Tag Archive for: Brain neurons

In the realm of cannabis effects, the infamous “munchies” phenomenon has long been observed, but a recent breakthrough in research at Washington State University sheds light on the intricate mechanisms at play. Delving into the brains of mice exposed to vaporized cannabis sativa, scientists discovered a specific neural activity in the hypothalamus, a crucial region governing appetite. Published in Scientific Reports, this study not only deepens our understanding of how cannabis affects the brain but also holds promise for future therapeutic interventions targeting appetite disorders in cancer patients, individuals with anorexia, and potentially those struggling with obesity.

Employing advanced calcium imaging technology akin to a brain MRI, the researchers scrutinized the response of brain cells in mice exposed to cannabis vapor. Remarkably, the study uncovered the activation of neurons in the hypothalamus, specifically the Agouti Related Protein neurons, associated with the anticipation and consumption of palatable food. This activation was absent in the control group of unexposed mice.

Jon Davis, an assistant professor of neuroscience at WSU and the corresponding author, emphasized the significance of these findings, stating, “When the mice are given cannabis, neurons come on that typically are not active. There is something important happening in the hypothalamus after vapor cannabis.” The study marks a pioneering use of calcium imaging to explore brain reactions to food following cannabis exposure, setting it apart in the field of neuroscience research.

Crucially, the research identified the pivotal role of the cannabinoid-1 receptor, a well-known target of cannabis, in regulating the activity of Agouti Related Protein neurons. Employing a cutting-edge “chemogenetic” technique, acting as a molecular switch, researchers could manipulate these neurons. When deactivated, cannabis no longer induced an increase in appetite, providing a potential avenue for targeted therapeutic interventions.

This groundbreaking work builds upon earlier research from Davis’ lab, distinguishing itself by utilizing whole vaporized cannabis plant matter instead of isolated THC. This approach mirrors human cannabis consumption more closely. The study not only contributes to our understanding of the intricate dance between cannabis and appetite but also holds promise for developing more refined and targeted treatments for various appetite disorders.

Funding for this research was provided by the Alcohol and Drug Abuse Research Program, the National Institute on Alcohol Abuse and Alcoholism, the U.S. Department of Agriculture, and through financial support from the state of Washington Initiative Measure No. 171.

In conclusion, the groundbreaking research on cannabis’s influence on specific hunger neurons in the brain opens new avenues for understanding appetite regulation. By identifying the activation of distinct brain cells and the role of the cannabinoid-1 receptor, researchers have unveiled a potential pathway for developing targeted therapeutics. This discovery not only sheds light on the intricate relationship between cannabis and appetite but also holds promise for addressing appetite disorders in various medical contexts, ranging from supporting cancer patients to managing conditions like anorexia. As science delves deeper into the complexities of cannabis’s effects, this study contributes valuable insights that could pave the way for refined treatments and enhance our understanding of the brain’s response to recreational cannabis use.