High-performance liquid chromatographic analysis of epinephrine enantiomers using a UV detector in series with an optical activity detector

Determination of enantiomeric purity of ephedrine and pseudoephedrine by high-performance liquid chromatography with dual optical rotation/UV absorbance detection

A reversed-phase high-performance liquid chromatography (HPLC) method with dual optical rotation/UV absorbance detection has been developed for the determination of enantiomeric purity of ephedrine hydrochloride and pseudoephedrine hydrochloride using an achiral column. The method gave a correlation coefficient of 0.9997 for the plot of log(optical rotation response) versus log (concentration) over the range of 0.06-10 mg ml(-1) of (+)-ephedrine hydrochloride (20 microliters injection). The limit of detection was 1.0 micrograms. Enantiomeric purity is shown to be most readily determined by measuring optical rotation, alpha, and absorbance, A, responses for standard and unknown samples, and using the equation (alpha/A)u/(alpha/A)s = (2xu - 1)/(2xs - 1), where x is the mole fraction of one of the enantiomers and subscripts s and u refer to standard and unknown, respectively. In blind trials using unknown mixtures of (+)- and (+/-)-ephedrine hydrochloride and a (+)-ephedrine hydrochloride standard, enantiomeric purities were determined to +/- 0.4% (95% confidence level) with five or six replicate 50 micrograms injections. The method has also been applied to the determination of the enantiomer mole fraction of (+)-pseudoephedrine hydrochloride in a cough linctus, giving xu = 0.99 +/- 0.01 with seven replicate injections of 20-fold diluted linctus samples containing 7.5 micrograms of the chiral compound being assayed. Unlike conventional polarimetry, the method does not require chemically-pure samples and can be orders of magnitude more economical in material.

A review of the application of chiroptical methods to analytical chemistry

The analytical applications of the two most important chiroptical methods, optical rotatory dispersions (ORD) and circular dichroism (CD), have been surveyed, emphasizing the methods corresponding to the profile of the Journal of Pharmaceutical and Biomedical Analysis. After a brief introduction of the ORD and CD methods, the advantages and drawbacks of the application of the two methods have been described, and compared, and the calibration of ORD and CD instruments have been given. The analytical applications have been divided as follows: the use of ORD and CD in identification studies, the direct determination of optically active substances, the determination of optically active compounds after chromophore group formation, determination of optically inactive substances via their products with optically active compounds. The difference chiroptical methods increasing the selectivity of measurements and the chiroptical titrations have been summarized. Stress has been laid on the applicability of selective chiroptical detectors (based on laser light, too) used in liquid chromatography and the future developments have been mentioned.

Polarimetric detection in high-performance liquid chromatography

Chiroptical detection for HPLC is particularly useful as a selective detection method for chiral molecules, and in enantiomeric purity determination with partial chiral separation or without chiral separation. The recent development of laser-based polarimeters with microdegree sensitivity has increased the applicability of optical rotation detection in HPLC. The detection limit of these instruments is submicrogram on-column for many chiral compounds in analytical HPLC. A variety of applications of the selective detection of optically active molecules are reviewed. The use of polarimetric detection with partial chiral separation is considered, both as an aid to method development and for enantiomeric purity determination. Finally applications to enantiomeric purity determination without chiral separation are reviewed, with the dual use of nonchirally selective and chiroptical detectors to determine the total amount and optical purity of the analyte. Determinations of chiral purity for samples of high enantiomeric excess are described, which with laser-based instrumentation may give accuracies of better than +/- 1% with sample loadings of 50 micrograms on an achiral column. Applications to the study of enantioselective reactions are also considered, with determination of enantiomeric excess in near-racemates to better than +/- 0.1%.

Chromatographic separation of enantiomers

In this paper a review is presented on the chromatographic analysis of enantiomers with special attention to high pressure liquid chromatography. Also, some examples of resolution of racemates by thin layer chromatography and gas chromatography are given. The various procedures in the surveyed literature have been divided into three main classes: procedures with formation of diastereomeric compounds prior to the chromatographic separation, procedures in which a chiral mobile phase is used, and procedures with the use of a chiral stationary phase. These methods are subdivided and some examples of their application to drugs and related compounds are presented.