Analysis of enantiomers of chiral phenethylamine drugs by capillary gas chromatography/mass spectrometry/flame-ionization detection and pre-column chiral derivatization

Enantioselective Analysis of Mexiletine Using Chromatographic Techniques: A Review

Background:

Mexiletine belongs to the β-amino-aryl-ether group of pharmaceutical and applied in the diagnosis of antiarrhythmics, allodynia, and myotonic disorders. In its chemical structure, it possesses a chiral center and practiced in the form of the racemic mixture. The production and accessibility of mexiletine have accompanied with a meaningful development in awareness of its pharmacologic actions. But in clinical arrhythmias and binding experiments on cardiac sodium channels, the (R)-enantiomer of mexiletine is more potent than the (S)-enantiomer. Also, (S)-enantiomer is further active in the diagnosis of allodynia than the (R)-enantiomer.

Methods:

During the last two decades, chromatographic techniques such as HPLC, and GC coupled with mass spectrometry or field ionization detector was used for the stereoselective analysis of MEX enantiomers.

Results:

The direct enantioresolution deal with the use of chiral stationary phases (CSPs) with or no pre-derivatization which depend on a chromophoric entity in the racemates whereas indirect HPLC process involved the use of chiral derivatization reagents (CDR) for the synthesis of diastereomeric derivatives of racemates. Different techniques have their strengths and weaknesses.

Conclusion:

Regulation of enantiomeric purity and estimation of particular enantiomers of drug molecules stays an essential topic for therapeutic, diagnostic, and regulatory uses and to promote a precise assessment of the hazards to human health by false enantiomers. This review aims to offer a systematic survey of the analytical methods (chromatography based) used in the enantioselective analysis of MEX developed in the last two decades (the year 2000 onwards).

Stereoselective analysis of ephedrine and its stereoisomers as impurities and/or by-products in seized methamphetamine by supercritical fluid chromatography/tandem mass spectrometry

In forensic science, drug profiling is clarifying the identity of seized drugs of abuse based on their physicochemical properties and it is applied to various drugs, including crystalline methamphetamine. Impurity analysis is particularly important in drug profiling because the impurities can be a measure for speculating how the methamphetamine was synthesized in the clandestine laboratories. However, developments in scientific techniques have allowed the synthesis of high-purity, homogeneous crystalline methamphetamine, and thus new techniques to characterize methamphetamine are needed. In this study, we developed a method for chiral separation of ephedrine and its stereoisomers by supercritical fluid chromatography. Ephedrine is a common starting compound for methamphetamine synthesis. It possesses two chiral center carbon atoms and has four stereoisomers, (1R,2S)-(-)-ephedrine, (1S,2R)-(+)-ephedrine, (1S,2S)-(+)-pseudoephedrine, and (1R,2R)-(-)-pseudoephedrine. Because the stereostructure of ephedrines contained in methamphetamine seizure reflects the starting materials and the synthetic pathways, the stereoisomer ratio will provide additional information for drug profiling. The developed method achieved rapid separation of four isomers in about 11min with low limits of detection (1pg on column). Due to a switching valve connecting a chromatograph to a mass spectrometer, dense methamphetamine sample solutions containing small amount of ephedrines could be analyzed directly with a simple pre-treatment. Using multivariate analysis, 44 real samples were objectively grouped based on stereoisomer ratio. Our method is expected to improve the profiling of crystalline methamphetamine.

Chiral Drug Analysis in Forensic Chemistry: An Overview

Many substances of forensic interest are chiral and available either as racemates or pure enantiomers. Application of chiral analysis in biological samples can be useful for the determination of legal or illicit drugs consumption or interpretation of unexpected toxicological effects. Chiral substances can also be found in environmental samples and revealed to be useful for determination of community drug usage (sewage epidemiology), identification of illicit drug manufacturing locations, illegal discharge of sewage and in environmental risk assessment. Thus, the purpose of this paper is to provide an overview of the application of chiral analysis in biological and environmental samples and their relevance in the forensic field. Most frequently analytical methods used to quantify the enantiomers are liquid and gas chromatography using both indirect, with enantiomerically pure derivatizing reagents, and direct methods recurring to chiral stationary phases.

Significance and challenges of stereoselectivity assessing methods in drug metabolism

Stereoselectivity in drug metabolism can not only influence the pharmacological activities, tolerability, safety, and bioavailability of drugs directly, but also cause different kinds of drug-drug interactions. Thus, assessing stereoselectivity in drug metabolism is of great significance for pharmaceutical research and development (R&D) and rational use in clinic. Although there are various methods available for assessing stereoselectivity in drug metabolism, many of them have shortcomings. The indirect method of chromatographic methods can only be applicable to specific samples with functional groups to be derivatized or form complex with a chiral selector, while the direct method achieved by chiral stationary phases (CSPs) is expensive. As a detector of chromatographic methods, mass spectrometry (MS) is highly sensitive and specific, whereas the matrix interference is still a challenge to overcome. In addition, the use of nuclear magnetic resonance (NMR) and immunoassay in chiral analysis are worth noting. This review presents several typical examples of drug stereoselective metabolism and provides a literature-based evaluation on current chiral analytical techniques to show the significance and challenges of stereoselectivity assessing methods in drug metabolism.

In situ aqueous derivatization as sample preparation technique for gas chromatographic determinations

The use of derivatization reactions is a common practice in analytical laboratories. Although in many cases it is tedious and time-consuming, it does offer a good alternative for the determination of analytes not compatible to gas chromatography. Many of the reactions reported in the literature occur in organic medium. However, in situ aqueous derivatization reactions, which can be performed directly in aqueous medium, offer important advantages over those mentioned above, such as no need of a previous extraction step and easy automation. Here we review the most recent developments and applications of in situ aqueous derivatization. The discussion focuses on the derivatization reactions used for the determination of alcohols and phenols, carboxylic acids, aldehydes and ketones, nitrogen-containing compounds and thiols in different aqueous matrices, such as environmental, biological and food samples. Several reactions are described for each functional group (acylation, alkylation, esterification, among others) and, in some cases, the same reagents can be used for several functional groups, such that there is an unavoidable overlap between sections. Finally, attention is also focused on the techniques used for the introduction of the derivatives formed in the aqueous medium into the chromatographic system. The implementation of in situ aqueous derivatization coupled to preconcentration techniques has permitted the enhancement of recoveries and improvements in the separation, selectivity and sensitivity of the analytical methods.

Stereoselective RP-HPLC determination of esmolol enantiomers in human plasma after pre-column derivatization

A stereoselective reversed-phase HPLC assay to determine S-(-) and R-(+) enantiomers of esmolol in human plasma was developed. The method involved liquid-liquid extraction of esmolol from human plasma, using S-(-)-propranolol as the internal standard, and employed 2,3,4,6-tetra-O-acetyl-beta-d-glucopyranosyl isothiocyanate as a pre-column chiral derivatization reagent. The derivatized products were separated on a 5-microm reversed-phase C18 column with a mixture of acetonitrile/0.02 mol/L phosphate buffer (pH 4.5) (55:45, v/v) as mobile phase. The detection of esmolol derivatives was made at lambda=224 nm with UV detector. The assay was linear from 0.035 to 12 microg/ml for each enantiomer. The analytical method afforded average recoveries of 94.8% and 95.5% for S-(-)- and R-(+)-esmolol, respectively. For each enantiomer, the limit of detection was 0.003 microg/ml and the limit of quantification for the method was 0.035 microg/ml (RSD<14%). The reproducibility of the assay was satisfactory.