Your search keyword '"Anizan S"' showing total 5 results

1. In Vivo Toxicokinetics of Novel Psychoactive Substances (NPS) in Rats

Author

Huestis, M.A., primary, Concheiro, M., additional, Scheidweiler, K.B., additional, Anizan, S., additional, Lehner, K.R., additional, Bukhari, M.O., additional, Suzuki, M., additional, Rice, K.C., additional, and Baumann, M.H., additional

Published

2015

2. Determination of five tetracyclines and their epimers by LC-MS/MS based on a liquid-liquid extraction with low temperature partitioning.

Author

Desmarchelier A, Anizan S, Minh Tien M, Savoy MC, and Bion C

Subjects

Chromatography, Liquid, Food Analysis, Food Contamination analysis, Liquid-Liquid Extraction, Tandem Mass Spectrometry, Temperature, Tetracyclines analysis, Tetracyclines chemistry

Abstract

An LC-MS/MS method is presented for screening five tetracyclines and their epimers in a broad range of food products. The scope of matrices includes meat-, fish-, seafood-based products, various dairy ingredients, infant formulae and fats. The method principle is based on a liquid-liquid extraction with aqueous ethylenediaminetetraacetic acid (EDTA) and acetonitrile followed by a freezing step to promote phase separation at low temperature. After defatting with hexane, sample extracts were evaporated and reconstituted before injection onto the LC-MS/MS system. The addition of oxalic acid in the aqueous mobile phase was mandatory to maintain good peak shape and sensitivity over the run. The screening is based upon a double preparation of each sample, one 'as such' and a second one with the analytes spiked in the sample, in order to mitigate the risk of false negative response. The method was validated according to the European Community Reference Laboratories Residues Guidelines. A total of 93 samples were included in the validation by two independent laboratories giving both false-negative and false-positive rates at 0% for all compounds. Over the last two years, 2600 samples were analysed routinely and only one chicken sample was found above the regulatory limit.

Published

2018

3. Neuropharmacology of 3,4-Methylenedioxypyrovalerone (MDPV), Its Metabolites, and Related Analogs.

Author

Baumann MH, Bukhari MO, Lehner KR, Anizan S, Rice KC, Concheiro M, and Huestis MA

Subjects

Animals, Behavior, Animal drug effects, Brain drug effects, Humans, Neuropharmacology, Substance-Related Disorders, Synthetic Cathinone, Adrenergic Uptake Inhibitors pharmacology, Benzodioxoles pharmacology, Dopamine Plasma Membrane Transport Proteins drug effects, Dopamine Uptake Inhibitors pharmacology, Norepinephrine Plasma Membrane Transport Proteins drug effects, Psychotropic Drugs pharmacology, Pyrrolidines pharmacology

Abstract

3,4-Methylenedioxypyrovalerone (MDPV) is a psychoactive component of so-called bath salts products that has caused serious medical consequences in humans. In this chapter, we review the neuropharmacology of MDPV and related analogs, and supplement the discussion with new results from our preclinical experiments. MDPV acts as a potent uptake inhibitor at plasma membrane transporters for dopamine (DAT) and norepinephrine (NET) in nervous tissue. The MDPV formulation in bath salts is a racemic mixture, and the S isomer is much more potent than the R isomer at blocking DAT and producing abuse-related effects. Elevations in brain extracellular dopamine produced by MDPV are likely to underlie its locomotor stimulant and addictive properties. MDPV displays rapid pharmacokinetics when injected into rats (0.5-2.0 mg/kg), with peak plasma concentrations achieved by 10-20 min and declining quickly thereafter. MDPV is metabolized to 3,4-dihydroxypyrovalerone (3,4-catechol-PV) and 4-hydroxy-3-methoxypyrovalerone (4-OH-3-MeO-PV) in vivo, but motor activation produced by the drug is positively correlated with plasma concentrations of parent drug and not its metabolites. 3,4-Catechol-PV is a potent uptake blocker at DAT in vitro but has little activity after administration in vivo. 4-OH-3-MeO-PV is the main MDPV metabolite but is weak at DAT and NET. MDPV analogs, such as α-pyrrolidinovalerophenone (α-PVP), display similar ability to inhibit DAT and increase extracellular dopamine concentrations. Taken together, these findings demonstrate that MDPV and its analogs represent a unique class of transporter inhibitors with a high propensity for abuse and addiction.

Published

2017

4. Linear pharmacokinetics of 3,4-methylenedioxypyrovalerone (MDPV) and its metabolites in the rat: relationship to pharmacodynamic effects.

