Enzyme induction observed in healthy volunteers after repeated administration of rifapentine and its lack of effect on steady-state rifapentine pharmacokinetics: part I.

OBJECTIVE: To determine the effects of rifapentine on hepatic mixed function oxidase activity and to assess the effect of enzyme induction on the steady-state pharmacokinetics of rifapentine. STUDY DESIGN: Twenty-three healthy males were randomized to receive two of the following treatments in a two-period, four-treatment, incomplete block, crossover design: single daily oral rifapentine doses of 150 mg (group A), 300 mg (group B), or 600 mg (group C) on study days 1 and 4-10, or single oral rifapentine 600 mg doses given every 3 days for a total of four doses (group D). Serial blood samples were collected after the first and last rifapentine dose and assayed for rifapentine and its active metabolite, 25-desacetyl-rifapentine. Urine was collected for determination of cortisol and 6-hydroxycortisol concentrations. RESULTS: The ratio of 6beta-hydroxycortisol:cortisol increased during rifapentine administration (+229%, +317%, and +357% on day 10 for groups A, B, and C, respectively). Ratios returned to baseline 2 weeks after the last dose. The per cent increase in the ratio of 6beta-hydroxycortisol:cortisol following daily doses (+357%) was much higher compared with every 72-hour dosing (+236%). Single-dose and steady-state comparisons of AUCss(0-24) and AUC(0-->infinity) for both rifapentine and 25-desacetyl-rifapentine were similar (P = NS) at corresponding doses of rifapentine. Mean t(1/2) at steady-state was 84-98% of corresponding single-dose values. CONCLUSION: Rifapentine is a potent inducer of CYP3A activity. However, single-dose pharmacokinetics of rifapentine predict steady-state exposure, indicating no autoinduction of rifapentine metabolism with repeated administration. Enzyme activity returns to predose levels within 2 weeks of the last daily dose of rifapentine.

Disposition and metabolism of 14C-rifapentine in healthy volunteers.

Rifapentine is a long-acting cyclopentyl-derivative of rifampin. This study was designed to investigate the mass balance and biotransformation of 14C-rifapentine in humans. Four healthy male volunteers received a single 600-mg oral dose of 14C-rifapentine in a hydroalcoholic solution. Whole blood, urine, and fecal samples were collected before and at frequent intervals after drug administration. Amount of radioactivity recovered in urine and feces was assessed for up to 18 days postdose. Metabolite characterization in urine and feces was conducted using high-performance liquid chromatography with radiometric detection and liquid chromatography/mass spectroscopy. The total recovery of radioactive dose was 86.8%, with the majority of the radioactive dose recovered in feces (70.2%). Urine was a minor pathway for excretion (16.6% of the dose recovered). More than 90% of the excreted radioactivity was profiled as 14C chromatographic peaks and 50% was structurally characterized. These characterized compounds found in feces and urine were rifapentine, 25-desacetyl-rifapentine, 3-formyl-rifapentine, and 3-formyl-25-desacetyl-rifapentine. The 25-desacetyl metabolite, formed by esterase enzymes found in blood, liver, and other tissues, was the most abundant compound in feces and urine, contributing 22% to the profiled radioactivity in feces and 54% in urine. The 3-formyl derivatives of rifapentine and 25-desacetyl-rifapentine, formed by nonenzymatic hydrolysis, were also prominent in feces and, to a lesser extent, in urine. In contrast to the feces and urine, rifapentine and 25-desacetyl-rifapentine accounted for essentially all of the plasma radioactivity (99% of the 14C area under the concentration-time curve), indicating that 25-desacetyl-rifapentine is the primary metabolite in plasma. It appears, therefore, that the nonenzymatic hydrolysis of rifapentine to 3-formyl byproducts occurs primarily in the gut and the acidic environment of the urine.

Drug interactions at the renal level. Implications for drug development.

The kidney plays a major role in the elimination of drugs. The purpose of this paper is to: (i) review the mechanisms of renal elimination; (ii) identify potential mechanisms for renal drug interactions; (iii) review in vitro and in vivo animal models for studying renal elimination mechanisms and identifying potential drug-drug interactions; (iv) review experimental designs used in identifying drug-drug interactions in humans with an emphasis on gaining information regarding the mechanism of the interaction; and (v) make recommendations regarding the potential for renal drug interactions in drug development. It is concluded that clinically significant drug interactions resulting in toxicity because of some mechanism at the renal level appear to be relatively rare and that in vitro screening should not be done on all drugs during drug development. Five potential mechanisms exist for drug interactions at the renal level: (i) a displacement of bound drug resulting in an increase in drug excretion via an increase in glomerular filtration; (ii) competition at a tubular secretion site resulting in a decrease in drug excretion; (iii) competition at the tubular reabsorption site resulting in an increase in drug excretion; (iv) a change in urinary pH and/or flow that may increase or decrease drug excretion depending on the pKa of the drug; and (v) inhibition of renal drug metabolism. The most well known renal drug interaction is competitive inhibition of tubular secretion, ultimately leading to an increase in plasma drug concentration. Only when renal clearance is a major contributor to the total clearance (> 30%) and plasma concentrations are greater than the Michaelis-Menten transport constant does the potential exist for clinically significant renal drug-drug interactions because only then does nonlinear pharmacokinetics become evident. The potential for drug interactions is small when renal clearance is less than 20 to 30% of the total clearance and/or when plasma concentrations are less than the Michaelis-Menten transport constant, unless the drug has a narrow therapeutic window.

Trends in the stage of cancer at the time of diagnosis.

The stage of cancers at the time of diagnosis for 10 major sites of disease from patients treated at two Medical College of Wisconsin teaching hospitals was analyzed from tumor registry data and compared from the years 1983, 1987, and 1991. A trend toward earlier stages of cancer of major sites was noted, with patients having in situ or localized disease increasing from 35% in 1983 to 48% in 1991. Patients with breast cancer demonstrated the strongest trend, with 44% of the cases representing in situ or localized disease in 1983 compared to 61% in 1991 (p = 0.03). A shift toward earlier stage of cancer at diagnosis was also noted for other major sites including: lung, trachea and bronchus; colon and rectum; and prostate cancers. Trends toward an earlier stage of cancer may result from patient and physician education, local practice patterns, as well as proper use of screening programs. Information on such trends from hospital tumor registries may be helpful in the appropriate and efficient allocation of local health care resources.