Cocaine’s secondary costs to society due to cocaine treatment and prevention programs, emergency room visits and other healthcare costs, lost job productivity, lost earnings, cocaine-related crime, and social welfare are estimated to be in the billions of dollars annually–not to mention the drug’s human toll. According to the National Institute on Drug Abuse (NIDA), about 1.7 million people regularly use cocaine in the United States–a population larger than that of the city of Philadelphia–and cocaine is the leading cause of heart attacks and strokes for people under 35.
Once in the bloodstream, cocaine crosses the blood-brain barrier and accumulates rapidly in the ventral tegmental area of the brain. This area is connected by nerve cells to the nucleus accumbens, the so-called pleasure center of the brain. There, the cocaine molecules interfere with the normal regulation of dopamine by binding to dopamine transporters and blocking them from recycling the neurotransmitter.
This leads to the build-up of dopamine in the brain’s pleasure center, which produces a euphoric feeling in the user–a quick rush that hits seconds after the user takes the drug and lasts several minutes.
Relapse, unfortunately, is a reality for many addicts. Part of the basis of relapse may be the strong positive reinforcement of the high–doing the drug is so enjoyable for addicts that they are conditioned to return to it.
Several years ago, Janda and his colleagues designed an antibody that was able to bind to cocaine. If the antibody was present in the bloodstream, it would soak up the cocaine like a sponge and prevent it from entering the central nervous system where the drug exerts its narcotic effect. As a molecule, cocaine is easily degraded by the body’s natural chemistry, and the sequestered cocaine would eventually disappear.
While this strategy was partially effective, the ability of the antibody to curtail cocaine’s effect proved to be limited in animal studies. The antibody could not cross the blood-brain barrier and cocaine could. In laboratory models, a large dose of cocaine molecules could overwhelm the antibodies in the blood, doing an end-run around them and leaking into the brain.
A few years ago, Janda and his graduate students Rocio Carrera and Gunnar Kaufmann decided they wanted to target the cocaine antibodies into the brain. That’s when they set out to create a new form of virus. This was done with collaborators Jenny Mee and Michael Meijler in the Department of Chemistry and Professor George Koob in the Department of Neuropharmacology and the Pearson Center For Alcoholism And Addiction Research at Scripps Research.
The reserachers used filamentous phage–a type of virus that infects bacteria–for the study. They inserted DNA encoding an antibody that binds cocaine into the phage’s genetic code. When the modified phage were grown, they had hundreds of these antibodies displayed on their surfaces.
Phage particles, like many types of viruses, have the ability to enter the brain through the internasal passageway. Janda, Carrera, and Kaufmann used this ability to deliver their antibody into the central nervous system. The current study demonstrates the ability of the antibody/phage to reduce one effect of cocaine in rodent models (increased locomotion).
A similar technique could potentially be used for treating the positively reinforcing aspects of the drug in humans, say the scientists, but they cautioned that such an approach has not been tested clinically and that even if proven safe and effective it would be years before any such therapy were available to patients.
The technique of displaying therapeutic proteins or peptides on phage particles could be useful as a general way of delivering therapies into the brain
The research article “Treating cocaine addiction with viruses” is authored by M. Rocio A. Carrera, Gunnar F. Kaufmann, Jenny M. Mee, Michael M. Meijler, Kim D. Janda, and George F. Koob and is being published online the week of June 21 – 25, 2004 by the journal Proceedings of the National Academy of Sciences. It will appear in a printed issue of PNAS later this year.
This research was supported by the National Institute on Drug Abuse and The Skaggs Institute for Chemical Biology at The Scripps Research Institute.