Rimantadine pharmacokinetics in healthy subjects and patients with end-stage renal failure.

The single-dose (two 100 mg doses) pharmacokinetics of rimantadine hydrochloride were compared in eight patients with end-stage renal disease who were on hemodialysis and seven age-matched healthy subjects. Plasma and urine rimantadine concentrations were determined by a GC/MS method. The plasma half-life (43.6 vs 27.5 hours) and AUC (9.9 +/- 2.1 vs 6.0 +/- 1.6 micrograms.hr/ml) were significantly (p less than 0.05) increased in the patient population. No significant differences were noted in the maximum rimantadine concentration, time of maximum concentration, or apparent volume of distribution. Urinary excretion of unchanged rimantadine accounted for 16% of the dose in the healthy subjects. Hemodialysis did not appreciably remove rimantadine. These findings suggest that rimantadine dosage may need to be reduced in patients with end-stage renal disease but supplemental doses on dialysis days are not required.

Interferon kinetics and adverse reactions after intravenous, intramuscular, and subcutaneous injection.

Three groups of six subjects each received a single 36 X 10(6) U dose of recombinant leukocyte A interferon (rIFN-alpha A) as a 40-min infusion, an intramuscular injection, or a subcutaneous injection. Blood samples were collected at specific times after dosing for analysis of rIFN-alpha A serum concentrations by an enzyme immunoassay method, ELISA. The rIFN-alpha A was rapidly distributed and moderately eliminated (t 1/2 = 5.1 hr) after intravenous infusion. The maximum concentrations at the end of intravenous infusion were tenfold the maximum concentrations after intramuscular and subcutaneous injections. Renal tubular secretion or extrarenal elimination was suggested by clearance values of 1.8 times the glomerular filtration rate. After intramuscular and subcutaneous injection, rIFN-alpha A was absorbed slowly (time to reach maximum concentration ranged from 4 to 8 hr), which resulted in prolonged serum concentrations. Estimated bioavailability was more than 80% for both intramuscular and subcutaneous injection shares qualitatively the same adverse reactions, the reactions differ in severity and duration. The adverse effects appear to be related to route of administration of herpes labialis were also noted. There were no significant clinical laboratory abnormalities of medical concern. Although rIFN-alpha A injected by intravenous infusion or intramuscular or subcutaneous injection shares qualitatively the same adverse reactions, the reactions differ in severity and duration. The adverse effects appear to be related to route of administration.

Distribution of alpha interferon in serum and cerebrospinal fluid after systemic administration.

After intravenous infusion of recombinant leukocyte interferon (rIFN-alpha A) to four subjects with an indwelling reservoir, serial serum and cerebrospinal fluid samples were taken over 48 hr and were analyzed for interferon by an enzyme immunoassay method (ELISA). On separate occasions, 18 and 50 X 10(6) of rIFN-alpha A were infused over 10 min. Maximum serum concentrations of rIFN-alpha A ranged from 6720 to 11,000 pg/ml and from 32,900 to 43,400 pg/ml after the 18 and 50 X 10(6) U doses. There was no measurable concentration of rIFN-alpha A in the cerebrospinal fluid of subjects who received 18 X 10(6) U doses. In three of four subjects who received 50 X 10(6) U rIFN-alpha A, concentrations ranged from 17 to 70 pg/ml that were measurable no earlier than 1 hr after the start of the infusion and that in two cases were measurable throughout 24 hr.

Pharmacokinetics of rimantadine hydrochloride in patients with chronic liver disease.

Six patients with chronic liver disease and six sex-, age (+/- 5 years)-, and weight (+/- 5 kg)-matched healthy control subjects received a single dose of two 100 mg tablets rimantadine HCl. Eight additional patients with chronic liver disease who were not matched to healthy subjects received a single dose of two 100 mg tablets of rimantadine HCl. Blood and urine samples were collected and rimantadine concentrations were determined by a GCMS method. The values for maximum plasma concentration, AUC, elimination half-life, and renal clearance were not significantly different between patients and control subjects, independent of the statistical analyses (parametric and nonparametric) used. The mean apparent elimination half-life, volume of distribution, and total clearance in the matched patients with liver disease were 32 hours, 24 L/kg, and 676 ml/min, respectively. Renal clearance and the amount excreted in the urine unchanged were 63 ml/min and 10%, respectively. In conclusion, rimantadine pharmacokinetics were not appreciably altered in patients with less severe chronic liver disease.

Trimoprostil plasma concentration--gastric acid inhibition relationships: potentiation by food.

