Cocaine Addiction Therapy: Rosemary Compound Shows Promise

Paracelsus

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In a study published in Neuron researchers from the University of California, Irvine, have identified a key brain circuit involved in cocaine addiction and uncovered a promising therapeutic compound, carnosic acid, that may help in reducing cocaine's addictive grip. The study sheds light on the complex neurobiology of addiction and offers a new avenue for treatment that could potentially save lives.

The Study at a Glance​

The research, led by Guilian Tian and colleagues, explores how specific neurons in the brain's globus pallidus externus (GPe) region influence cocaine-induced behavioral changes. The GPe, traditionally associated with motor control, was found to play a crucial role in controlling the behavioral responses to cocaine. This region acts as a gatekeeper, determining how susceptible an individual is to the drug's effects.

The team's experiments on mice demonstrated that activity in GPe neurons, particularly those expressing the proteins KCNQ3 and KCNQ5, correlates strongly with the animals' sensitivity to cocaine. Notably, after cocaine administration, the expression of these proteins decreased, leading to heightened neuron excitability, which in turn reinforced addictive behaviors.

The Role of Carnosic Acid​

One of the most exciting findings from the study is the identification of carnosic acid—a compound derived from rosemary—as a potential treatment for cocaine addiction. Carnosic acid was shown to activate KCNQ3/5 channels in the GPe, reducing neuron excitability. This effect significantly impaired cocaine's rewarding properties and reduced both the development of addiction-like behaviors and the voluntary consumption of the drug.

Implications for Addiction Therapy​

The study's findings are particularly promising because they suggest that carnosic acid, or similar compounds, could be used to treat psychostimulant addiction with minimal side effects. Unlike other treatments that affect the entire dopamine system, leading to various undesirable effects, this approach targets specific circuits, offering a more focused and potentially safer intervention.

Looking Ahead​

While the results are preliminary and have so far only been demonstrated in mice, they offer a hopeful perspective on future treatments for cocaine addiction. Further research will be needed to confirm these effects in humans and to explore whether similar approaches could be applied to other forms of addiction.

Read the full article here: Molecular and Circuit Determinants in the Globus Pallidus Mediating Control of Cocaine-Induced Behavioral Plasticity.


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