Development and validation of a fast ultra-high-performance liquid chromatography tandem mass spectrometry method for determining carbonic anhydrase inhibitors and their metabolites in urine and hair.

A new, rapid, sensitive, and comprehensive ultra-high-performance liquid chromatography tandem mass spectrometry (UHPLC-MS/MS) method for quantifying diuretics (acetazolamide, brinzolamide, dorzolamide, and their metabolites) in human urine and hair was developed and fully validated. Twenty-five milligrams of hair were incubated with 500-µl M3® buffer reagent at 100°C for 1 h for complete digestion. After cooling, 1-µl supernatant was injected onto chromatography system. Urine samples were simply diluted before injection. The chromatographic run time was short (8 min) through a column with a mobile phase gradient. The method was linear (determination coefficients always higher than 0.99) from limit of quantification (LOQ) to 500 ng/ml in urine and from LOQ to 10 ng/mg in hair. LOQs ranged from 0.07 to 1.16 ng/ml in urine and from 0.02 to 0.15 ng/mg in hair. No significant ion suppression due to matrix effect was observed, and process efficiency was always higher than 80%. Intra- and inter-assay precision was lower than 15%. The suitability of the methods was tested with six urine and hair specimens from patients treated with acetazolamide, dorzolamide, or brinzolamide for ocular diseases or systemic hypertension. Average urine concentrations were 266.32 ng/ml for dorzolamide and 47.61 ng/ml for N-deethyl-dorzolamide (n = 3), 109.27 ng/ml for brinzolamide and 1.02 ng/ml for O-desmethyl-brinzolamide (n = 2), and finally, 12.63 ng/ml for acetazolamide. Average hair concentrations were 5.94 ng/mg for dorzolamide and 0.048 ng/mg for N-deethyl-dorzolamide (n = 3), 3.26 ng/mg for brinzolamide (n = 2), and 2.3 ng/mg for acetazolamide (n = 1). The developed method was simple and fast both in the extraction procedures making it eligible in high-throughput analysis for clinical forensic and doping purposes.

Population pharmacokinetic and pharmacodynamic modeling of acetazolamide in peritoneal dialysis patients and healthy volunteers.

PURPOSE: To characterize the pharmacokinetics (PK) and pharmacodynamics (PD) of acetazolamide (ACTZ) in peritoneal dialysis patients, ACTZ 500 mg was administered intravenously to 7 healthy subjects (HV) and 8 peritoneal dialysis patients (CAPD). METHODS: Population PK/PD modeling was performed with ACTZ serum (total and unbound), urine and dialysate concentrations, intra-ocular pressure (IOP) and covariates. A multi-compartment PK model (accounting for non-linear protein binding) and an inhibitory Emax (maximal change in IOP) PD model were selected. RESULTS: As expected, renal clearance (which almost equals total body clearance) was severely decreased in CAPD (1.2 vs 80.3 L/h) and the elimination half-life of total ACTZ was prolonged (20.6 vs 3.4 hours). The protein binding was significantly altered with a mean free fraction 4.2% in HV and 8.6% in CAPD. Moreover protein binding of ACTZ was concentration dependent in both HV and CAPD. Despite a higher free fraction of ACTZ, the Emax was lower in CAPD: 4.4±1.4 vs 7.4±2.8 mmHg. CONCLUSION: Both PK and PD are significantly altered in dialysis patients.

The metabolism of methazolamide - identification of metabolites in guinea pig urine.

The in vivo metabolism of methazolamide, a carbonic anhydrase inhibitor, was studied using guinea pigs as the animals. (14)C-Labeled methazolamide was synthesized. Eighty percent of intraperitoneally injected radioactivity was recovered from urine and feces within 24 hours. HPLC analysis on a C(18) column detected 2 radioactive metabolites (Peaks A and B). The Peaks A and B were isolated from the urine of the animals dosed with non-radioactive methazolamide.They were purified on the C(18) column. Their chemical structure was revealed by UV-absorbance spect a and LC/MS, and confirmed by comparing it with that of chemically synthesized compound. They were a glucuronide, (2-acetylimino-3-methyl-Δ(4)-1,3,4-thiadiazol-5-yl)-1-thio-ß-D-glucopyranosiduronic acid, and a sulfonic acid, N-[3-methyl-5-sulfo-1,3,4-thiadiazol-2(3H)-ylidene]acetamide.

