• Energy Research

ABSTRACTPharmacokinetic studies concerningd‐penicillamine (an acetaldehyde sequestering agent) are scarce and have not evaluated the influence of chronic ethanol consumption and age on its disposition. Since recent preclinical studies proposed‐penicillamine as a promising treatment for alcohol relapse, the main aim of the present work was to evaluate the influence of these two factors ond‐penicillamine disposition in order to guide future clinical studies on the anti‐relapse efficacy of this drug in alcoholism. Additionally, the effect of the administered dose was also evaluated. To this end, three studies were carried out. Study 1 assessed the influence of dose ond‐penicillamine disposition, whereas studies 2 and 3 evaluated, respectively, the influence of chronic alcohol consumption and age. Rapid intravenous administrations of 2, 10 and 30 mg/kg ofd‐penicillamine were performed using young or adult ethanol‐naïve rats or adult ethanol‐experienced (subjected to a long‐term ethanol self‐administration protocol) rats. Pharmacokinetic parameters were derived from the biexponential model. Statistical analysis ofCL, normalizedAUC0∞,V1andk10revealed that disposition, in the range plasma concentrations assayed, is non‐linear both in young ethanol‐naïve and in adult ethanol‐experienced rats. Notably, no significant changes int1/2were detected. Chronic ethanol consumption significantly reducedCLvalues by 35% without affectingt1/2.d‐Penicillamine disposition was equivalent in young and adult animals. In conclusion, although DP pharmacokinetics is non‐linear, the lack of significant alterations of thet1/2would potentially simplify the clinical use of this drug. Chronic consumption of ethanol also altersd‐penicillamine disposition but, again, does not modifyt1/2. Copyright © 2014 John Wiley & Sons, Ltd.

AbstractWhile most individuals with access to alcohol drink it recreationally, about 5 % lose control over their intake and progressively develop an alcohol use disorder (AUD), characterised by compulsive alcohol drinking accompanied by decreased interest in alternative sources of reinforcement. The neural and molecular mechanisms underlying the vulnerability to switch from controlled to compulsive alcohol intake have not been fully characterized, so limiting the development of new treatments for AUD. It has recently been shown that rats having reduced levels of expression of the gamma-aminobutyric acid (GABA) transporter, GAT-3, in the amygdala tend to persist in seeking and drinking alcohol even when adulterated with quinine, suggesting that pharmacological interventions aimed at restoring GABA homeostasis in these individuals may provide a targeted treatment to limit compulsive alcohol drinking. Here, we tested the hypothesis that the GABABreceptor agonist baclofen, which decreases GABA release, specifically decreases compulsive alcohol drinking in vulnerable individuals. In a large cohort of Sprague-Dawley rats allowed to drink alcohol under an intermittent two-bottle choice procedure, a cluster of individuals was identified that persisted in drinking alcohol despite adulteration or the availability of an alternative ingestive reinforcer, saccharin. In these rats, that were characterised by decreased GAT-3 mRNA levels in the central amygdala, acute baclofen administration (1.5 mg/kg, intraperitoneal) resulted in a decrease in compulsive drinking. These results indicate that low GAT-3 mRNA levels in the central amygdala represent an endophenotype of AUD and that the associated compulsive alcohol drinking characteristic is sensitive to baclofen.

Previous experiments in our laboratory have shown that D-penicillamine (DP) (acetaldehyde sequestering agent) is able to block the increase in ethanol consumption observed after a period of imposed deprivation (the so-called alcohol deprivation effect (ADE)), using a non-operant paradigm in Wistar rats.This study is aimed at investigating the robustness and reproducibility of our previous data using an operant paradigm, which is considered to be a valid and reliable model of human drug consumption, and the ADE, probably the most often used measure of ethanol relapse-drinking behaviour in rats.Male Wistar rats with a limited (30-min sessions), intermittent and extended background of ethanol operant self-administration were used. In order to evaluate the efficacy of several DP doses (6.25, 12.5 and 25 mg/kg i.p.) in preventing alcohol relapse, we set up a protocol based on the ADE. In a separate experiment, the effect of DP on spontaneous motor activity of rats was also tested.A significant ADE was observed in animals treated with saline. DP treatment blocked the increase in ethanol responses following the imposed abstinence period. The higher dose suppressed the ADE and provoked a significant reduction in ethanol consumption with respect to the baseline conditions. Basal motor activity was not altered after DP treatment.Our positive results with DP, using two different paradigms that evaluate relapse of ethanol drinking, will help to increase the positive predictive value of pre-clinical experiments and offer a solid base to inspire human studies with DP.

