Rayleigh light scattering detection of three α1-adrenoceptor antagonists coupled with high performance liquid chromatograph.

Herein, a Rayleigh light-scattering (RLS) detection method combined with high performance liquid chromatograph (HPLC) without any post-column probe was developed for the separation and determination of three α1-adrenoceptor antagonists. The quantitative analysis is benefiting from RLS signal enhancement upon addition of methanol which induced molecular aggregation to form an hydrophobic interface between aggregates and water that produce a sort of superficial enhanced scattering effect. A good chromatographic separation among the compounds was achieved using a Gemini 5u C18 reversed phase column (250 mm × 4.6 mm; 4 µm) with a mobile phase consisting of methanol and ammonium acetate-formic acid buffer solution (25 mM; pH=3.0) at the flow rate of 0.7 mL min(-1). The RLS signal was monitored at λex=λem=354 nm. A limit of detection (LOD) of 0.065-0.70 µg L(-1) was reached and a linear range was found between peak height and concentration in the range of 0.75-15 µg L(-1) for doxazosin mesylate (DOX), 0.075-3.0 µg L(-1) for prazosin hydrochloride (PRH), and 0.25-5 µg L(-1) for terazosin hydrochloride (TEH), with linear regression coefficients all above 0.999. Recoveries from spiked urine samples were 88.4-99.0% which is within acceptable limits. The proposed method is convenient, reliable and sensitive which has been used successfully in human urine samples.

Isotachophoretic determination of bisoprolol, clonidine, disopyramide and tolazoline in human fluids.

Separation and determination of bisoprolol, clonidine, disopyramide and tolazoline in control serum and in human urine was investigated by capillary isotachophoresis. The drugs were separated by using the cationic electrolyte system. viz., sodium acetate buffer (pH 4.64) (c1 = 10 mM)-beta-alanine. The compounds were almost totally isolated from serum by solid-phase extraction using a Sep-Pak C18 cartridge. The recovery of compounds varied from 87 to 99%. The linear calibration range was studied to apply the method to real human fluids. The limit of determination of the drugs was 40.0 micrograms/ml serum. The limit of determination by direct sampling for bisoprolol is 3 micrograms/ml urine.

Direct determination of naftopidil by non-protected fluid room temperature phosphorescence.

A selective and sensitive room temperature phosphorimetric method for the direct determination of naftopidil in biological fluids is described. The method is based on obtaining a phosphorescence signal from this antihypertensive drug using TlNO3 as a heavy atom perturber and Na2SO3 as a deoxygenator agent without a protective medium. This technique is named non-protected room temperature phosphorescence (NP-RTP), and enables us to determine analytes in complex matrices without the need for a tedious prior separation process. The optimization of Na2SO3 (8.5 x 10(-3) M) and the accurate value of pH (9.0) were determined using a simplex as a method of optimization. Sodium carbonate-hydrogencarbonate buffer solution (5.0 x 10(-2) M) was used to adjust the suitable pH. The optimum concentration of Tl+ (8.5 x 10(-2) M) was also determined. The delay time, gate time and time between flashes selected were 200 microseconds, 200 microseconds and 5 ms, respectively. Under the above conditions we propose a method to determine naftopidil by direct measurement of phosphorescence intensity with an emission wavelength of 526 nm and an excitation wavelength of 296 nm in the concentration range 0.05-1.00 mg L-1. Under these conditions the phosphorescence signal appears in 3 min once the sample has been prepared. Optimization of the various conditions permitted the establishment of an NP-RTP method for the determination with a detection limit, according to the error propagation theory, of 21.0 ng mL-1. The repeatability was studied using 10 solutions of 0.20 mg L-1 of naftopidil; if error propagation is assumed, the relative error is 1.39%. The standard deviation for replicate samples was 1.1 x 10(-2) mg L-1. This method was successfully applied to the determination of naftopidil, in human urine with recoveries between 106 and 112%.

Determination of the alpha, beta-adrenoceptor blocker YM-09538 in urine by gas chromatography with a nitrogen-sensitive detector.

A gas chromatographic method for the quantitative determination of the alpha, beta-adrenoceptor blocker YM-09538 in urine is described. YM-09538 was extracted from alkalinized urine with ethyl acetate and converted to its cyclic methylboronate derivative. Analysis by gas chromatography using a nitrogen-sensitive detector allowed quantitation of the drug over a concentration range of 0.2-5.0 micrograms/ml. Urinary excretion of YM-09538 was determined in humans after oral administration of 50 mg.

High-performance liquid chromatographic determination of the conjugate metabolites of moxisylyte in human plasma and urine.

Sensitive and specific high-performance liquid chromatographic methods with fluorescence detection are described for the determination of the metabolites of moxisylyte (4-(2-dimethylaminoethoxy)-5-isopropyl-2-methylphenyl acetate) in human plasma and urine. Deacetylmoxisylyte glucuroconjugate (DAM-G) was hydrolysed enzymatically using 1-glucuronidase and quantified as the difference between the DAM concentrations determined after and before hydrolysis. The two sulphate derivatives (deacetylmoxisylyte sulphoconjugate, DAM-S and monomethyldeacetylmoxisylyte sulphoconjugate, MDAM-S), were analysed without prior hydrolysis. Their extraction from plasma and urine, as well as that of DAM from plasma, involved the use of C18 cartridges adapted on a Benchmate workstation. DAM in urine was quantified after liquid-liquid extraction. The two methods were validated for specificity, linearity, intra- and inter-day precision and accuracy. Precision was generally < or = 15% and accuracy < or = 12%. In plasma, the limits of quantification were 2.5 ng/ml for DAM and 2.8 ng/ml for the two sulphates, in urine, they were 40 ng/ml for DAM and 200 ng/ml for the sulphates. These methods were used for pharmacokinetic studies in healthy subjects.

