Health & Medicine - Posted by Tom Hughes-UNC on Wednesday, September 5, 2012 12:27 - 0 Comments
Alcohol botches brain’s rebound from trauma
UNC-CHAPEL HILL (US) — Heavy alcohol use rewires brain circuitry, which makes it harder for alcoholics to recover psychologically following a traumatic experience, say researchers.
Doctors have long recognized a link between alcoholism and anxiety disorders such as post-traumatic stress disorder (PTSD). Those who drink heavily are at increased risk for traumatic events like car accidents and domestic violence, but that only partially explains the connection.
Straight from the Source
“There’s a whole spectrum to how people react to a traumatic event,” says study author Thomas Kash, assistant professor of pharmacology at the University of North Carolina School of Medicine.
“It’s the recovery that we’re looking at—the ability to say ‘this is not dangerous anymore.’ Basically, our research shows that chronic exposure to alcohol can cause a deficit with regard to how our cognitive brain centers control our emotional brain centers.”
Scientists at the National Institute on Alcohol Abuse and Alcoholism (NIAAA) and University of North Carolina’s Bowles Center for Alcohol Studies conducted the study with mice, and their findings are published in Nature Neuroscience.
“A history of heavy alcohol abuse could impair a critical mechanism for recovering from a trauma, and in doing so put people at greater risk for PTSD,” says NIAAA scientist Andrew Holmes, the study’s senior author.
“The next step will be to test whether our preclinical findings translate to patients currently suffering from comorbid PTSD and alcohol abuse. If it does, then this could lead to new thinking about how we can better treat these serious medical conditions.”
Over the course of a month, the researchers gave one group of mice doses of alcohol equivalent to double the legal driving limit in humans. A second group of mice was given no alcohol. The team then used mild electric shocks to train all the mice to fear the sound of a brief tone.
When the tone was repeatedly played without the accompanying electric shock, the mice with no alcohol exposure gradually stopped fearing it. The mice with chronic alcohol exposure, on the other hand, froze in place each time the tone was played, even long after the electric shocks had stopped.
The pattern is similar to what is seen in patients with PTSD, who have trouble overcoming fear even when they are no longer in a dangerous situation.
The researchers traced the effect to differences in the neural circuitry of the alcohol-exposed mice. Comparing the brains of the mice, researchers noticed nerve cells in the prefrontal cortex of the alcohol-exposed mice actually had a different shape than those of the other mice. In addition, the activity of a key receptor, NMDA, was suppressed in the mice given heavy doses of alcohol.
Holmes says the findings are valuable because they pinpoint exactly where alcohol causes damage that leads to problems overcoming fear. “We’re not only seeing that alcohol has detrimental effects on a clinically important emotional process, but we’re able to offer some insight into how alcohol might do so by disrupting the functioning of some very specific brain circuits,” says Holmes.
Understanding the relationship between alcohol and anxiety at the molecular level could offer new possibilities for developing drugs to help patients with anxiety disorders who also have a history of heavy alcohol use.
“This study is exciting because it gives us a specific molecule to look at in a specific brain region, thus opening the door to discovering new methods to treat these disorders,” says Kash.
Study co-authors include additional researchers from UNC and NIAAA.