Individual efficacy of clarithromycin (A-56268) and its major human metabolite 14-hydroxy clarithromycin (A-62671) in experimental pneumococcal pneumonia in the mouse.

In man, clarithromycin (A-56268) is metabolized to a 14-hydroxy derivative (14-OH clarithromycin, A-62671); this metabolite is absent in mice. An experimental mouse model was used to compare the efficacy of clarithromycin versus 14-OH clarithromycin in pneumococcal pneumonia by treatment with either the parent drug or its 14-OH metabolite alone. Four groups of 15 mice were infected intra-tracheally with a virulent strain of Streptococcus pneumoniae serotype 3 (approximately 10(5) cfu/mouse). Treatment was begun 18 h post infection, with clarithromycin or erythromycin 50 mg/kg subcutaneously (sc) bd, 14-OH clarithromycin 25 mg/kg sc bd or antibiotic free saline sc bd for 24 or 48 h. Survival rates ten days after one day of treatment with clarithromycin, 14-OH clarithromycin, erythromycin, or saline were 53%, 60%, 27% and 0% respectively. After two days treatment the rates were 100%, 100%, 53% (P less than 0.01) and 0% respectively. Thirty-six h after two doses, 14-OH clarithromycin demonstrated superior intra-pulmonary killing activity to erythromycin (2.7 +/- 0.4 vs 6.6 +/- 0.8 log10 cfu/mL lung homogenate) (P less than 0.001) and comparable activity to clarithromycin (3.6 +/- 1.3 log10 cfu/mL). These results show that clarithromycin (50 mg/kg sc) and 14-OH clarithromycin (25 mg/kg sc) have similar in vivo efficacy in a mouse model, in which the 14-OH metabolite is not produced from clarithromycin. This suggests that in man, the clinical efficacy of clarithromycin is not impaired by metabolism to 14-OH clarithromycin, which achieves serum concentrations in man of approximately 1 mg/L after multiple doses of clarithromycin 500 mg po.     

Effect of omeprazole on concentrations of clarithromycin in plasma and gastric tissue at steady state.

This study was conducted to determine (i) the effect of omeprazole on steady-state concentrations of clarithromycin and 14-(R)-hydroxyclarithromycin in plasma and gastric mucosa, (ii) the effect of clarithromycin on steady-state concentrations of omeprazole in plasma, and (iii) the effect of clarithromycin on the suppression of gastric acid secretion by omeprazole. Twenty healthy, Helicobacter pylori-negative male subjects completed this three-period, double-blind, randomized crossover study. In period 1, all subjects received 40 mg of omeprazole each morning for 6 days. Twenty-four-hour gastric pH monitoring took place on days -1 and 6. Pharmacokinetic sampling took place on day 6. In periods 2 and 3, subjects were randomly assigned to receive either 40 mg of omeprazole or omeprazole placebo daily for 6 days plus clarithromycin (500 mg) every 8 h for 5 days with a single 500-mg dose on day 6. Gastric tissue and mucus samples were obtained via endoscopy on day 5. Gastric pH monitoring and pharmacokinetic sampling took place on day 6. Two-week washout intervals separated the three study periods. Clarithromycin increased mean omeprazole area under the concentration-time curve from 0 to 24 h from 3.3 +/- 2.0 to 6.3 +/- 4.5 micrograms.h/ml (P < 0.05) and harmonic mean half-life from 1.2 to 1.6 h (P < 0.05) but did not significantly alter the effect of omeprazole on gastric pH. Mean clarithromycin area under the concentration-time curve from 0 to 8 h increased from 22.9 +/- 5.5 (placebo) to 26.4 +/- 5.7 micrograms.h/ml (omeprazole) (P < 0.05) when clarithromycin was administered with omeprazole. Analysis of variance revealed that mean concentrations of clarithromycin in tissue and mucus were statistically significantly higher when clarithromycin was given with omeprazole than when clarithromycin was given with placebo (P <0.001). Mean maximum observed concentrations of clarithromycin in the gastric fundus increased from 20.8 +/- 7.6 (placebo) to 24.3 +/- 6.4 micrograms/g (omeprazole), and those in the gastric mucous from 4.2 +/- 7.7 placebo to 39.3 +/- 32.8 micrograms/g (omeprazole). Similar increases were observed for the 14-(R)-hydroxyclarithromycin. These results show that omeprazole increases concentrations of clarithromycin in gastric tissue and mucus and may provide a mechanism for synergy between clarithromycin ad omeprazole that explains the excellent eradication of H. pylori seen in clinical trials.     