High-performance liquid chromatographic determination of alfuzosin in biological fluids with fluorimetric detection and large-volume injection.

A high-performance liquid chromatographic method has been developed for the determination of alfuzosin, a new antagonist of alpha 1 post-synaptic adrenergic receptors, in blood, plasma or urine. With fluorimetric detection and the large volume injection technique, the limit of detection in plasma is 0.5-1 ng ml-1, which is sensitive enough for pharmacokinetic studies in man. The calibration graph is linear between 1 and 200 ng ml-1 in blood plasma, with coefficients of variation of 6.2 and 1%, respectively. In urine, the linearity range is 0.05-10 micrograms ml-1; at the lowest concentration, the coefficient of variation is about 10%. A constant plasma/blood concentration ratio (1.25 +/- 0.05) allows the measurement of drug in either fluid. In blood or plasma, alfuzosin is stable at 37 degrees C for 24 h and at -20 degrees C for 6 months. As expected for reversed-phase chromatography, the retention times of alfuzosin and a few of its analogues decrease inversely with the concentration of acetonitrile in the mobile phase. However, as this concentration reaches about 75%, the retention times increase sharply. This U-shaped curve may be explained by interactions of the amino groups with silanol groups of the stationary phase.

Highly sensitive method for the determination of tamsulosin hydrochloride in human plasma dialysate, plasma and urine by high-performance liquid chromatography-electrospray tandem mass spectrometry.

A highly sensitive method for the determination of tamsulosin hydrochloride, a structurally new type of sulphamoile derivative, in human plasma dialysate, plasma and urine has been developed by using liquid chromatography-electrospray tandem mass spectrometry (LC-MS-MS). Plasma dialysate, plasma and urine samples were extracted by brief liquid-phase extraction and analyzed using an HPLC system coupled to a mass spectrometer via an electrospray ionization interface. Selected reaction monitoring was used for the detection of tamsulosin and its internal standard. This method was validated in the concentration range 10-1000 pg/ml in plasma dialysate, 0.5-50 ng/ml in plasma, and 1-100 ng/ml in urine with sufficient specificity, accuracy and precision. The in vivo protein binding study demonstrated that the unbound tamsulosin in human plasma obtained by the equilibrium dialysis after 0.4-mg oral dosing was measurable. In addition, the percentage of unbound tamsulosin in an in vitro study (0.71-0.91%) obtained by using spiked 14C-labelled tamsulosin was slightly larger than that of the in vivo study (0.68-0.86%), indicating that the unbound concentration calculated by the product of the plasma concentration and the in vitro unbound fraction (fu) was unfavorably overestimated. These results suggest that the combination of LC-MS-MS and equilibrium dialysis method has enough sensitivity to determine the unbound concentration in clinical use and gives the concentration more exactly than the in vitro fu.

Metabolism of tamsulosin in rat and dog.

1. The metabolism of tamsulosin hydrochloride (TMS), a potent alpha 1-adrenoceptor blocking agent, was studied after a single oral administration to rat and dog. 2. Eleven metabolites (1, 2, 3, 4 and their glucuronides, sulphates of 1 and 3, and A-1) were identified from the urine and bile of rat and dog administered TMS. 3. Unchanged drug and metabolites in urine and bile were quantified in rat and dog dosed with 14C-TMS(1 mg/kg). In rat the main metabolic routes were de-ethylation of the o-ethoxyphenoxy moiety, demethylation of the methoxybenzenesulphonamide moiety, and conjugation of the resultant metabolites by glucuronic acid and sulphuric acid. In dog the main pathways were de-ethylation of the ethoxyphenoxy moiety, conjugation of the de-ethylated product by sulphuric acid, and oxidative deamination of the side chain. 4. The organ responsible for the metabolism of TMS in rat was estimated using 9000g supernatants of liver, kidney, small and large intestine homogenate and plasma. The drug was rapidly metabolized in liver but hardly metabolized in the other organs or plasma.

Pharmacokinetics of moxisylyte in healthy volunteers after intracavernous injection of increasing doses.

OBJECTIVE: The concentration-time profiles of specific metabolites of moxisylyte, an alpha-adrenoceptor blocking agent, in the plasma and urine from 18 healthy volunteers were investigated after intracavernous (IC) administrations at three dose levels (10, 20 and 30 mg). RESULTS: Four metabolites, unconjugated desacetyl-moxisylyte (DAM), DAM glucuronide, and DAM and monodesmethylated DAM (MDAM) sulphates were found in plasma and urine. For all metabolites, t1/2 elimination was independent of the administered dose (1.19 h for unconjugated DAM; 1.51 h for DAM glucuronide; 1.51 h for DAM sulphate; and 2.17 h for MDAM sulphate). Cmax and AUC increased in direct proportion to dose, except for the inactive DAM glucuronide. Any the differences detected were small and equivalence of the three doses can be accepted. CONCLUSION: The pharmacokinetics of moxisylyte in humans following intracavernous administration were linear in the dose range 10 to 30 mg.