Sample preparation and RPHPLC determination of diuretics in human body fluids.

This article describes reverse phase high-performance liquid chromatography (RPHPLC) methods for determination of diuretics in different human body fluids (whole blood, plasma, serum or urine). Sample preparation procedures, including solid-phase extraction, liquid-liquid extraction, dilution, precipitation as well as automated RPHPLC procedures, are discussed in order to present the advantages and disadvantages of each type of sample preparation. Also, values of analytical recovery of each procedure used for sample preparation are summarized. The most important RPHPLC parameters (detection mode, stationary phase, mobile phase, sensitivity, etc.) are also summarized and discussed.

Blood disposition and urinary excretion kinetics of methazolamide following oral administration to human subjects.

The pharmacokinetic disposition of methazolamide (MTZ) was studied in five healthy volunteers following administration of a single oral dose. Drug concentrations in blood, plasma, and urine were measured by HPLC. Over the range of plasma concentrations observed in vivo, MTZ free fraction (measured by ultrafiltration) was 0.28. Being a carbonic anhydrase inhibitor, MTZ would be expected to distribute into, and be sequestered by, red blood cells. For this reason, MTZ disposition was characterized utilizing blood concentrations as the reference. Using a two-compartment model, a series of differential equations were simultaneously fitted to blood concentrations and urinary excretion data generating estimates for k10 (0.035 +/- 0.019 h(-1)), k12 (0.200 +/- 0.036 h(-1)), k21 (0.077 +/- 0.046 h(-1)), k(a) (0.304 +/- 0.064 h(-1)), Vc (1.1 +/- 0.18 L) and f(r) (fraction excreted renally, 0.61 +/- 0.14). Total blood clearance was 0.037 +/- 0.020 L h(-1). The model estimate of elimination half-life (126 +/- 61 h) was consistent with drug binding to a high affinity carbonic anhydrase isozyme in the erythocyte. Estimates of MTZ renal clearance and renal excretion ratio were 0.021 +/- 0.010 L h(-1) and 0.16 +/- 0.06, respectively. Overall, the prolonged elimination of MTZ from the blood is the result of extensive erythrocyte distribution and tubular reabsorption by the kidney.

Urinary excretion of acetazolamide in healthy volunteers after short- and long-term exposure to high altitude.

Acetazolamide is recommended for the prophylaxis of acute mountain sickness symptoms which sets in on climbing to high altitudes (H) above 2,500 m. It is primarily excreted unchanged in urine. In a previous study, we reported on the changes in urinary excretion of meperidine and its metabolite normeperidine on exposure to high altitude. In this study, we investigated the effect on urinary excretion of acetazolamide. The study was carried out in three groups of 12 healthy male volunteers each: at sea level (group L), these same volunteers the day after arrival at high altitude of 4,360 m (group HA), and subjects residing for approximately 10 months at high altitude (group HC). Urine was collected for the periods of 0-2, 2-4, 4-8, 8-12, 12-24 and 24-36 h after peroral administration of a single 250 mg dose. Urinary pH was measured and the concentrations of acetazolamide were determined. There were no significant changes observed in the amount of acetazolamide excreted in urine over 36 h. The urinary pH ranged from 4.5 to 7.8 for L, from 4.2 to 6.9 for HA and from 3.1 to 6.7 for HC. The Fel (fraction eliminated unchanged in urine) was calculated from the amount excreted in 36 h in urine and dose, assuming a bioavailability of 1 based on literature data. No significant changes in Fel were seen.

Ocular absorption, blood levels, and excretion of dorzolamide, a topically active carbonic anhydrase inhibitor.