Comparative pharmacokinetics and serum inhibitory activity of clindamycin in different dosing regimens.

The comparative pharmacokinetics and serum inhibitory effects of clindamycin were evaluated in six healthy male subjects given multiple-dose infusions of the following regimens in a crossover fashion: 600 mg every 6 h, 900 mg every 8 h, and 1,200 mg every 12 h. Serial blood samples were obtained after the last dose in each regimen and analyzed for clindamycin by a sensitive and specific high-performance liquid chromatography assay technique. Clindamycin pharmacokinetics were estimated by using noncompartmental methods, and serum inhibitory titers were serially determined against Bacteroides fragilis ATCC 25285 and evaluated by using area under the serum inhibitory curve (AUIC). Maximum and minimum concentrations in plasma averaged 12.2 +/- 1.6 and 1.2 +/- 0.6, 16.3 +/- 4.0 and 0.9 +/- 0.5, and 16.8 +/- 2.5 and 0.4 +/- 0.2 micrograms/ml for the 600-, 900-, and 1,200-mg regimens, respectively. Clindamycin plasma clearance and elimination half-life averaged 23.3 +/- 4.0 liters/h and 1.9 +/- 0.4 h for the 600-mg regimen, 25.6 +/- 8.2 liters/h and 2.1 +/- 0.4 h for the 900-mg regimen, and 26.4 +/- 4.7 liters/h and 2.1 +/- 0.4 h for the 1,200-mg regimen. These results were not significantly different. Apparent volume of distribution increased significantly for the 1,200-mg regimen compared with the 600-mg regimen. Mean maximum reciprocal serum inhibitory titers were 96 +/- 35, 101 +/- 43, and 160 +/- 78 for the 600-, 900-, and 1,200-mg regimens, respectively. Minimum reciprocal serum inhibitory titers averaged 12 +/- 4, 6 +/- 3, and 5 +/- 2 for the low-, medium-, and high-dose regimens, respectively. Mean AUIC increased roughly in proportion to dose. Similar daily values for the area under the concentration-time curve and for AUIC for each of the regimens suggest similar daily drug exposure and serum inhibitory activity. A regimen of 1,200 mg every 12 h may represent an alternative dosing strategy for clindamycin.     

Pharmacokinetics and tolerance of lomefloxacin after sequentially increasing oral doses.

The pharmacokinetics of five dose levels of lomefloxacin (100, 200, 400, 600, and 800 mg) were examined in a single-dose, double-blind, placebo-controlled study involving 40 subjects. There were eight subjects in each group: five received active drug and three received placebo; each subject was given only one dose. All subjects completed the study, and lomefloxacin was well tolerated at all doses. No drug crystals were noted in the urine at 3 and 6 h after the dose. The mean maximum concentration in serum (Cmax) ranged from 1.11 to 7.46 micrograms/ml for the 100- to 800-mg doses, respectively, and the AUC increased proportionally with the dose. The mean time to Cmax (Tmax) values averaged 64.8 +/- 28.8 min. The elimination half-life and plasma clearance averaged 7.7 +/- 0.52 h and 259 +/- 37 ml/min, respectively. Mean concentrations in urine were highest during the first 4 h after the dose and ranged from 104 to 713 micrograms/ml following the 100- and 800-mg doses, respectively. Concentrations above 20 micrograms/ml in urine were observed in most subjects over 24 h at the three lower doses and averaged over 120 micrograms/ml during the 12- to 24-h interval at the 400-mg dose, thus supporting once-per-day dosing. Excretion rates from urine and the cumulative amount excreted increased in a dose-related fashion. Renal clearance decreased moderately at the higher doses. Thus, lomefloxacin was well tolerated, and dose proportionality was demonstrated by most pharmacokinetic parameters. The 400-mg dose produced concentrations in plasma and urine above the MIC for susceptible pathogens.     

