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EFFECTS OF WITHDRAWAL FROM CHRONIC ETHANOL TREATMENT ON SPONTANEOUS FIRING IN RAT VENTRAL TEGMENTAL AREA SLICES
British Journal of Pharmacology
... The amplitude of GABA A -mediated IPSP/Cs as well as the frequency and amplitude of spontaneously occurring mIPSCs were found to be robustly enhanced, suggesting enhanced basal GABAergic transmission . Significant reductions in DA D2 receptors, in DA release and in the firing rate of dopaminergic neurons were revealed as well as changes in their firing pattern (Molleman & Little, 1995;Volkow et al., 2002). This could contribute to the dysphoric effects of alcohol withdrawal. ...
There is no specialized alcohol addiction area in the brain; rather, alcohol acts on a wide range of excitatory and inhibitory
nervous networks to modulate neurotransmitters actions by binding with and altering the function of specific proteins. With no hematoencephalic
barrier for alcohol, its actions are strongly related to the amount of intake. Heavy alcohol intake is associated with both
structural and functional changes in the central nervous system with long-term neuronal adaptive changes contributing to the phenomena
of tolerance and withdrawal. The effects of alcohol on the function of neuronal networks are heterogeneous. Because ethanol affects
neural activity in some brain sites but is without effect in others, its actions are analyzed in terms of integrated connectivities in the
functional circuitry of neuronal networks, which are of particular interest because of the cognitive interactions discussed in the manuscripts
contributing to this review. Recent molecular data are reviewed as a support for the other contributions dealing with cognitive
disturbances related to alcohol acute and addicted consumption.
The present study investigated the activity of neurons in the mesolimbic dopamine system after the end of the acute phase of the behavioural signs of ethanol withdrawal in mice. This was designed to provide a comparison with earlier behavioural studies, in which greater development of sensitisation to amphetamine and cocaine, but no change in the initial effects of these compounds, or in the behaviour in the absence of drug treatment, was seen when repeated injection of these psychostimulants were given after chronic ethanol consumption. In the present study, single unit recordings were made from dopamine-sensitive neurons in the ventral tegmental area in perfused midbrain slices prepared 24 h after cessation of chronic ethanol consumption. Profound decreases in firing of the ventral tegmental area (VTA) neurons were seen in slices prepared after the ethanol treatment. Firing rates increased after application of N-methyl-dl-aspartate, but still remained lower and more variable after the ethanol treatment. Application of dopamine or amphetamine, following stimulation of firing with a low concentration of N-methyl-dl-aspartate, also resulted in lower firing rates in slices from ethanol-treated mice. No changes were seen in release of tritiated dopamine, in response to applied KCl or amphetamine, from slices of striatum or cerebral cortex, prepared 24 h after cessation of the chronic ethanol consumption, compared with control values. The results demonstrate that very substantial decreases in firing rate, and in the number of active cells, occur in VTA neurons at a time when withdrawal hyperexcitability was no longer apparent and overt changes in behaviour were not seen.
This review describes the effects of ethanol on the components of neuronal transmission and the relationship of such effects to the behavioural actions of ethanol. The concentrations of ethanol with acute actions on voltage-sensitive ion channels are first described, then the actions of ethanol on ligand-gated ion channels, including those controlled by cholinergic receptors, 5-hydroxytryptamine receptors, the various excitatory amino acid receptors, and gamma-aminobutyric acid receptors. Acute effects of ethanol are then described on brain areas thought to be involved in arousal and attention, the reinforcing effects of ethanol, the production of euphoria, the actions of ethanol on motor control, and the amnesic effects of ethanol; the acute effects of ethanol demonstrated by EEG studies are also discussed. Chronic effects of alcohol on neuronal transmission are described in the context of the various components of the ethanol withdrawal syndrome, withdrawal hyperexcitability, dysphoria and anhedonia, withdrawal anxiety, craving, and relapse drinking. Electrophysiological studies on the genetic influences on the effects of ethanol are discussed, particularly the acute actions of ethanol and electrophysiological differences reported in individuals predisposed to alcoholism. The conclusion notes the concentration of studies on the classical transmitters, with relative neglect of the effects of ethanol on peptides and on neuronal interactions between brain areas and integrated patterns of neuronal activity.
Excessive consumption of beverage alcohol (ethanol) is a major health concern worldwide. Understanding the mechanisms by which ethanol affects neural functioning, after both acute and chronic exposure, has become a major goal in the study of alcoholism. With such an understanding, we should be able to institute more effective treatments and preventative measures for alcohol abuse problems. Recent studies have found, contrary to earlier assumptions, that ethanol has selective, dose-dependent effects on various neurotransmitter systems within the CNS. These effects are observed at all levels of analysis, from molecular to behavioral. This review by Herman Samson and Adron Harris covers these recent findings, with the intent of generating questions that will focus further research efforts.
Withdrawal of rats from chronic ethanol, morphine, cocaine and amphetamine resulted in a marked reduction in extracellular dopamine (DA) concentration in the ventral striatum as measured by microdialysis. Following ethanol and naloxone-precipitated morphine withdrawal, the time course of DA reduction paralleled that of the withdrawal symptomatology. On the other hand, following discontinuation of chronic cocaine, DA reduction was delayed by over 24 h but persisted for several days. After amphetamine withdrawal the fall in DA occurred more rapidly but the reduction also persisted for several days. The administration of the NMDA receptor antagonist, MK-801, to rats withdrawn from chronic ethanol, morphine or amphetamine, but not from chronic cocaine, readily reversed the fall in DA output. The reduction in extracellular DA during ethanol withdrawal was also reversed by SL 82.0715, another NMDA receptor antagonist.