Understanding addiction in the adolescent mind

Understanding addiction in the adolescent mind
Dr. Cui (left) and Dr. Taylor at the Cui Lab. Credit: Swanson School of Engineering/Paul Kovach

Several studies have provided strong evidence that adolescents—people in their teens to early twenties—have a higher vulnerability than adults to addictive substances like cocaine. To understand the origin of the age effect requires a sensor to effectively measuring how cocaine interacts with different parts of the brain over time.

Bioengineers at the University of Pittsburgh have developed a new method of using synthetic DNA called "aptamers" to view the effect of cocaine on the brain in real-time with a much higher resolution than other techniques. The Royal Society of Chemistry published their results in its Journal of Materials Chemistry B earlier this year.

"Aptamer-based cocaine sensors have been previously developed for detecting cocaine in whole blood samples, outside of the body. We are the first to develop a sensor for detecting cocaine in the of live animals," says Xinyan Tracy Cui, William Kepler Whiteford Professor of Bioengineering at Pitt's Swanson School of Engineering.

Dr. Cui is principal investigator for a two-year, $421,185 new study titled "Dual Polymer Coatings for High Fidelity and Stable In Vivo Cocaine Sensing From MEAs." She and her team will be using the aptamer-based sensors to observe the effects of cocaine use on both adult and adolescent rats and record the differences.

"It remains unknown whether the 'age effect' is the result of differences in neuron sensitivity to cocaine or a consequence of how cocaine concentrates in different areas of the brain," explains I. Mitch Taylor, postdoctoral researcher in the Cui Lab. "By measuring cocaine concentration and following the pharmacokinetics of the drug over repeated use in both adult and adolescent rats, we hope to answer this question."

In addition to observing the effect of cocaine on the brain, the researchers will be testing a polymer coating that protects the sensors from harmful exposure once they are implanted inside the rats. Past studies have shown that the brain's biological environment can interfere with the sensors' ability to relay information to the researchers.

"The worked great for a couple of hours in the brain tissue, and then performance degraded rapidly due to sensor degradation and biofouling," says Dr. Cui. "The newly funded project will use advanced polymers to stabilize the sensor and minimize the host tissue reactions, with the goal of achieving long term in vivo sensing over the period of days."

Dr. Cui aims to directly measure real-time cocaine concentration in different locations of the brain with micrometer resolution for at least 72 hours. Conventional methods of measuring cocaine in the tissue are only able to measure concentration levels every five-10 minutes and over a large volume.

The funding comes from a R21 Exploratory/Development grant from the National Institutes of Health (NIH) National Institute on Drug Abuse. The researchers will focus on studying usage during this grant period with potential to broaden their research efforts down the road.

"Our sensor technology platform is well suited to be developed for detecting other substances in the future," assures Dr. Cui.

More information: I. Mitch Taylor et al. Aptamer-functionalized neural recording electrodes for the direct measurement of cocaine in vivo, Journal of Materials Chemistry B (2017). DOI: 10.1039/C7TB00095B

Journal information: Journal of Materials Chemistry
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