Dose ranging study and constant infusion evaluation of ciprofloxacin.

We evaluated the pharmacokinetics of 100- and 200-mg doses of ciprofloxacin, with the 200-mg dose administered either as a 30-min infusion or as a 100-mg loading dose followed by a 4-h constant infusion of 25 mg/h in six normal volunteers. No significant differences were seen in the dose-normalized area under the curve when the 100- and 200-mg 30-min administrations were compared. Differences that approached statistical significance were seen when data from either of these trials were compared with data from the constant-infusion arm. Serum clearances averaged 23.0 +/- 9.1 liters/h per 1.73 m2 for the 100-mg dose and 23.7 +/- 5.1 liters/h per 1.73 m2 for the 200-mg dose. Renal clearance accounted for approximately two-thirds of the serum clearance in each instance. Half-lives were slightly longer than 4 h. For the constant-infusion arm, serum clearance was 28.9 +/- 2.7 liters/h per 1.73 m2, with renal clearance accounting for 58% of serum clearance. Although no nonlinearities were apparent in the 100- to 200-mg dose range, larger doses, particularly in the multiple-dosing situation, may uncover nonlinearity in the disposition of ciprofloxacin.     

Lack of effect of zafirlukast on the pharmacokinetics of azithromycin, clarithromycin, and 14-hydroxyclarithromycin in healthy volunteers

This randomized, open-label, crossover study was conducted to investigate whether the coadministration of zafirlukast would affect the pharmacokinetics of azithromycin, clarithromycin, or 14-hydroxyclarithromycin (14-OHC). Twelve healthy subjects (six males and six females) received single 500-mg doses of azithromycin and clarithromycin with and without zafirlukast given to a steady-state concentration. Blood was collected prior to all macrolide doses and for 3 and 10 days after each clarithromycin and azithromycin dose, respectively. Serum was assayed for azithromycin, clarithromycin, and 14-OHC concentrations by validated high-performance liquid chromatography assay systems. Data analyses were done by noncompartmental and nonparametric methods. Analysis of the patients indicated that the addition of steady-state concentrations of zafirlukast did not significantly alter the pharmacokinetic parameters of or overall exposure (based on the area under the concentration-time curve) to azithromycin, clarithromycin, and 14-OHC. While zafirlukast is a known inhibitor of CYP3A4, it does not appear to exert a clinically or statistically significant pharmacokinetic effect on azithromycin, clarithromycin, or 14-OHC.     

Multiple-dose safety and pharmacokinetics of oral garenoxacin in healthy subjects