A single, oral, 1.5-mg dose of trimoprostil was taken before a standard meal and a matching placebo was taken after a standard meal by 10 subjects (group A). A second group of 10 subjects took placebo before a meal and trimoprostil after the meal (group B), while a third group took placebo both before and after the standard meal (group C). Food-stimulated gastric acid production was measured by intragastric titration for 6.5 hr after dosing. Trimoprostil taken after the meal had a greater effect on gastric acid secretion than when taken before the meal: Duration of effect was 5 to 5.5 hr in group B and 2 to 2.5 hr in group A. Blood samples were drawn and assayed for trimoprostil by gas chromatography-mass spectrometry. Mean trimoprostil plasma concentration and mean inhibition of gastric acid secretion data were fit to two models by the Hill equation. The mean plasma concentration associated with 50% inhibition of gastric acid secretion was 1.25 ng/ml. Trimoprostil plasma concentrations between 3 and 4 ng/ml were associated with 70% to 80% gastric acid inhibition. Overall, there appears to be a pharmacokinetic-pharmacologic correlation between trimoprostil plasma concentrations and inhibition of gastric acid secretion. Trimoprostil (1.5 mg) in the presence of food appears to have a therapeutic advantage, in that it decreases acid secretion longer than when taken without food and suffers no loss of bioavailability.

Clinical pharmacokinetics of interferons.

Interferons are a family of proteins shown to be effective in the treatment of viral (condylomata, acuminata) and neoplastic (hairy cell leukaemia and AIDS-related Kaposi's sarcoma) diseases. To date, the clinical utility of the interferons has been hampered by an incomplete understanding of their mechanism of action. However, there is supporting evidence that the route of administration, i.e. the pharmacokinetic behaviour, is an important treatment variable. The pharmacokinetics of interferons have been fairly well described. The decline in serum concentrations of interferon is rapid after intravenous administration. The volume of distribution approximates 20 to 60% of bodyweight. Work in animals suggests that the catabolism of interferons falls within the natural handling of proteins. Clearance values vary (4.8 to 48 L/h) across the family of interferons and probably reflect the natural internal digestion and turnover of these proteins. Terminal elimination half-lives range from 4 to 16 hours, 1 to 2 hours and 25 to 35 minutes for alpha, beta and gamma, respectively. Intramuscular and subcutaneous administration of interferons alpha and beta results in protracted but fairly good absorption: greater than 80% for interferon-alpha and 30 to 70% for interferon-gamma. Interferon therapy is associated with adverse events which are usually mild and reversible. Temporal relationships exist between the degree and duration of adverse effects and the route of administration. Attempts to relate inducible biochemical markers, such as 2',5'-oligoadenylate synthetase activity, to dose or concentration have met with some success although alterations in these markers have not been shown to relate to clinical response.(ABSTRACT TRUNCATED AT 250 WORDS)

Estrogen deprivation in breast cancer. Clinical, experimental, and biological aspects.

The endocrinological and clinical effects of an LH-RH agonist, Zoladex, and an antiestrogen, Nolvadex, in patients with advanced breast cancer are outlined and their potential in the therapy of nonmalignant diseases of the breast and high-risk states is briefly discussed. Additional data are presented to indicate that new antiestrogens are now available for experimental studies that, unlike tamoxifen, do not possess partial estrogen-like activity and that show favorable antitumor properties against DMBA-induced mammary tumors and MCF-7 human breast cancer cells in culture. The lack of agonistic effects of this new class of pharmacological agents now allows a state of total estrogen deprivation to be approached, a previously unobtainable clinical goal.

Influence of food on the bioavailability of trimoprostil: an overview.

The influence of food on the bioavailability of trimoprostil , a new antiulcer prostaglandin E2 derivative, was investigated in healthy male volunteers in four separate studies. Doses of 0.75, 1.5, and 3.0 mg were administered orally in both the presence and absence of food followed by serial blood sampling through 24 hours. Plasma trimoprostil concentrations were determined by a gas chromatograph-negative chemical ionization-mass spectrometric method for pharmacokinetic evaluation. Food decreased the absorption rate of trimoprostil as indicated by a later tmax (P less than 0.01) and corresponding lower Cmax at each dose. However, the food effect on tmax diminished as the dose increased. Although Cmax was reduced, food did not alter the extent of absorption, indicated by similar AUC (P greater than 0.05) between fed and fasted states. Both Cmax and AUC increased proportionately with an increase in dose. The harmonic mean half-lives of elimination were similar (P greater than 0.05) across all doses and ranged from 27 to 55 minutes.

Trimoprostil plasma concentration-gastric acid inhibition relationships in duodenal ulcer patients.

