Lack of effect of a high-fat meal on the bioavailability of 17 beta-estradiol/norgestimate in healthy postmenopausal women

The effect of a high-fat meal on the absorption and pharmacokinetics of 17 beta-estradiol (E2), estrone (E1), estrone sulfate (E1S), and 17-deacetylnorgestimate (17d-NGM) were determined in this two-way complete crossover study of a single dose of E2/NGM (2 mg/180 micrograms) in 24 postmenopausal women. Equal numbers of subjects were randomly assigned to two treatment sequences indicated by the order of fed and fasting treatments. Serial blood samples were collected before and after dosing and assayed using validated methods. Food had no effect on the pharmacokinetics of E2, the pharmacologically active estrogen species. Food increased the rates of formation of E1 and E1S and slowed the formation of 17d-NGM. However, because E1 and E1S are pharmacologically less active metabolites of E2, and since the pharmacokinetic alterations in 17d-NGM were observed over a short time period, these results are probably of no clinical relevance. The extent of formation of all analytes, as measured by AUC, was not affected by food. In conclusion, administration of a tablet containing 17 beta-estradiol/norgestimate (2 mg/180 micrograms) was safe and well tolerated by healthy postmenopausal women and may be given without regard to the timing of meals in relation to dosing.     

The effect of probenecid on the renal elimination of cimetidine

It is generally assumed that the systems involved in the transport of organic cations and organic anions in the renal proximal tubule are substrate selective (i.e., organic anions do not inhibit organic cation transport and vice versa). However, recent data obtained in vitro have suggested that the organic anion probenecid inhibits the renal transport of the organic cation cimetidine. We addressed the question of whether this interaction is biologically relevant in human beings. The study involved a two-treatment, randomized crossover design. Six healthy male subjects were given an intravenous infusion of 300 mg cimetidine alone as one treatment and, as the other treatment, received multiple oral doses of probenecid before receiving the cimetidine infusion. The renal clearance of cimetidine and inulin was determined in each period. There were no significant differences between treatments in cimetidine plasma concentrations, apparent volume of distribution, systemic clearance, half-life, amount of drug excreted unchanged in the urine, or nonrenal clearance. Probenecid significantly decreased the renal clearance of cimetidine by decreasing both the filtration clearance and the net secretory clearance. These effects were most evident in the first 1/2 to 1 hour after cimetidine administration, when probenecid levels in plasma and renal tissue would have been the highest. Because there was no effect of probenecid on cimetidine plasma concentrations, this interaction is not clinically relevant to the therapeutic use of these two compounds. However, the study demonstrates that renal interactions between organic cations and organic anions can occur in human beings. The mechanism of this interaction and the implications to other drug combinations are being explored.     

Pharmacokinetic profile of levofloxacin following once-daily 500-milligram oral or intravenous doses.

The pharmacokinetics of once-daily oral levofloxacin (study A) or intravenous levofloxacin (study B) in 40 healthy male volunteers were investigated in two separate randomized, double-blind, parallel-design, placebo-controlled studies. Levofloxacin at 500 mg or placebo was administered orally or intravenously as a single dose on day 1; daily oral or intravenous dosing resumed on days 4 to 10. In a third study (study C), the comparability of the bioavailabilities of two oral and one intravenous levofloxacin formulations were investigated with 24 healthy male subjects in an open-label, randomized, three-way crossover study. Levofloxacin at 500 mg as a single tablet or an intravenous infusion was administered on day 1; following a 1-week washout period, subjects received the second regimen (i.e., the other oral formulation or the intravenous infusion); the third and final regimen was administered following a 1-week washout period. The concentrations of drug in plasma and urine were measured by validated high-pressure liquid chromatography methods. Pharmacokinetic parameters were estimated by noncompartmental methods. In both study A (oral levofloxacin) and study B (intravenous levofloxacin), steady state was attained within 48 h after the start of the multiple dosing on day 4. Levofloxacin pharmacokinetics were linear and predictable for the single and multiple 500-mg, once-daily oral and intravenous dosing regimens, and the values of the pharmacokinetic parameters for the oral and intravenous administrations were similar. Study C indicated that levofloxacin was rapidly and completely absorbed from the oral tablets, with mean times to the maximum concentration of drug in serum of approximately 1.5 h and mean absolute bioavailability of > or =99%. These results support the interchangeability of the oral and intravenous routes of levofloxacin administration.     

