Catha edulis (Khat) and its alkaloids, cathinone and cathine: chemistry, pharmacology and a speculative study on the influence of 1-cathinone on the uptake and release of dopamine and norepinephrine in synaptosomes from different rat brain regions : a comparison with d-amphetamine

Al-Sharifi, Mamdouh

January 1983

This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).

Khat

Cathinone

Cathine

Alkaloids

Plant Extracts

Utilizing Voltage-gated Calcium Channels to Assess the Activity of Cathinone Derivatives at Human Monoamine Transporters

Ruiz, Brian A

01 January 2018

Cathinones are psychostimulant compounds heavily implicated as drugs of abuse. They exert their physiological actions at the monoamine transporters, which are responsible for maintaining synaptic neurotransmitter homeostasis. Monoamine transporters produce currents during transport and have been shown to depolarize cell membranes and activate voltage-gated calcium channels in mammalian expression systems. This phenomenon is harnessed in an assay which measures these induced calcium transients, allowing for quantification of pharmacodynamic effects of compounds at monoamine transporters. It is unknown if this electrical coupling occurs in neurons, but the implications if it does are significant. In the current work, fluorescent resonance energy transfer studies of HEK cells expressing hDAT suggest that a subpopulation of monoamine transporters and calcium channels may be interacting directly. Additionally, this work presents calcium assay data comparing several novel methcathinone analogs. Of the compounds tested, a single α-methyl substituent at the α-carbon yields the greatest potency at hDAT. The implications of these results shed light on future psychostimulant studies and further define the physiological relationship of the components of a system used to study these compounds.

monoamine transporter

psychostimulant

cathinone

dopamine

serotonin

addiction

Cellular and Molecular Physiology

CHEMOKINE MODULATION OF MDPV-INDUCED BEHAVIOR AND NEUROPLASTICITY

Oliver, Chicora

January 2019

Psychostimulant abuse is a major public health concern yet no FDA-approved medications exist. Synthetic cathinones (“bath salts”) are a class of psychostimulants that have emerged relatively recently worldwide. One synthetic cathinone, MDPV (3,4-methylenedioxypyrovalerone) is mechanistically similar to cocaine but is over ten times more potent, possesses high abuse potential, and is relatively understudied. Recent studies have revealed involvement of inflammatory proteins called chemokines in the rewarding effects of MDPV and the mechanistically similar drug, cocaine. We and others have shown that the chemokine-receptor ligand pair CXCL12-CXCR4 is recruited in the rewarding effects of cocaine and MDPV. Humans and animal models of cocaine addiction have dysregulated CXCL12 and the commercially-available CXCR4 antagonist, AMD3100, can reverse cocaine use and relapse in preclinical models of addiction. Specifically, AMD3100 reduces self-administration and reinstatement to cocaine-seeking with concomitant alterations in CXCL12 gene expression in the midbrain. Here, I employ several complementary methods to demonstrate that AMD3100 also reverses MDPV-elicited behaviors. I demonstrate that (i) AMD3100 reverses MDPV-induced hyperlocomotion, conditioned place preference (preclinical model of drug reward), self-administration and reinstatement to MDPV-seeking behavior; (ii) AMD3100 can rescue MDPV-induced deficits in measures of anxiety and recognition memory shortly after a binge; and (iii) repeated MDPV exposure upregulates CXCL12 gene expression in the nucleus accumbens with concomitant downregulation of dendrite morphometrics and a related synapse scaffolding protein gene expression. These findings implicate CXCR4-CXCL12 signaling in the modulation of MDPV-elicited behaviors, suggesting that AMD3100 is a viable therapeutic option for the effects of this synthetic cathinone. / Psychology

Neurosciences

Chemokine

Inflammation

Mdpv

Psychostimulant

Reward

Synthetic Cathinone

Lethal and Toxic Effects of Synthetic Cathinone Analogues at Physiologically Preferred and High Temperatures

Heeren, Sasha

January 2021

No description available.

Pharmacology

Toxicology

Cathinone

dimethylone

pentylone

psychostimulant

bath salts

dopamine

ammonia

zebrafish

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

Comprehensive Forensic Toxicological Analysis of Designer Drugs

Swortwood, Madeleine Jean

21 October 2013

New designer drugs are constantly emerging onto the illicit drug market and it is often difficult to validate and maintain comprehensive analytical methods for accurate detection of these compounds. Generally, toxicology laboratories utilize a screening method, such as immunoassay, for the presumptive identification of drugs of abuse. When a positive result occurs, confirmatory methods, such as gas chromatography (GC) or liquid chromatography (LC) coupled with mass spectrometry (MS), are required for more sensitive and specific analyses. In recent years, the need to study the activities of these compounds in screening assays as well as to develop confirmatory techniques to detect them in biological specimens has been recognized. Severe intoxications and fatalities have been encountered with emerging designer drugs, presenting analytical challenges for detection and identification of such novel compounds. The first major task of this research was to evaluate the performance of commercially available immunoassays to determine if designer drugs were cross-reactive. The second major task was to develop and validate a confirmatory method, using LC-MS, to identify and quantify these designer drugs in biological specimens. Cross-reactivity towards the cathinone derivatives was found to be minimal. Several other phenethylamines demonstrated cross-reactivity at low concentrations, but results were consistent with those published by the assay manufacturer or as reported in the literature. Current immunoassay-based screening methods may not be ideal for presumptively identifying most designer drugs, including the “bath salts.” For this reason, an LC-MS based confirmatory method was developed for 32 compounds, including eight cathinone derivatives, with limits of quantification in the range of 1-10 ng/mL. The method was fully validated for selectivity, matrix effects, stability, recovery, precision, and accuracy. In order to compare the screening and confirmatory techniques, several human specimens were analyzed to demonstrate the importance of using a specific analytical method, such as LC-MS, to detect designer drugs in serum as immunoassays lack cross-reactivity with the novel compounds. Overall, minimal cross-reactivity was observed, highlighting the conclusion that these presumptive screens cannot detect many of the designer drugs and that a confirmatory technique, such as the LC-MS, is required for the comprehensive forensic toxicological analysis of designer drugs.

designer drugs

toxicology

LC-MS

ELISA

EMIT

cross-reactivity

cathinone derivatives

forensic toxicology

bath salts

Analytical Chemistry

Toxicology