Recent electrophysiological evidence suggests that ethanol simultaneously exerts opposite effects on the activity of dopamine (DA) neurons in the ventral tegmental area (VTA) through two parallel mechanisms, one promoting and the other reducing the GABA release onto VTA DA neurons. Here we explore the possible behavioural implications of these findings by investigating the role displayed by acetaldehyde (the main metabolite of ethanol) and the non-metabolized fraction of ethanol in motor activity of rats. We analyse the appearance of motor activation or depression after intra-VTA administration of ethanol in rats subjected to different pharmacological pre-treatments designed to preferentially test either the effects of acetaldehyde or the non-metabolized ethanol. Motor activity was evaluated after intra-VTA administration of 35 nmol of ethanol, an apparently ineffective dose that does not modify the motor activity of animals. Pharmacological pre-treatments were used in order to either increase (cyanamide, 10 mg/kg, ip) or decrease (D-penicillamine, 50 mg/kg, ip and sodium azide, 7 mg/kg, ip) acetaldehyde levels in the VTA. Pre-treatments aimed to augment acetaldehyde, increased motor activity of rats. Otherwise, pre-treatments intended to decrease local acetaldehyde levels evoked significant reductions in motor activity that were prevented by the local blockade (bicuculline, 17.5 pmol) of the GABAA receptors. Our findings suggest that the brain-generated acetaldehyde is involved in the stimulant effects of ethanol, whereas the non-biotransformed fraction of ethanol, acting through the GABAA receptors, would account for the depressant effects. The present behavioural findings suggest that ethanol dually modulates the activity of DA neurons.

A recent hypothesis, based on electrophysiological and behavioural findings, suggests that ethanol simultaneously exerts opposed effects on the activity of dopamine (DA) neurons in the ventral tegmental area (VTA) through two parallel mechanisms, one promoting and the other reducing the GABA release onto VTA DA neurons. In this sense, the activating effects are mediated by salsolinol, a metabolite of ethanol, acting on the μ-opioid receptors (MORs) located in VTA GABA neurons. The inhibitory effects are, however, triggered by the non-metabolized fraction of ethanol which would cause the GABAAreceptors-mediated inhibition of VTA DA neurons. Since both trends tend to offset each other, only the use of appropriate pharmacological tools allows analysis of this phenomenon in depth. Herein, we present new behavioural findings supporting this hypothesis. Motor activity was evaluated in rats after intra-VTA administration of ethanol 35 nmol, an apparently ineffective dose, 24 h after the irreversible blockade of MORs in the VTA with β-FNA. Our results showed that this pre-treatment turned the initially ineffective ethanol dose into a depressant one, confirming that the activating effect of ethanol can be selectively suppressed without affecting the depressant effects mediated by the non-biotransformed fraction of ethanol.

The possible involvement of salsolinol (Sal), an endogenous condensation product of ACD (the first metabolite of ethanol) and dopamine, in the neurochemical basis underlying ethanol action has been repeatedly suggested although it has not been unequivocally established, still being a controversial matter of debate. The main goal of this review is to evaluate the presumed contribution of Sal to ethanol effects summarizing the reported data since the discovery in the 1970s of Sal formation in vitro during ethanol metabolism until the more recent studies characterizing its behavioral and neurochemical effects. Towards this end, we first analyze the production and detection of Sal, in different brain areas, in basal conditions and after alcohol consumption, highlighting its presence in regions especially relevant in regulating ethanol-drinking behaviour and the importance of the newly developed methods to differentiate both enantiomers of Sal which could help to explain some previous negative findings. Afterwards, we review the behavioral and neurochemical studies. Finally, we present and discuss the previous and current enunciated mechanisms of action of Sal in the CNS.

Nowadays, very few approved anti-relapse treatments for alcoholism exist, and their overall efficacy can be considered moderate. An exciting rationale drug development opportunity for the treatment of chronic alcoholism is the use of acetaldehyde sequestering agents. Although these compounds are able to attenuate or prevent most of the behavioral and neurochemical effects of ethanol, the efficacy of acetaldehyde sequestration, by using agents such as D-penicillamine (DP), in relapse prevention has not been studied yet.The aim of this study was to analyze the effects of DP treatment on the alcohol deprivation effect (ADE) in long-term ethanol-experienced rats as a model of relapse behavior and measure drug plasma and brain levels during treatment.Rats were subcutaneously implanted with mini-osmotic pumps delivering 0, 0.25, or 1 mg/h of DP during 1 week. The efficacy to prevent ADE was determined. DP plasma and brain levels achieved during its subcutaneous administration were measured. In a second experiment, animals received bilateral infusions of 0 or 1.5 μg/h of DP directly into pVTA, and the appearance of ADE was evaluated.One milligram per hour, but not 0.25 mg/h, DP infusion prevented ADE and reduced the total ethanol preference in animals. DP plasma concentrations associated with ADE suppression were around 3-4 μg/ml, and brain DP levels in these conditions were about 2-3 % of those found in plasma. Intra-pVTA DP administration also suppressed ADE.DP is able to prevent alcohol-relapse-like drinking in rats suggesting that this drug may be a useful new tool in the management of relapse in alcohol-dependent patients.