Topiramate and phenytoin pharmacokinetics during repetitive monotherapy and combination therapy to epileptic patients

PURPOSE: To evaluate the potential pharmacokinetic interactions between topiramate (TPM) and phenytoin (PHT) in patients with epilepsy by studying their pharmacokinetics (PK) after monotherapy and concomitant TPM/PHT treatment. METHODS: Twelve patients with epilepsy stabilized on PHT monotherapy were enrolled in this study, with 10 and seven patients completing the phases with 400 and 800 mg TPM daily doses, respectively. TPM was added at escalating doses, and after stabilization at the highest tolerated TPM dose, PHT doses were tapered. Serial blood and urine samples were collected for PK analysis during the monotherapy phase or the lowest PHT dose after taper and the concomitant TPM/PHT phase. Potential metabolic interaction between PHT and TPM also was studied in vitro in human liver microsomal preparations. RESULTS: In nine of the 12 patients, PHT plasma concentrations remained stable, with a mean (+/-SD) area under the curve (AUC) ratio (combination therapy/monotherapy) of 1.13 +/- 0.17 (range, 0.89-1.23). Three patients had AUC ratios of 1.25, 1.39, and 1.55, respectively, and with the addition of TPM (800, 400, and 400 mg daily, respectively), their peak PHT plasma concentrations increased from 15 to 21 mg/L, 28 to 36 mg/L, and 27 to 41 mg/L, respectively. Human liver microsomal studies with S-mephenytoin showed that TPM partially inhibited CYP2C19 at very high concentrations of 300 microM (11% inhibition) and 900 microM (29% inhibition). Such high plasma concentrations would correspond to doses in humans that are 5 to 15 times higher than the recommended dose (200-400 mg). TPM clearance was approximately twofold higher during concomitant TPM/PHT therapy CONCLUSIONS: This study provides evidence that the addition of TPM to PHT generally does not cause clinically significant PK interaction. PHT induces the metabolism of TPM, causing increased TPM clearance, which may require TPM dose adjustments when PHT therapy is added or is discontinued. TPM may affect PHT concentrations in a few patients because of inhibition by TPM of the CYP2C19-mediated minor metabolic pathway of PHT.     

Renal Transport of Drugs: An Overview of Methodology with Application to Cimetidine

The development of new methods to study transport processes in renal epithelia has greatly enhanced our knowledge of the mechanisms involved in the transport of a number of endogenous compounds. More recently, these methods have been applied to study mechanisms of specific drug transport. This article is intended to provide an overview of the various methods used to study renal elimination of compounds. References to more detailed reviews of the individual methods are provided. Studies of the renal transport of cimetidine, a histamine H₂-receptor antagonist, are presented to illustrate the application of these methods to the study of specific drugs. Methods such as clearance techniques and the Sperber chicken preparation used to study renal elimination of compounds in whole animals are briefly described. Techniques to identify the site of renal transport including stop flow, isolated perfused tubules, and micropuncture methods are discussed and references to more technical reviews are cited. The more recently developed methods of isolated membrane vesicles for studying transport across the individual polar membranes of the proximal tubule are discussed along with the relevant studies of the use of these membranes in elucidating the mechanisms involved in the renal transport of cimetidine. Finally, the use of cultured renal epithelial cell lines in studying renal transport is described. Knowledge of drug transport mechanisms in the kidney is important both in drug targeting to the kidney and in understanding the pharmacokinetics of renally eliminated drugs. As exemplified by the studies with cimetidine, only by combining the data from experiments using diverse methodology can the mechanisms involved in the renal excretion of compounds be delineated. With the use of existing methods and the development of new technologies, many of the questions related to drug transport mechanisms can be addressed.     

A capillary gas chromatographic assay with nitrogen phosphorus detection for the quantification of topiramate in human plasma, urine and whole blood

An accurate and robust method involving liquid liquid extraction and capillary gas chromatographic (GC) assay with nitrogen phosphorus detection (NPD) was developed and validated for the quantitative determination of topiramate [2,3:4,5-bis-O-(-1-methylethylidene)-beta-D-fructopyranose sulfamate], Topamax, an anticonvulsant drug, in human plasma, urine, and whole blood. The galactopyranose analog of topiramate was used as the internal standard. A DB-5, fused silica capillary column (J&W Scientific, Folsom, CA) was used, yielding typical retention times of 4.95 min for topiramate and 5.32 min for the internal standard in human plasma. The assay involved organic extraction with methyl t-butyl ether (MTBE) from base, a back extraction into acid and a second extraction in MTBE. The organic solvent was evaporated, and the residue was redissolved and injected for analysis. The standard curve was validated from 0.5 to 50 microg/ml(-1) for human plasma and whole blood, and from 1.0 to 50 microg/ml(-1) for urine. Peak area ratios of drug to internal standard were determined and used to construct a standard curve. The resulting chromatograms showed no endogenous interfering peaks with the respective blank human fluids. Chromatograms corresponding to topiramate and the internal standard produced sharp peaks that were well resolved. This assay showed precision and accuracy of < or = 5%. Two minor human metabolites of topiramate did not interfere with the assay. This assay was successfully applied to determine the pharmacokinetics of topiramate during the development of this drug.