E.W.J. van Ewijk-Beneken Kolmer

Determination of nevirapine, an HIV-1 non-nucleoside reverse transcriptase inhibitor, in human plasma by reversed-phase high-performance liquid chromatography.

A sensitive and rapid high-performance liquid chromatography method has been developed to measure the levels of the HIV-1 non-nucleoside reverse transcriptase inhibitor nevirapine in human plasma. The sample pre-treatment consists of a protein precipitation with perchloric acid. A Hypersil ODS column is used at ambient temperature and a wavelength of 280 nm is used for ultraviolet detection. The mobile phase contains acetonitrile and a 60 mM phosphate buffer pH 4.5 (30:70, v/v). The detection limit of the method is 0.05 mg/l using 150 microl of plasma. The lower and upper limit of quantitation are 0.1 mg/l and 10 mg/l, respectively. The average recovery of nevirapine is 101.8% with a variation of 4.6%. The average inter-assay precision is 2.4%, the average intra-assay precision 2.9% and the average accuracy 97%.

Isolation, identification and determination of sulfamethoxazole and its known metabolites in human plasma and urine by high-performance liquid chromatography

From human urine the following metabolites of sulfamethoxazole (S) were isolated by preparative HPLC: 5-methylhydroxysulfamethoxazole (SOH), N4-acetyl-5-methylhydroxysulfamethoxazole (N4SOH) and sulfamethoxazole-N1-glucuronide (Sgluc). The compounds were identified by NMR, mass spectrometry, infrared spectrometry, hydrolysis by beta-glucuronidase and ratio of capacity factors. The analysis of S and the metabolites N4-acetylsulfamethoxazole (N4), SOH, N4-hydroxysulfamethoxazole (N4OH), N4SOH, and Sgluc in human plasma and urine samples was performed with reversed-phase gradient HPLC with UV detection. In plasma, S and N4 could be detected in high concentrations, while the other metabolites were present in only minute concentrations. In urine, S and the metabolites and conjugates were present. The quantitation limit of the compounds in plasma are respectively: S and N4 0.10 micrograms/ml; N4SOH 0.13 micrograms/ml; N4OH 0.18 micrograms/ml; SOH 0.20 micrograms/ml; and Sgluc 0.39 microgram/ml. In urine the quantitation limits are: N4 and N4OH 1.4 micrograms/ml; S 1.5 micrograms/ml; N4SOH 1.9 micrograms/ml; SOH 3.5 micrograms/ml; and Sgluc 4.1 micrograms/ml. The method was applied to studies with healthy subjects and HIV positive patients.

Direct gradient reversed-phase high-performance liquid chromatographic determination of salicylic acid, with the corresponding glycine and glucuronide conjugates in human plasma and urine

A gradient reversed-phase HPLC analysis for the direct measurement of salicylic acid (SA) with the corresponding glycine and glucuronide conjugates in plasma and urine of humans was developed. The glucuronides were isolated by preparative HPLC from human urine samples. The concentration of the glucuronides in the isolated fraction were determined after enzymatic hydrolysis. Salicylic acid acyl glucuronide (SAAG) was not present in plasma. No isoglucuronides were present in acidic and alkaline urine of the volunteer. The limits of quantitation in plasma are: SA 0.2 microgram/ml, salicyluric acid (SU) 0.1 microgram/ml, salicylic acid phenolic glucuronide (SAPG) 0.4 microgram/ml and salicyluric acid phenolic glucuronide (SUPG) 0.2 microgram/ml. The limit of quantitation in urine is for all compounds 5 micrograms/ml. Salicylic acid acyl glucuronide is stable in phosphate buffer pH 4.9 during 8 h at 37 degrees C; thereafter it declines to 80% after 24 h. The subjects urine was therefore acidified by the oral intake of 4 x 1.2 g of ammonium chloride/day. With acidic urine, hardly any salicylic acid is excreted unchanged (0.6%). It is predominantly excreted as salicyluric acid (68.7%).