Garenoxacin (T-3811ME, BMS-284756) is a novel des-F(6) quinolone that has been shown to be effective in vitro against a wide range of clinically important pathogens, including gram-positive and gram-negative aerobes and anaerobes. This study was conducted to evaluate the safety and tolerability of multiple oral doses (100 to 1200 mg/day) of garenoxacin in healthy subjects and to determine its multiple-dose pharmacokinetics. Forty healthy male and female subjects (18 to 45 years of age) were enrolled in this randomized, double-blind, placebo-controlled, sequential, multiple- and ascending-dose study. Each subject received a once-daily oral dose of garenoxacin (100, 200, 400, 800, or 1200 mg) or a placebo for 14 days. Blood and urine samples were collected for measurements of garenoxacin by validated liquid chromatography with dual mass spectrometry, and plasma garenoxacin concentration-time data were analyzed by noncompartmental methods. The effects of garenoxacin on Helicobacter pylori, psychometric test performance, and electrocardiograms were assessed, as was drug safety. Over the 14 days of dosing, geometric mean peak concentrations of garenoxacin in plasma (C(max)) at the 100- and 1200-mg doses were within the ranges of 1.2 to 1.6 and 16.3 to 24 microg/ml, respectively. The corresponding values for the geometric mean area under the concentration-time curve over the dosing interval (AUC(tau)) for garenoxacin in plasma at the 100- and 1200-mg doses were within the ranges of 11.5 to 15.7 and 180 to 307 microg. h/ml, respectively. Increases in systemic exposure to garenoxacin in terms of AUC and C(max) were approximately dose proportional over the 100- to 400-mg dose range but demonstrated increases that were somewhat greater than the dose increments at the 800- and 1200-mg doses. Median values for the time to achieve C(max) were in the range of 1.13 to 2.50 h for all doses. The mean elimination half-life for garenoxacin in plasma appeared to be independent of dose and ranged from 13.3 to 17.8 h (day 14). Approximately 30 to 50% of an administered garenoxacin dose was excreted unchanged in the urine. At doses of 100 to 400 mg, steady-state concentrations of garenoxacin in plasma appeared to be attained by the fourth dose. Multiple oral doses of garenoxacin were well tolerated and did not demonstrate clinically significant effects on QT(c) or psychometric test results. Garenoxacin administered alone for 14 days at doses of >or=400 mg demonstrated activity against H. pylori. These results suggest that multiple once-daily oral doses of garenoxacin of up to 1200 mg are safe and well tolerated and that the pharmacokinetics of garenoxacin support once-daily administration.     

Pharmacokinetics of rifabutin.

We investigated the pharmacokinetics of rifabutin in 15 male patients as part of a phase I trial of the treatment of early symptomatic human immunodeficiency virus infection. Six or more patients were studied at each of four different oral dosage levels: 300, 600, 900, and 1,200 mg/day. Twelve studies were also conducted with tracer doses of intravenous radiolabeled [14C]rifabutin. Blood and urine samples were collected for at least 72 h after the first (day 1) and last (day 28) doses of rifabutin and analyzed by high-pressure liquid chromatography. The plasma concentration data were best described by a two-compartment open model with a terminal half-life of 36 h. Rifabutin was rapidly absorbed, reaching a peak concentration about 2 to 3 h after an oral dose. Peak and trough concentrations for the 1,200-mg dose were 907 and 194 ng/ml, respectively. Total body clearance was 10 to 18 liters/h. Oral bioavailability was 12 to 20%. The drug was moderately bound to plasma proteins with a free fraction of 29 +/- 2% (mean +/- standard deviation). About 10% of an administered intravenous dose of rifabutin is excreted into the urine unchanged. Renal clearance was 1.5 +/- 0.2 liters/h. The volume of distribution was large (8 to 9 liters/kg), suggesting extensive distribution into the tissues. The area under the curve for the last dose was smaller than that of the first dose, suggesting possible induction of drug-metabolizing enzymes.     

Effect of dose on pharmacokinetics and serum bactericidal activity of mezlocillin.

