Depressant effect of alcohol: action on GABA and Glutamate synapses and how this leads to over-drinking, addiction, withdrawal syndrome and relapse. This video is available for instant download licensing here : https://www.alilamedicalmedia.com/-/galleries/narrated-videos-by-topics/addiction-science/-/medias/60ac8268-63f3-420f-a6e8-5a083fc55ec3-alcohol-s-effects-on-the-brain-narrated-animation-professional
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Alcohol, or more specifically, ethanol, affects brain functions in several ways. Alcohol is generally known as a DEPRESSANT of the central nervous system; it INHIBITS brain activities, causing a range of physiological effects. The pleasurable feeling associated with drinking, on the other hand, is linked to alcohol-induced dopamine release in the brain’s reward pathway. Alcohol also increases levels of brain serotonin, a neurotransmitter implicated in mood regulation.
Neurons can be excitatory or inhibitory. Responsiveness or excitability of a neuron is determined by the value of electrical voltage across its membrane.
A balance between excitation and inhibition is essential for normal brain functions. Short-term alcohol consumption DISRUPTS this balance, INCREASING INHIBITORY and DECREASING EXCITATORY functions. Specifically, alcohol inhibits responsiveness of neurons via its interaction with the GABA system. GABA is a major INHIBITORY neurotransmitter. Upon binding, it triggers GABA receptors, ligand-gated chloride channels, to open and allow chloride ions to flow into the neuron, making it more NEGATIVE and LESS likely to respond to new stimuli. Alcohol is known to POTENTIATE GABA receptors, keeping the channels open for a longer time and thus exaggerating this inhibitory effect. GABA receptors are also the target of certain anesthetic drugs. This explains the SEDATIVE effect of alcohol.
At the same time, alcohol also inhibits the glutamate system, a major excitatory circuit of the brain. Glutamate receptors, another type of ion channel, upon binding by glutamate, open to allow POSITIVELY-charged ions into the cell, making it more POSITIVE and MORE likely to generate electrical signals. Alcohol binding REDUCES channel permeability, LOWERING cation influx, thereby INHIBITING neuron responsiveness. GABA ACTIVATION and glutamate INHIBITION together bring DOWN brain activities. Depending on the concentration of ethanol in the blood, alcohol’s depressant effect can range from slight drowsiness to blackout, or even respiratory failure and death.
Chronic, or long-term consumption of alcohol, however, produces an OPPOSITE effect on the brain. This is because SUSTAINED inhibition caused by PROLONGED alcohol exposure eventually ACTIVATES the brain’s ADAPTATION response. In attempts to restore the equilibrium, the brain DECREASES GABA inhibitory and INCREASES glutamate excitatory functions to compensate for the alcohol’s effect. As the balance tilts toward EXCITATION, more and more alcohol is needed to achieve the same inhibitory effect. This leads to overdrinking and eventually addiction. If alcohol consumption is ABRUPTLY reduced or discontinued at this point, an ill-feeling known as WITHDRAWAL syndrome may follow. This is because the brain is now HYPER-excitable if NOT balanced by the inhibitory effect of alcohol. Alcohol withdrawal syndrome is characterized by tremors, seizures, hallucinations, agitation and confusion. Excess calcium produced by overactive glutamate receptors during withdrawal is toxic and may cause brain damage. Withdrawal-related anxiety also contributes to alcohol-seeking behavior and CONTINUED alcohol abuse.