results of an opiate+benzodiazepine interaction in which peripherally administered alprazolam was observed to modulate behavior resulting from intravenous injections of heroin. As a first step in determining the role of central sites in this drug interaction, changes in drug reward (measured by conditioned place preference; CPP) were assessed in rats given systemic administration of alprazolam coupled with intracranially infused heroin (into the ventral tegmental area; VTA). Sprague-Dawley rats were implanted with guide cannula targeting the VTA, after which a heroin-induced CPP dose-response curve was determined (2.5-40 ng administered bilaterally in 0.5 microl/side). In other animals, intra-VTA heroin-induced place preferences were challenged with systemically applied alprazolam (0.125 mg/kg i.p.). The data confirm that rats dose-dependently develop reliable place preferences for a distinct environment paired with bilateral VTA-infusions of heroin. Additionally, when a non-rewarding dose of alprazolam was combined with a non-rewarding bilateral intra-VTA heroin dose (5 ng), a significant CPP was produced. These data extend earlier results by demonstrating that a systemically applied benzodiazepine can enhance the rewarding effects produced by central opiate administration. The results suggest that the VTA might be a site where this opiate+benzodiazepine interaction occurs.

Case studies reveal that opiate addicts often self-medicate with benzodiazepine (BDZ) tranquilizers prior to taking their opiate. Our laboratory has previously utilized the conditioned place preference paradigm to confirm that BDZs can augment the affective response to heroin in laboratory animals. The combination of alprazolam and varying doses of intravenous heroin resulted in a leftward shift of the heroin dose-response curve. The present experiment was devised to extend the previous findings by examining the ability of varying alprazolam doses (0.125, 0.25, or 0.5 mg/kg ip) to potentiate the reward of a single challenge dose of heroin (0.025 mg/kg iv). The results demonstrate that a nonrewarding dose of alprazolam (0.125 mg/kg) and intravenous heroin can interact to produce reliable place preferences. The data thereby support prior work from our laboratory regarding the synergistic actions of BDZs and opiates.