Author

Anizan S, Concheiro M, Lehner KR, Bukhari MO, Suzuki M, Rice KC, Baumann MH, and Huestis MA

Subjects

Animals, Benzodioxoles pharmacology, Designer Drugs pharmacokinetics, Designer Drugs pharmacology, Dopamine Uptake Inhibitors pharmacokinetics, Dopamine Uptake Inhibitors pharmacology, Dose-Response Relationship, Drug, Male, Motor Activity drug effects, Psychotropic Drugs pharmacology, Pyrrolidines pharmacology, Rats, Sprague-Dawley, Synthetic Cathinone, Benzodioxoles pharmacokinetics, Psychotropic Drugs pharmacokinetics, Pyrrolidines pharmacokinetics

Abstract

3,4-Methylenedioxypyrovalerone (MDPV) is a commonly abused synthetic cathinone in the United States and is associated with dangerous side effects. MDPV is a dopamine transporter blocker that is 10-fold more potent than cocaine as a locomotor stimulant in rats. Previous in vitro and in vivo metabolism studies identified 3,4-dihydroxypyrovalerone (3,4-catechol-PV) and 4-hydroxy-3-methoxypyrovalerone (4-OH-3-MeO-PV) as the two primary MDPV metabolites. This study examined MDPV pharmacokinetics and metabolism, along with associated pharmacodynamic effects in rats receiving 0.5, 1.0 and 2.0 mg/kg subcutaneous (s.c.) MDPV. Blood was collected by an indwelling jugular catheter before dosing and at 10, 20, 30, 60, 120, 240 and 480 minutes thereafter. Plasma specimens were analyzed by liquid chromatography coupled to high-resolution tandem mass spectrometry. Maximum concentrations (Cmax ) and area-under-the-curve (AUC) for MDPV and two metabolites increased proportionally with administered dose, showing linear pharmacokinetics. MDPV exhibited the highest Cmax at all doses (74.2-271.3 μg/l) and 4-OH-3-MeOH-PV the highest AUC (11 366-47 724 minutes per μg/l), being the predominant metabolite. MDPV time to Cmax (Tmax ) was 12.9-18.6 minutes, while 3,4-catechol-PV and 4-OH-3-MeO-PV peaked later with Tmax 188.6-240 minutes after s.c. dosing. Horizontal locomotor activity (HLA) and stereotypy correlated positively with plasma MDPV concentrations, while HLA correlated negatively with MDPV metabolites. These results suggest that the parent compound mediates motor stimulation after systemic MDPV administration, but additionally, metabolites may be inhibitory, may not be active or may not pass the blood brain barrier., (Published 2014. This article is a U.S. Government work and is in the public domain in the USA.)

Published

2016

5. The corticotropin releasing hormone-1 (CRH1) receptor antagonist pexacerfont in alcohol dependence: a randomized controlled experimental medicine study.

Author

Kwako LE, Spagnolo PA, Schwandt ML, Thorsell A, George DT, Momenan R, Rio DE, Huestis M, Anizan S, Concheiro M, Sinha R, and Heilig M

Subjects

Adult, Aged, Alcohol Deterrents pharmacokinetics, Alcoholism psychology, Brain drug effects, Brain physiopathology, Central Nervous System Depressants, Craving drug effects, Cues, Double-Blind Method, Emotions physiology, Ethanol, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Pyrazoles pharmacokinetics, Receptors, Corticotropin-Releasing Hormone antagonists & inhibitors, Stress, Psychological drug therapy, Stress, Psychological physiopathology, Triazines pharmacokinetics, Visual Perception drug effects, Visual Perception physiology, Young Adult, CRF Receptor, Type 1, Alcohol Deterrents administration & dosage, Alcoholism drug therapy, Alcoholism physiopathology, Pyrazoles administration & dosage, Triazines administration & dosage

Abstract

Extensive preclinical data implicate corticotropin-releasing hormone (CRH), acting through its CRH1 receptor, in stress- and dependence-induced alcohol seeking. We evaluated pexacerfont, an orally available, brain penetrant CRH1 antagonist for its ability to suppress stress-induced alcohol craving and brain responses in treatment seeking alcohol-dependent patients in early abstinence. Fifty-four anxious alcohol-dependent participants were admitted to an inpatient unit at the NIH Clinical Center, completed withdrawal treatment, and were enrolled in a double-blind, randomized, placebo-controlled study with pexacerfont (300 mg/day for 7 days, followed by 100 mg/day for 23 days). After reaching steady state, participants were assessed for alcohol craving in response to stressful or alcohol-related cues, neuroendocrine responses to these stimuli, and functional magnetic resonance imaging (fMRI) responses to alcohol-related stimuli or stimuli with positive or negative emotional valence. A separate group of 10 patients received open-label pexacerfont following the same dosing regimen and had cerebrospinal fluid sampled to estimate central nervous system exposure. Pexacerfont treatment had no effect on alcohol craving, emotional responses, or anxiety. There was no effect of pexacerfont on neural responses to alcohol-related or affective stimuli. These results were obtained despite drug levels in cerebrospinal fluid (CSF) that predict close to 90% central CRH1 receptor occupancy. CRH1 antagonists have been grouped based on their receptor dissociation kinetics, with pexacerfont falling in a category characterized by fast dissociation. Our results may indicate that antagonists with slow offset are required for therapeutic efficacy. Alternatively, the extensive preclinical data on CRH1 antagonism as a mechanism to suppress alcohol seeking may not translate to humans.

Published

2015