Mezlocillin is subject to dose-dependent pharmacokinetics. Previous studies have examined the pharmacokinetic but not the pharmacodynamic aspects of this effect. The pharmacokinetic disposition of mezlocillin was determined in eight healthy volunteers in a randomized, crossover fashion after single infusions of 50 and 80 mg of mezlocillin per kg of body weight. Plasma and urine were assayed with a specific high-pressure liquid chromatography assay and analyzed by noncompartmental methods. Pharmacodynamic (bactericidal) effects were evaluated from serial serum bactericidal titers obtained after each dose by using the area under the bactericidal activity curve method. The mean mezlocillin total body clearance decreased from 203.6 +/- 36.2 ml/min after the 50-mg/kg dose to 171.7 +/- 42.1 ml/min after the 80-mg/kg dose (P, 0.01). The decreased clearance was reflected by a decrease in nonrenal clearance only (108.9 +/- 20.0 to 77.9 +/- 23.5 ml/min, respectively; P, 0.001). Mean areas under the curve for concentration in plasma versus time normalized to the 50-mg/kg dose were 314 +/- 73 and 375 +/- 64 micrograms X h/ml for the low and high doses, respectively (P, 0.01). No significant changes were observed in the steady-state volume of distribution or elimination half-life. Mean areas under the bactericidal activity curve were 100 +/- 77 and 244 +/- 143 for the 50- and 80-mg/kg doses, respectively. The decrease in mezlocillin clearance and the disproportionate increase in the area under the curve for concentration in plasma versus time, coupled with the observed prolonged bactericidal effects of the 80-mg/kg dose, lend support for administration of mezlocillin at a higher dose less frequently (e.g., 5 g every 8 h). Clinical trials with the higher-dose regimen are warranted to validate these observations.     

Pharmacokinetics and tolerance of DU-6859a, a new fluoroquinolone, after single and multiple oral doses in healthy volunteers.

The pharmacokinetics and tolerance of DU-6859a, 7-[(7S)-7-amino-5-azaspiro[2,4]heptan-5-yl]-8-chloro-6-fluor o-1-[(1R, 2S)-2-fluoro-1-cyclopropyl]-1,4-dihydro-4-oxo-3-quinolinecarboxylic acid sesquihydrate, were investigated in healthy male Japanese volunteers after single (25, 50, 100, and 200 mg) and multiple (100 mg three times a day for 6 days plus once a day on the 7th day and 50 mg every 12 h for 13 doses) oral doses. DU-6859a was well tolerated at all doses, and all 36 subjects completed the study; mild transient soft stool in five volunteers and mild transient diarrhea in one volunteer on the multiple-dose (100 mg three times a day) study were the only side effects reported. No drug crystals were observed in the urine after the single 200-mg dose and the 100-mg three times a day regimen. DU-6859a was rapidly absorbed in the fasted state. The mean maximum concentration in serum (Cmax) ranged from 0.29 to 1.86 micrograms/ml for the 25- to 200-mg dose, and the mean time to reach Cmax ranged from 1.0 to 1.3 h. The terminal half-life ranged from 4.4 to 5.0 h. The area under the curve increased dose dependently. The serum protein binding of the drug was approximately 50%. The apparent volume of distribution clearly exceeded 1 liter/kg, suggesting good tissue penetration. Within 48 h, the cumulative urinary recovery of unchanged drug amounted to 69 to 74% of the dose administered, while fecal excretion up to 48 h after the 200-mg dose accounted for ca. 3% of the dose. Food intake did not affect the rate and extend of absorption of DU-6859a to a clinically significant extent. During multiple oral dosing, the accumulation of the drug in serum was close to the theoretically predicted values, which indicated that there was virtually no drug accumulation.     

Steady-state plasma and bronchopulmonary characteristics of clarithromycin extended-release tablets in normal healthy adult subjects

