Beta‐caryophyllene, a Volatile Phytocannabinoid, Attenuates Cocaine Self‐administration and Relapse in Rats

Abstract

Cocaine abuse continues to be a serious health problem worldwide. Despite intense research, there is still no FDA‐approved medication to treat cocaine use disorder. The recent search for effective therapeutics has been focused on the endocannabinoid system because of its critical role in the neurobiology of drug addiction. In the last decade, there has been a growing interest in beta‐caryophyllene (BCP), a volatile phytocannabinoid present in high proportions in cannabis and large number of spice and food plants including black pepper, thyme and cloves. This dietary additive that has a CB2 receptor (CB2R) agonist profile, has shown to produce promising therapeutic effects for multiple neuropsychiatric disorders. Surprisingly, the therapeutic potential of BCP in the treatment of drug abuse and addiction has not been explored. Here, using gold standard animal models of drug abuse, we systematically evaluated the potential utility of BCP against cocaine‐related behaviors in rodents and its mechanisms of action. In a series of experiments we found that BCP attenuated cocaine‐enhanced electrical brain‐stimulation reward and optogenetic intracranial self‐stimulation driven by activation of dopamine (DA) neurons in DAT‐cre mice, both outcomes indicating reduced reward. Intriguingly, when administered systemically or orally, BCP attenuated cocaine self‐administration in rats, suggesting an ability to reduce drug abuse. BCP also reduced drug‐primed reinstatement of cocaine seeking and cocaine conditioned place preference, indicative of its preventative effects against relapse. When BCP was substituted for cocaine, rats ceased responding, suggesting BCP has low liability abuse. In regards to the receptor mechanisms, our pharmacological approach (along with our transgenic approach utilizing with CB1, CB2, GPR55 knockout mice) indicates that BCP produces attenuating effects on cocaine self‐administration that are mediated by non‐cannabinoid receptors. We are now exploring the involvement of peroxisome proliferator‐activated receptor (PPAR) and transient receptor potential vanilloid 1 cation channels (TRPV1) in BCP action against cocaine. Our findings suggest that BCP shows exceptional promise as a therapeutic candidate in the treatment of cocaine use disorder. Importantly, given its good oral bioavailability and the advantage of being an already FDA‐approved non‐toxic dietary additive, BCP is a valuable candidate for drug repurposing programs in translational medicine.