Enantioselective analysis of pheniramine in rat using large volume sample stacking or cation-selective exhaustive injection and sweeping coupled with cyclodextrin modified electrokinetic chromatography.

For the aim of simultaneously performing the enantioseparation and determination of the trace enantiomers in plasma samples, enantioseparation by HPLC using five kinds of chiral stationary phases were initially investigated. But unfortunately, enantioseparation could not be detected in reversed mobile phase mode with all the five columns. For this reason, two simple, economical and highly efficient online preconcentration methods, large volume sample stacking and sweeping (LVSS-sweeping) and cation-selective exhaustive injection and sweeping (CSEI-sweeping) both followed by the cyclodextrin modified electrokinetic chromatography (CDEKC) were examined in the present work. Parameters affecting the enantioseparation and enhancement efficiency of these two injection modes were monitored in detail, and migration order of the two enantiomers was identified by circular dichroism (CD) and HPLC. Upon optimization, two enantiomers were best separated with the improvement of sensitivity reaching 160-fold and 4000-fold respectively for LVSS-sweeping and CSEI-sweeping comparing with the normal CDEKC separation. Then the optimal condition of CSEI-sweeping-CDEKC was validated and showed high sensitivity (10 ng/mL for lower limit of quantification, LLOQ), satisfactory accuracy (96.8-111.6%) and precision (relative standard deviation, RSD within 9.4%). This demonstrated it to be a suitable strategy for the rapid enantioselective determination and quantitative analysis of pheniramine enantiomers in plasma samples. Therefore, the method was further applied in the enantiomeric analysis of pheniramine in rat pharmacokinetics and plasma protein binding investigations. Stereoselectivity in pharmacokinetics as well as plasma protein binding were observed, suggesting that the stereoselective protein binding might be responsible for the stereoselectivity in pharmacokinetics.

Enantiomeric separation and simulation studies of pheniramine, oxybutynin, cetirizine, and brinzolamide chiral drugs on amylose-based columns.

Solid phase extraction (SPE)-chiral separation of the important drugs pheniramine, oxybutynin, cetirizine, and brinzolamide was achieved on the C18 cartridge and AmyCoat (150 x 46 mm) and Chiralpak AD (25 cm x 0.46 cm id) chiral columns in human plasma. Pheniramine, oxybutynin, cetirizine, and brinzolamide were resolved using n-hexane-2-PrOH-DEA (85:15:0.1, v/v), n-hexane-2-PrOH-DEA (80:20:0.1, v/v), n-hexane-2-PrOH-DEA (70:30:0.2, v/v), and n-hexane-2-propanol (90:10, v/v) as mobile phases. The separation was carried out at 25 ± 1 ºC temperature with detection at 225 nm for cetirizine and oxybutynin and 220 nm for pheniramine and brinzolamide. The flow rates of the mobile phases were 0.5 mL min(-1). The retention factors of pheniramine, oxybutynin, cetirizine and brinzolamide were 3.25 and 4.34, 4.76 and 5.64, 6.10 and 6.60, and 1.64 and 2.01, respectively. The separation factors of these drugs were 1.33, 1.18, 1.09 and 1.20 while their resolutions factors were 1.09, 1.45, 1.63 and 1.25, and 1.15, respectively. The absolute configurations of the eluted enantiomers of the reported drugs were determined by simulation studies. It was observed that the order of enantiomers elution of the reported drugs was S-pheniramine > R-pheniramine; R-oxybutynin > S-oxybutynin; S-cetirizine > R-cetirizine; and S-brinzolamide > R-brinzolamide. The mechanism of separation was also determined at the supramolecular level by considering interactions and modeling results. The reported SPE-chiral high-performance liquid chromatography (HPLC) methods are suitable for the enantiomeric analyses of these drugs in any biological sample. In addition, simulation studies may be used to determine the absolute configuration of the first and second eluted enantiomers.

Determination of loratadine and pheniramine from human serum by gas chromatography-mass spectrometry.

In this work, a method for the determination of the antihistaminic drugs loratadine and pheniramine from human serum is presented. Serum samples are extracted under basic conditions with hexane-n-amyl alcohol (95:5, v/v), the analytes are reextracted into diluted hydrochloric acid and, after basification, are once again extracted into the organic phase. The samples are measured by GC-MS. The limits o detection of the assay are 0.5 ng/ml for loratadine and 2 ng/ml for pheniramine. The R.S.D.s in the day-to-day precision test for loratadine are 7.0% at 20 ng/ml and 12.4% at 2 ng/ml. for pheniramine, the R.S.D. are 6.4% at 300 ng/ml and 10.2% at 20 ng/ml.

Pharmacokinetics of pheniramine (Avil) and metabolites in healthy subjects after oral and intravenous administration.

The pharmacokinetics of pheniramine and its two metabolites (N-desmethyl pheniramine and N-didesmethyl pheniramine) were determined in six healthy male subjects after intravenous (n = 3) or oral (n = 3) administration (30.5 mg of pheniramine - free base). Serum and urine levels were measured by HPLC. After i.v. administration, serum concentrations of pheniramine between 231 and 894 ng/ml were reached and after oral administration peak serum concentrations between 173 and 274 ng/ml were reached after 1-2.5 h. AUC values up to 72 h were 3035-4662 (i.v.) and 3507-5768 (ng/ml X h) (oral). The terminal half-lives were estimated to range between 8 and 17 h (i.v.) and 16 and 19 h (oral). Serum levels of the N-desmethyl derivative remained very low (up to 21 ng/ml), but were still detectable after 72 h. Serum levels of the N-didesmethyl derivative were below the detection limit. The amount of pheniramine excreted in the urine for up to 120 h varied between 5.7 and 11.6 mg and 10.2 and 13.2 mg after i.v. and oral administration respectively. Unlike the serum, considerable fractions of the drug occurred as metabolites in urine. Values were 8.1-16.4 mg (i.v.) and 7.4-13.3 mg (oral) for N-desmethyl pheniramine, 0.4-2.9 mg (i.v.) and 0.2-0.8 mg (oral) for N-didesmethyl pheniramine.