OBJECTIVES: The steady-state concentrations of clarithromycin in plasma were compared with concomitant concentrations in epithelial lining fluid (ELF) and alveolar macrophages (AM) obtained from intrapulmonary samples during bronchoscopy and bronchoalveolar lavage (BAL). Concentrations of the major metabolite, 14-hydroxyclarithromycin, were also determined in plasma and AM. MATERIALS AND METHODS: Forty-two healthy, non-smoking adult subjects (age: 18-54 years; 19 females, 23 males) received oral clarithromycin extended-release formulation (1000 mg once daily for five consecutive days). Bronchoscopy and BAL were carried out once in each subject at either 3, 6, 9, 12, 24 or 48 h after the last administered dose of clarithromycin. In addition, three subjects who did not take clarithromycin served as controls and underwent bronchoscopy at 0 h. Drug concentrations in plasma, ELF, and AM were determined by high-performance liquid chromatography. RESULTS: Clarithromycin was extensively concentrated in ELF [range of mean (+/-s.d.) concentrations: 6.38 +/- 3.92 to 11.50 +/- 6.65 mg/L] and AM (127.0 +/- 61.5 to 573.8 +/- 309.3 mg/L) than simultaneous plasma concentration (0.75 +/- 0.31 to 2.22 +/- 0.72 mg/L). The ranges of mean (+/-s.d.) concentrations of 14-hydroxyclarithromycin in plasma and AM were 0.52 +/- 0.29 to 0.80 +/- 0.31 mg/L and 22.1 +/- 13.5 to 49.5 +/- 16.2 mg/L, respectively. CONCLUSIONS: Once-daily dosing of extended-release formulation clarithromycin 1000 mg produced significantly (P < 0.05) higher steady-state concentrations of clarithromycin in ELF (2-14 times) and AM (50-700 times) compared to simultaneous plasma concentrations throughout the 24 h period after drug administration. The 14-hydroxy metabolite of clarithromycin achieved significantly (P < 0.05) higher steady-state concentrations in AM (18-180 times) compared with concurrent plasma concentrations.     

Multiple-dose pharmacokinetics and safety of oral amifloxacin in healthy volunteers.

The multiple-dose pharmacokinetics and safety of amifloxacin, a new fluoroquinolone antibacterial agent, were evaluated in healthy male volunteers. Amifloxacin was administered orally at 200, 400, or 600 mg every 12 h (q12h) and 400, 600, or 800 mg every 8 h (q8h) for 10 days. An additional dose was administered on day 11. Concentrations of amifloxacin in plasma and urine were measured on days 1, 5, and 11 by high-performance liquid chromatography. Steady-state amifloxacin concentrations were reached by day 5. Mean +/- standard deviation maximum observed amifloxacin concentrations in plasma were 2.52 +/- 1.12, 4.98 +/- 1.44, 5.40 +/- 2.02, 4.59 +/- 2.17, 6.53 +/- 2.44, and 8.01 +/- 3.00 micrograms/ml after the initial dose and 2.30 +/- 0.98, 5.41 +/- 0.74, 8.05 +/- 1.68, 6.87 +/- 2.81, 9.53 +/- 0.50, and 11.9 +/- 1.92 micrograms/ml on day 11 of the study for the 200-, 400-, and 600-mg q12h and 400-, 600-, and 800-mg q8h regimens, respectively. Amifloxacin was rapidly absorbed, as evidenced by the mean time to the maximum observed amifloxacin concentration of 0.98 h. Mean values for the terminal amifloxacin half-life in plasma ranged from 3.58 to 5.78 h. Mean amifloxacin concentrations in urine on day 11 in samples collected 0 to 2 h after dosing were 105, 417, 376, 336, 518, and 464 micrograms/ml for the 200-, 400-, and 600-mg q12h and 400-, 600-, and 800-mg q8h regimens, respectively. The mean amount of the dose excreted in the urine as amifloxacin was 53.9%. Amifloxacin was generally well tolerated, although there was a tendency for the subjects who received amifloxacin to experience more gastrointestinal, central nervous system, and cutaneous complaints than did those who received placebo. Clinically significant adverse reactions, including pruritus and transaminase elevations, occurred only at doses of 1,200 mg/day or above. Clinical and pharmacokinetic data suggest that orally administered amifloxacin may have utility in the treatment of urinary tract infections.     

