Many studies on cocaine addiction – and attempts to block its addictiveness – have focused on dopamine transporters, proteins that reabsorb the brain’s “reward” chemical once its signal is sent. Since cocaine blocks dopamine transporters from doing their recycling job, it leaves the feel-good chemical around to keep sending the pleasure signal.
A study conducted at the U.S. Department of Energy’s Brookhaven National Laboratory suggests that cocaine’s effects go beyond the dopamine system. In the study, cocaine addiction had significant effects on brain metabolism, even in mice that lack the gene for dopamine transporters.
“In dopamine-transporter-deficient mice, these effects on metabolism are clearly independent of cocaine’s effects on dopamine,” said Brookhaven neuroscientist Panayotis (Peter) Thanos, who led the research. “These metabolic factors may be a strong regulator of cocaine addiction, and may also suggest new avenues for cocaine addiction treatments.”
The scientists used positron emission tomography, or PET scanning, to measure brain metabolism in dopamine-transporter deficient mice (known as DAT knockouts) and in littermates that had normal dopamine transporter levels. In this technique, the scientists administer a radioactively labeled form of sugar (glucose) – the brain’s main “fuel” – and use the PET scanner to track its site-specific concentrations in various brain regions. They tested the mice before and after cocaine administration, and compared the results to mice treated with saline instead of the drug.
Before any treatment, mice lacking dopamine transporters had significantly higher metabolism in the thalamus and cerebellum compared with normal mice. This elevated metabolism may be linked to chronically high levels of dopamine in the DAT knockout mice. It also suggests that dopamine levels may play an important role in modulating glucose levels in these brain areas, which play important roles integrating sensory information, learning, and motor function.
Interestingly, DAT knockout mice have been suggested as an animal model for attention-deficit hyperactivity disorder (ADHD). Elevated metabolism due to persistent elevated dopamine levels may be a factor contributing to the symptoms of ADHD, Thanos said.
After the scientists administered cocaine, whole brain metabolism decreased in both groups of mice, but more significantly in normal mice than in DAT knockouts. The scientists were able to detect this reduction in metabolism in a wide range of brain regions in the normal mice, suggesting that these decreases in metabolism are somehow associated with the blockade of dopamine transporters by cocaine addiction.
The scientists also observed a reduction in metabolism in the thalamus region in the DAT knockout mice. This effect may likely be due to the effect of cocaine addiction on other neurotransmitter systems, for example, norepinepherine or serotonin.
In summary, cocaine addiction has an effect on regional brain activity, which is mostly driven by dopamine action and to a secondary degree norepinephrine or serotonin. These results also support the idea that the thalamus and the cerebellum play key roles in cocaine’s mechanism of effect on sensory input, learning, and motor function. This is particularly of interest in better understanding the mechanism of cocaine addiction as well as the neurobiology of ADHD.
All research involving laboratory animals at Brookhaven National Laboratory is conducted under the jurisdiction of the Lab’s Institutional Animal Care and Use Committee in compliance with the Public Heath Service (PHS) Policy on Humane Care and Use of Laboratory Animals, the U.S. Department of Agriculture’s Animal Welfare Act, and the National Academy of Sciences’ Guide for the Care and Use of Laboratory Animals.
Source:
Cocaine’s Effects on Brain Metabolism May Contribute to Abuse. Brookhaven National Laboratory. February 2008