The effect of single 0.25 mg, 0.75 mg, 1.5 mg, and 3.0-mg oral doses of trimoprostil and placebo on the inhibition of meal-stimulated gastric acid secretion was investigated in duodenal ulcer patients. Drug and placebo were administered in a double-blind, randomized, crossover study under fasting conditions. A bactopeptone meal was administered 30 minutes after dosing. Gastric acid output was measured by intragastric titation (pH 5.5) and trimoprostil plasma concentrations were measured by a specific gas chromatography-negative chemical ionization-mass spectrometric method. Meal-stimulated gastric acid secretion was significantly reduced when compared to placebo for one hour after 0.25 mg, 1.5 hours after 0.75 mg, and for 2.5-3.0 hours after both 1.5 mg and 3.0 mg doses. The maximal inhibition of gastric acid ranged from 65% reduction after 0.75 mg to 74% after 1.5 mg to 82% after 3.0-mg doses. Trimoprostil was rapidly absorbed and eliminated; terminal elimination half-life ranged from 21 to 45 minutes. Both maximum concentration and area under the plasma concentration-time curve increased proportionately with an increase in the dose. The concentration-effect data at a given dose were simultaneously fit to a pharmacokinetic/pharmacologic effect model. An IC50 (plasma concentration needed to elicit a 50% inhibition effect) value of 0.2 ng/mL was observed at doses of 0.75 mg to 3.0 mg. Overall, trimoprostil was effective in inhibiting acid output in a dose-related manner in duodenal ulcer patients.

Influence of alcohol on the pharmacokinetics of diazepam controlled-release formulation in healthy volunteers.

Twelve normal volunteers were empanelled in an open-label, three-way crossover study to evaluate the influence of alcohol on the pharmacokinetics of controlled-release diazepam capsules. Each volunteer received one 15-mg diazepam controlled-release capsule alone, concomitantly with alcohol or followed by alcohol 2 hours later. The mean plasma concentration-time profiles following both alcohol treatments were superimposable on the profile from the control. The mean plateau concentrations were observed to endure from 2 through 12 hours in all cases. The mean +/- S.D. areas under the plasma concentration-time curves from time zero to infinity were similar indicating no difference in the extent of absorption of diazepam in the presence of alcohol. The harmonic mean elimination half-lives were also similar. Overall, the pharmacokinetics and the release properties of controlled-release diazepam capsule were not influenced by alcohol in normal volunteers.

Pharmacokinetics and pharmacodynamics of intravenous cibenzoline in normal volunteers.

The pharmacokinetics of intravenous (IV) cibenzoline were studied in six healthy male volunteers ranging in age from 51 to 78 years. The subjects received intravenous (IV) cibenzoline 100 mg over 20 minutes, and plasma and urine specimens were collected for 48 hours. Cibenzoline plasma concentrations at the end of the infusion ranged from 730 to 1,420 ng/mL and exhibited triexponential decline thereafter. The following mean model independent pharmacokinetic parameters were calculated from the plasma and urine concentration data: terminal half-life, 9.8 hours (range, 8.5-11.9); plasma clearance, 523 mL/min (range, 387-687); volume of distribution, 445 L (range, 328-506); and renal clearance, 289 mL/min (range, 202-334). Approximately 31% to 59% of the dose was recovered unchanged in the urine in 48 hours. A triexponential pharmacokinetic equation with zero order input was used to curve fit the plasma and urine data, and the model-dependent parameters agreed well with the model-independent estimates. A hysteresis loop was observed in the relationship between cibenzoline plasma concentration and QRS prolongation, indicating an initial lag between plasma concentration and effect after IV administration. Based on these results, the following preliminary dosing regimen was proposed to rapidly achieve and maintain therapeutic plasma concentrations equal to or slightly greater than 200-400 ng/mL: 0.25 mg/kg/min IV bolus over one minute followed by 1-1.5 mg/kg/hr for one hour and 0.2-0.4 mg/kg/hr for long-term infusion.

Relative bioavailability of rimantadine HCl tablet and syrup formulations in healthy subjects.

Twenty healthy male subjects completed an open-label randomized crossover design to assess the bioavailability of 100 mg of rimantadine HCl in tablet and syrup forms relative to an oral solution. Blood samples were drawn and rimantadine plasma concentrations were determined by a GC-MS method. The maximum plasma concentration (Cmax), the time to Cmax (tmax), the area under the plasma concentration-time curve (AUC), and k were compared among treatments using an analysis of variance and the Hauck-Anderson test for bioequivalence. The Hauck-Anderson test was satisfied when the syrup and solution were compared. The relative bioavailability of the syrup was 96%. Both Cmax and AUC were significantly (p less than 0.05) increased (23 and 17%, respectively) when the tablet was compared with the solution. The relative bioavailability of the tablet was 117%. This outcome was unusual and could not be explained. However, this was not anticipated to be of clinical consequence since the majority of the safety and efficacy of rimantadine HCl was established using a tablet.