Pharmacokinetic interaction between amprenavir and clarithromycin in healthy male volunteers

The P450 enzyme, CYP3A4, extensively metabolizes both amprenavir and clarithromycin. To determine if an interaction exists when these two drugs are coadministered, the pharmacokinetics of amprenavir and clarithromycin were investigated in healthy adult male volunteers. This was a Phase I, open-label, randomized, balanced, multiple-dose, three-period crossover study. Fourteen subjects received the following three regimens: amprenavir, 1,200 mg twice daily over 4 days (seven doses); clarithromycin, 500 mg twice daily over 4 days (seven doses); and the combination of the above regimens over 4 days (seven doses of each drug). Twelve subjects completed all treatments and the follow-up period. The erythromycin breath test (ERMBT) was administered at baseline, 2 h after the final dose of each of the three regimens and at the first follow-up visit. Coadministration of clarithromycin and amprenavir significantly increased the mean amprenavir AUC(ss), C(max,ss), and C(min,ss) by 18, 15, and 39%, respectively. Amprenavir had no significant effect on the AUC(ss) of clarithromycin, but the median T(max,ss)for clarithromycin increased by 2.0 h, renal clearance increased by 34%, and the AUC(ss) for 14-(R)-hydroxyclarithromycin decreased by 35% when it was given with amprenavir. Amprenavir and clarithromycin reduced the ERMBT result by 85 and 67%, respectively, and by 87% when the two drugs were coadministered. The baseline ERMBT value did not correlate with clearance of amprenavir or clarithromycin. A pharmacokinetic interaction occurs when amprenavir and clarithromycin are coadministered, but the effects are not likely to be clinically important, and coadministration does not require a dosage adjustment for either drug.     

Tight binding of clarithromycin, its 14-(R)-hydroxy metabolite, and erythromycin to Helicobacter pylori ribosomes.

Clarithromycin is a recently approved macrolide with improved pharmacokinetics, antibacterial activity, and efficacy in treating bacterial infections including those caused by Helicobacter pylori, an agent implicated in various forms of gastric disease. We successfully isolated ribosomes from H. pylori and present the results of a study of their interaction with macrolides. Kinetic data were obtained by using 14C-labeled macrolides to probe the ribosomal binding site. Clarithromycin, its parent compound erythromycin, and its 14-(R)-hydroxy metabolite all bound tightly to H. pylori ribosomes. Kd values were in the range of 2 x 10(-10) M, which is the tightest binding interaction observed to date for a macrolide-ribosome complex. This tight binding was due to very slow dissociation rate constants of 7.07 x 10(-4), 6.83 x 10(-4), and 16.6 x 10(-4) min-1 for clarithromycin, erythromycin, and 14-hydroxyclarithromycin, respectively, giving half-times of dissociation ranging from 7 to 16 h, the slowest yet measured for a macrolide-ribosome complex. These dissociation rate constants are 2 orders of magnitude slower than the dissociation rate constants of macrolides from other gram-negative ribosomes. [14C]clarithromycin was bound stoichiometrically to 50S ribosomal subunits following incubation with 70S ribosomes and subsequent separation of the 30S and 50S subunits by sucrose density gradient centrifugation. These data predict that the lower MIC of clarithromycin compared with that of erythromycin for H. pylori is likely due to a faster rate of intracellular accumulation, possibly because of increased hydrophobicity.     

Tolerability, pharmacokinetics, and serum bactericidal activity of intravenous dalbavancin in healthy volunteers