Interindividual variation in the capacity-limited renal glucuronidation of probenecid by humans

A dose of 1,000 mg probenecid was administered orally to 14 human volunteers in order to quantify the maximal rate of formation and excretion of probenecid acyl glucuronide in the urine. Probenecid showed dose-dependent pharmacokinetics. Plasma protein binding of probenecid was high, being somewhat higher in males (90.7±1.4%) than in females (87.9±1.4%; p=0.0019). It was shown that probenecid is metabolized by cytochrome P-450 into at least two phase I metabolites. Each of the metabolites accounted for less than 12% of the dose administered; the main metabolite probenecid acyl glucuronide, representing 42.9±13.2% of the dose, was only present in urine and not in plasma. The renal excretion rate-time profile of probenecid acyl glucuronide showed a plateau value in the presence of an acidic urine pH. This plateau value was maintained for about 10 h at the dose of 1,000 mg. The height of the plateau value depended on the individual and varied between 250 and 800μg/min (15–50 mg/h). It was inferred that probenecid acyl glucuronide is formed in the kidney during blood-to-lumen passage through the tubular cells. We conclude that the plateau value in the renal excretion rate of probenecid glucuronide reflects itsVmax of formation.

CAPACITY LIMITED RENAL GLUCURONIDATION OF PROBENECID BY HUMANS : A PILOT VMAX-FINDING STUDY

Probenecid shows dose-dependent pharmacokinetics. When in one volunteer the dose is increased from 250 to 1,500 mg orally, thet1/2 increased from 3 to 6 h. TheCmax was 14μg/ml with a dosage of 250 mg, 31μg/ml with 500 mg, 70μg/ml with 1,000 mg and 120μg/ml with 1,500 mg. Thetmax remained 1 h for all four dosages. The AUC/dose ratio increased with the dose, indicating nonlinear elimination. The total body clearance declined from 64.5 ml/min for 250 mg to 26.0 ml/min for 1,500 mg. The renal clearance of probenecid remained constant, 0.6–0.8 ml/min. Protein binding of probenecid is high (91%) and independent of the dose. The phase I metabolites show lower protein binding values (34–59%). The protein binding of probenecid glucuronidein vitro (spiked plasma) is 75%. Probenecid is metabolized by cytochrome P-450 to three phase I metabolites. Each of the metabolites accounts for less than 10% of the dose administered; the percentage recovered in the urine is independent of the dose. The main metabolite probenecid glucuronide is only present in urine and not in plasma. The renal excretion rate-time profile of probenecid glucuronide shows a plateau value of approximately 700μg/min (46 mg/h) with acidic urine pH. The duration of this plateau value depends on the dose: 2 h at 500 mg, 10 h at 1,000 mg and 20 h at 1,500 mg. It is demonstrated that probenecid glucuronide must be formed in the kidney during its passage of the tubule. The plateau value in the renal excretion rate of probenecid value reflects itsVmax of formation.

Direct-gradient high-performance liquid chromatographic analysis and preliminary pharmacokinetics of flumequine and flumequine acyl glucuronide in humans: effect of probenecid

A gradient high-performance liquid chromatographic analysis for the direct measurement of flumequine, with its acyl glucuronide, in plasma and urine of humans has been developed. In order to prevent hydrolysis and isomerization of flumequine acyl glucuronide, the samples were acidified by the oral intake of four 1.2-g amounts of ammonium chloride per day. In contrast to the acyl glucuronides of non-steroidal anti-inflammatory drugs, flumequine and its acyl glucuronide were stable in urine of pH 5.0-8.0. Flumequine acyl glucuronide is unstable at pH 1.5. In acidic urine (pH 5-6), almost no flumequine is excreted unchanged (1%): it is excreted chiefly as acyl glucuronide (84.2%). Probenecid co-medication reduces the renal excretion rate of flumequine acyl glucuronide from 662 to 447 micrograms/min (p = 0.00080), but not the percentage of glucuronidation.

Drug-drug interactions between raltegravir and pravastatin in healthy volunteers.

Background:To evaluate the potential drug-drug interaction between raltegravir and pravastatin. Methods:This was an open-label, randomized, 3-period, cross-over, single-centre trial in 24 healthy volunteers. Subjects received the following treatments: pravastatin 40 mg every day for 4 days, raltegravir 400 mg twice a day for 4 days, and pravastatin 40 mg every day + raltegravir 400 mg twice a day for 4 days. The treatments were separated by washout periods of 10 days. On day 4 of each treatment period, blood samples for pharmacokinetics were collected throughout a 24-hour period. Results:Geometric mean ratios (90% confidence interval) for pravastatin + raltegravir versus pravastatin alone were 0.96 (0.83 to 1.11) for AUC0-24 and 1.04 (0.85 to 1.26) for Cmax. The mean low-density lipoprotein cholesterol decrease after 4 days of pravastatin was 0.42 mmol/L both in the presence and the absence of raltegravir. The geometric mean ratio (90% confidence interval) AUC0-12, Cmax, and C12 for raltegravir + pravastatin versus raltegravir alone were 1.13 (0.77 to 1.65), 1.31 (0.81 to 2.13), and 0.59 (0.39 to 0.88), respectively. Conclusions:Raltegravir did not influence the pharmacokinetics or the short-term lipid-lowering effects of pravastatin, whereas pravastatin increased the Cmax but decreased the C12 of raltegravir. The effects of pravastatin on raltegravir pharmacokinetics are not likely to be clinically relevant.

