CHARACTERIZING THE PHARMACOLOGICAL PROFILE OF MEPHEDRONE AND DETERMINING THE ABUSE LIABILITY MECHANISMS

Saber, Iman A.

January 2017

Illicit drug use has been a growing concern over the past few decades. The rise in use of illegal drugs drove the government and law enforcement to aggressively tackle this problem and crackdown on the illicit use of drugs. However, this sparked a further interest in ‘legal highs.’ Before 2011, among the newly popular ‘legal highs’ was ‘Bath Salts.’ Cathinone is a monoamine alkaloid and the active ingredient found in the leaves of the khat plant. The psychoactive form of bath salts may contain a mixture of synthesized cathinones, including, 4-methyl-N-methcathinone (mephedrone), 3,4-methylenedioxy-N- methylcathinone (methylone) and methylenedioxypyrovalerone (MDPV). These three are commonly found in bath salts. One of the major psychoactive ingredients in bath salts is mephedrone. Mephedrone grew in popularity due to its low price, accessibility, and the shortage of MDMA, thus making mephedrone the prime drug to sell as a ‘legal high’ up until 2011 when it became banned in the United S / Pharmaceutical Sciences

Pharmacology

Behavioral Sciences

Neurosciences

Cathinone

Dopamine

Drug Discrimination

Self-administration

Serotonin

Sprague Dawley Rat

Glial Cell Modulators and Associated Anti-Inflammatory Activity: Implications in Reducing Methamphetamine Abuse-Related Behaviors in Rodents

Snider, Sarah

21 April 2014

Methamphetamine is a psychomotor stimulant that produces hyperactivity and euphoria and can lead to drug-seeking and abuse. An estimate from 2005 put the cost of methamphetamine abuse to society at an estimated 23.4 billion dollars. One of methamphetamine's effects is activation of glial cells and associated neuroinflammatory activity in the periphery and CNS. Glia are responsible for maintaining calcium homeostasis, neuroplasticity, immune activity, and cell signaling. Activation of glia and neuroinflammation are becoming recognized as links in drug abuse-related behavior. The goal of the present work was to assess the ability of ibudilast, AV1013, and minocycline, three glial cell modulating compounds, to attenuate responding in rodent procedures that model different aspects of methamphetamine abuse-related behavior. First, Ibudilast (1.8, 7.5, 13 mg/kg) and AV1013 (10, 30, 56 mg/kg) were examined for their effects on methamphetamine-induced (3 mg/kg) locomotor activity and sensitization in mice, the latter thought to involve neurocircuitry common with drug relapse. Ibudilast and AV1013 dose-dependently attenuated methamphetamine-induced locomotor activity and its sensitization. Second, ibudilast (1, 7.5, 10 mg/kg), AV1013 (1, 10, 30 mg/kg), and minocycline (10, 30, 60 mg/kg) were examined for their effects on methamphetamine self-administration (0.001, 0.03, and 0.1 mg/kg/inf) in rats. All three compounds significantly reduced methamphetamine (0.03 mg/kg/inf) self-administration. Results suggested baseline self-administration rate as a possible determinant of these effects; however, follow-up tests with ibudilast while controlling for baseline response rate dismissed this possibility. Additional follow-up tests identified whether the attenuation of operant response rates was specific to methamphetamine-maintained behavior. Using a behavioral economic approach, all three test compounds were determined to also affect non-nutritive banana pellet-maintained responding when the baseline strengths maintained by methamphetamine and banana pellet delivery were matched. Finally, ibudilast was evaluated for its effects on methamphetamine discrimination in rats, a procedure thought to model clinical subjective effects. Ibudilast (1, 7.5, 10 mg/kg) did not significantly modify methamphetamine’s discriminative stimulus effects when trained at either 1 or 0.56 mg/kg. These results support the hypothesis that attenuation of glial cell activity and neuroinflammation may be linked to some abuse-related behaviors of methamphetamine, reinforcing their examination as novel targets for treating methamphetamine abuse.

Methamphetamine

Locomotor Activity

Self Administration

Drug Discrimination

Mouse

Rat

Ibudilast

Behavioral Economics

Glia

Medical Pharmacology

Medical Sciences

Medicine and Health Sciences