Dorzolamide is a powerful inhibitor of carbonic anhydrase (CA) II that penetrates the sclera and cornea to reach the ciliary process and lowers formation of HCO3 and aqueous humor. The usual dose applied to the eye in treatment of glaucoma is 1 drop (30 microL of 2% solution) every 8 hr to each eye, or a total daily dose of 4 mg. On this regime, the red cells accumulated drug over a period of 8 days, reaching a value of 20-25 microM, which corresponds to the concentration of CA II in human red cells. This drug concentration persisted throughout the 18 months of application. The plasma concentration was 0.034 microM, or 1/700 that of the red cells. This plasma concentration corresponds to that calculated from the dilution of administered drug into body water. The data are well fitted into the equilibrium expression for KI of dorzolamide against CA II at 37 degrees C, as 8 x 10(-9) M. The red cells also contain a small amount (5 microM) of the N-des-ethyl metabolite, probably reflecting its modest binding to CA I. In the initial 8-day drug period, virtually none appeared in the urine since CA II sites were being filled. At steady state, renal excretion was 1.3 mg/day and the renal clearance 90 ml/min. These excretion numbers include the small (20%) amount of the des-ethyl metabolite of dorzolamide. The relation of these data to lowering of intraocular pressure is clear. By the systemic route, an inhibitor such as acetazolamide is effective when free drug concentration in plasma is 2.5 microM. In the case of topical drugs, as shown here, the plasma concentration is some 100 x lower, but the concentration in ciliary process is 2-10 microM, comparable to that following systemic drugs (1). In conclusion, the concentration in plasma (reflecting free drug) of dorzolamide is about 1/200 of that needed for systemic effects as seen following acetazolamide or methazolamide. Thus, there is a clear pharmacological basis for the lack of any physiological effects of ocular dorzolamide, except on the eye itself.

Absence of metabolic effects of the topical carbonic anhydrase inhibitors MK-927 and sezolamide during two-week ocular administration to normal subjects.

Potential systemic effects of the racemic carbonic anhydrase inhibitor MK-927 and its S-enantiomer, sezolamide hydrochloride, after topical ocular administration were investigated in a double-masked, randomized, placebo-controlled study in 16 healthy volunteers. A controlled diet was started 4 days before initiation of treatment and continued throughout the study. For 14 days six volunteers received bilaterally one drop of 2% MK-927 (1.2 mg) q.i.d., six received one drop of 1.8% sezolamide (1.1 mg) q.i.d., and four received the common vehicle q.i.d. Blood and urine electrolytes and acid-base profiles were measured before and on days 1, 7, and 14 of treatment, and 24-hour urine samples were collected daily. All values were compared with those on the pretreatment day. Taking the circadian variations of the parameters into account, no significant treatment effect was observed in either the daily profiles or the 14-day cumulative sodium, potassium, and citrate excretions. Because the usual variability of the measured biologic parameters has been reduced markedly by the stringent requirements of this study, it can be concluded that the induction of clinically significant metabolic changes by topically administered MK-927 or sezolamide is unlikely.

Development of direct stereoselective and non-stereoselective assays in biological fluids for the enantiomers of a thieno[2,3-b]thiopyran-2-sulfonamide, a topically effective carbonic anhydrase inhibitor.

A stereoselective assay for the optical isomers [(S) and (R)] of 5,6-dihydro-4-[(2-methylpropyl)amino]-4H-thieno[2,3-b]thiopyran-2- sulfonamide-7,7-dioxide in human whole blood has been developed. The assay is based on direct enantiomer separation on a chiral stationary phase column of bovine serum albumin attached to silica. The effect of pH, ionic strength, column length and organic modifier on chiral separation has been studied. The assay methodology, based on high-performance liquid chromatography (HPLC) with ultraviolet (UV) detection (252 nm), has been fully validated in the concentration range 25-250 ng/ml of each enantiomer. Since no interconversion of the isomers was observed in vivo for the clinical studies involving the single (S)-enantiomer, a more sensitive (2.5 ng/ml), non-stereoselective assay has been developed. This method, also based on HPLC with UV detection, was fully validated in whole blood, plasma and urine in the concentration range 2.5-100 ng/ml. The details of these assays, together with some representative data from a pilot human study, are also presented.