Pharmacokinetics of sulfamethoxazole with its hydroxy metabolites and N4-acetyl-,N1-glucuronide conjugates in healthy human volunteers.

SummaryThe aim of this investigation was to assess the pharmacokinetics of sulfamethoxazole (S) with its hydroxy metabolites (SOH, N4SOH, N4OH) and N4-acetyl- (N4) and N1-glucuronide (Sgluc) conjugates in 7 human volunteers after an oral dose of 800mg using a reversed phase gradient high-pressure liquid chromatography (HPLC) with UV detection. Sulfamethoxazole was rapidly and completely absorbed and metabolised to 5 metabolites. The plasma half-life (t½) of elimination varied for the parent drug and its metabolites between 9.7 and 15 hours. The protein binding of S (67.2%) increased when the compound was acetylated (88%), and decreased when it was oxidised at the 5-position (40%). Glucuronidation at the N1-position reduced the protein binding to 20%. The main metabolite in urine was N4 (43.5 ± 5.6%), followed by S (14.4 ± 3.4%). The percentages of the Sgluc (9.8 ± 2.6%), N4SOH (5.3 ± 1.0%), and SOH (3.0 ± 1.0%) did not differ statistically (p = NS). Only 2 to 3% of the N-hydroxylamine metabolite (N4OH) was excreted. The renal clearance values were: Sgluc 176 ± 33 ml/min, SOH 96.1 ± 23.7 ml/min, N4SOH 51.2 ± 10.4 ml/min, N4 35.2 ± 5.6 ml/min and S 2.7 ± 0.9 ml/min. The pharmacokinetic behaviour of the N1-glucuronide was reported for the first time. If one of the metabolites is responsible for the occurrence of side effects, then all metabolites must be included in this analysis.

Probenecid inhibits the glucuronidation of indomethacin and O-desmethylindomethacin in humans. A pilot experiment.

Indomethacin is metabolized in humans byO-demethylation, and by acyl glucuronidation to the l-O-glucuronide. Indomethacin, its metabolite, and their conjugates can be measured directly by gradient high-pressure liquid chromatographic analysis without enzymic deglucuronidation. The pharrnacokinetic profile of indomethacin and some preliminary pharmacokinetic parameters of indomethacin obtained from one human volunteer are given. In plasma only the parent drug indomethacin is present, while in urine the acyl and ether glucuronides are present in high concentrations. This confirms other reports that indomethacin andO-desmethylindomethacin may be glucuronidated in the kidney. Probenecid is a known substrate for renal glucuronidation. If indomethacin is glucuronidated in the human kidney like probenecid, then this glucuronidation might be reduced or inhibited under probenecid co-medication. This pilot experiment shows that probenecid reduced the acyl glucuronidation of indomethacin by 50% and completely inhibited the formation ofO-desmethylindomethacin acyl and ether glucuronide.

Direct gradient reversed-phase HPLC analysis and preliminary pharmacokinetics of nalidixic acid, 7-hydroxymethylnalidixic acid, 7-carboxynalidixic acid, and their corresponding glucuronide conjugates in humans.

A gradient reversed-phase high pressure liquid chromatographic analysis was developed for the direct measurement of nalidixic acid with its acyl glucuronide, 7-hydroxymethylnalidixic acid with its acyl and ether glucuronides, and 7-carboxynalidixic acid in human plasma and urine. The glucuronides and 7-carboxynalidixic acid were not present in plasma after an oral dose of 1,000 mg nalidixic acid. The acyl glucuronides of 7-carboxynalidixic acid were not present in plasma and urine. The acyl glucuronides are stable in urine at pH 5.0–5.5. The subjects urine must therefore be acidified by the oral intake of 4×1 g of ammonium chloride per day. With acidic urine, hardly any nalidixic acid was excreted unchanged (0.2%). It was excreted as acyl glucuronide (53.4% of dose), 7-hydroxymethylnalidixic acid (10.0%), the latters acyl glucuronide (30.9%), and 7-carboxynalidixic acid (4.2%).