Dose-dependent pharmacokinetics and biliary excretion of bromophenol blue in the rat.

Concentrations of bromophenol blue (I) in plasma, urine, and bile were determined spectrophotometrically after intravenous bolus injections and infusions in rats. The plasma concentrations were found to decrease monoexponentially after all doses except the highest, where the decrease was biexponential. Although the disposition kinetics of I were apparently first-order at all doses, the half-life increased with increasing dose. The area under the plasma concentration-time curve (AUC0-infinity) increased disproportionately with increasing dose. The binding of I to rat plasma proteins, as determined by equilibrium dialysis, showed that the fraction bound (96%) remained constant in the concentration range of 10-300 micrograms/ml. Plasma concentrations were determined at time zero after intravenous administration and after a second dose administered 20 min later when plasma concentrations from the first dose were minimal. The apparent first-order elimination rate constant for the plasma concentration decline following the second dose was significantly less than after the first dose, indicating that the residual dye in the liver altered the elimination of I after the second dose. The fraction of the dose in the liver decreased with increasing dose, indicating a saturable uptake process. The biliary excretion profile reflected the uptake saturation that occurred in the liver and demonstrated that the biliary excretion of I depended on the amount present in the liver. When liver damage was induced by exposure to carbon tetrachloride, dye concentrations in the plasma, liver, and kidney increased markedly.

Dose-dependent pharmacokinetics and hepatobiliary transport of bromophenol blue in the beagle.

The pharmacokinetic profile of bromophenol blue (I) in the plasma, urine, and bile of beagle dogs was determined after intravenous administration of 5-, 20-, and 30-mg/kg doses. In addition, two competitors, probenecid and phenylbutazone, were interacted with I in vivo and with I and rat liver cytoplasmic protein fractions Y and Z in vitro as a means of elucidating the mechanism of intrahepatic transport of I. Compound I was determined spectrophotometrically at 587 nm. In plasma, I displayed apparent first-order dose-dependent kinetics. The percentage of I bound to plasma proteins was approximately 92.5% over the dose range studied. Consecutive injections of equal doses of I produced statistically different terminal half-lives (p less than 0.05), suggesting the possibility of a saturable uptake process. In the presence of each competitor, the disposition of I was altered significantly (p less than 0.05): phenylbutazone displaced I from plasma protein, while probenecid decreased the binding of I to liver proteins in the Z-fraction. The Z-fraction bound a larger amount of I than the Y-fraction, suggesting a larger binding capacity. Under no circumstances was the binding of I to the Y-fraction altered. Cumulative biliary excretion data showed that the elimination of I in bile accounted for 92-99% of the dose delivered. The biliary excretion sigma- plots displayed no dose dependency, suggesting that the dose-dependent plasma half-life is due to a dose-dependent liver uptake (as opposed to elimination) process.

Effect of nonuniform bile flow rate on the rate of biliary excretion of bromophenol blue in the beagle.

Following the intravenous administration of bromophenol blue to beagle dogs, graphs of the biliary excretion rate versus time displayed drastic fluctuations which render them of little value for standard pharmacokinetic modeling purposes. It was shown that these fluctuations in excretion rate are highly correlated with corresponding fluctuations in the bile flow rate. An expression was derived which accounts for the primary effect of nonuniform bile flow rate on the biliary excretion rate. This treatment would enable the use of such biliary excretion rate data for pharmacokinetic modeling. Secondary effects of nonuniform bile flow on the biliary excretion rate are also discussed. It is suggested that the modeling of other flow rate-dependent elimination processes could benefit from such a treatment.

Influence of food and fluid ingestion on aspirin bioavailability.

The influence of test meals and accompanying fluid volume on aspirin bioavailability from commercial tablets was determined following single oral doses to healthy male volunteers. Plasma aspirin and salicylate levels were determined simultaneously using a GLC end-point. Area analysis indicated that approximately 5--8% of absorbed drug entered the systemic circulation as unchanged aspirin in nonfasted subjects compared to 16--18% in fasted individuals. Food tended to reduce the appearance rate of aspirin into the circulation, resulting in lower and somewhat more sustained levels than with fasting. Plasma salicylate levels were not influenced markedly by the various treatments, although levels were higher in fasted than in nonfasted subjects during the 1st hr after dosing. After this time, fat pretreatment tended to produce higher levels than other treatments.