Fifty-two healthy adult male and female volunteers were enrolled in this double-blind study to determine the maximum tolerated dose, characterize the pharmacokinetics, and obtain serum bactericidal activity (SBA) data for intravenous dalbavancin. Subjects were assigned to single- or multiple-dose groups and randomized to receive dalbavancin or placebo intravenously over 30 min. Doses started at 140 mg in the single-dose group and with a 300-mg loading dose (LD), followed by six daily 30-mg maintenance doses (MDs), in the multiple-dose cohort and escalated to a 1120-mg single dose and a 1000-mg LD and 100-mg MD regimen. Plasma, urine, and skin blister fluid aspirate drug concentrations were measured, and pharmacokinetic parameters were determined via noncompartmental methods. SBA against methicillin-resistant Staphylococcus aureus (MRSA) was determined at several time points. Adverse events and changes from the baseline for laboratory data, electrocardiograms, audiologic assessments, physical examinations, and vital signs were assessed. Concentrations increased in proportion to the dose. Steady-state concentrations were achieved by day 3 with the 10:1 LD-MD regimen. The half-life averaged 181 h, and the mean volume of distribution and clearance were 9.75 liters and 0.0473 liters/h, respectively. Mean values were similar in all groups and in males and females. The portion of the dose excreted renally averaged 33.5%. Bactericidal activity was demonstrated in serum at 7 days in all subjects receiving single doses of >or=500 mg. All doses were well tolerated. Dose-limiting toxicity was not encountered. No changes in auditory or vestibular function occurred. The long half-life and maintenance of SBA against MRSA for 1 week suggest that weekly dosing may be feasible.     

Multiple-dose pharmacokinetics of ciprofloxacin administered intravenously to normal volunteers.

We administered multiple doses of ciprofloxacin intravenously over 30 min every 12 h for 1 week to nine healthy volunteers. Three volunteers received a placebo (vehicle) intravenously. Doses of 100, 150, and 200 mg were evaluated with a 1-week wash-out period intervening between each dose level. Terminal excretion half-lives averaged 3.67 +/- 0.65, 3.60 +/- 0.26, and 4.00 +/- 0.69 h for the 100-, 150-, and 200-mg doses, respectively. Serum clearances were 30.1 +/- 3.4, 29.8 +/- 4.0, and 26.9 +/- 4.1 liters/h per 1.73 m2 for these doses. Urine concentrations remained in excess of the MIC for 90% of the relevant urinary tract pathogens for the full 12-h dosing interval at each dose. Renal clearance accounted for 56 to 71% of the serum clearance. However, because a microbiologic assay was used and biologically active, renally excreted metabolites were identified, the renal clearance determinations are likely to be in excess of the true values. The doses of ciprofloxacin administered intravenously were well tolerated, and the drug concentrations appeared adequate for the treatment of the vast majority of cases of nosocomially acquired sepsis and urinary tract infections. For patients with serious Pseudomonas infections and perhaps staphylococcal infections, either an 8-h dosing schedule or larger doses on a 12-h schedule should be considered.     

Multiple-dose pharmacokinetics of sparfloxacin and its influence on fecal flora.

In a randomized, double-blind, placebo-controlled, multiple-dose pharmacokinetic study, the safety and effect on intestinal flora of sparfloxacin (SPX) were determined in 12 healthy male volunteers (8 received SPX and 4 received a placebo). Following fasting and oral administration of 400 mg on day 1 and 200 mg on days 2 to 8, concentrations of the free drug in serum, urine, and feces were measured by high-performance liquid chromatography; serum and urine were also evaluated by a microbiological assay. All results, except those for renal excretion, exclude the glucuroconjugate metabolite. A mean peak concentration in serum (400-mg dose) of 0.56 +/- 0.13 mg/liter was measured 3.52 +/- 0.98 h after administration. Pharmacokinetic parameters (measured by high-performance liquid chromatography) were based on an open, one-compartment model and resulted in the following day 1 (calculated for the 200-mg dose), day 4 (recalculated for a single dose), and day 8 values (mean +/- standard deviation): area under the curve, 16.4 +/- 2.3 (day 1) and 18.3 +/- 5.1 (day 4) mg.h/liter; elimination half-life, 18.3 +/- 3.9 h; steady-state volume of distribution, 4.7 +/- 1.4 (day 1) and 4.3 +/- 1.2 (day 8) liters/kg; apparent total clearance, 201 +/- 31 (day 1) and 190 +/- 51 (day 4) ml/min; renal clearance, 19.1 +/- 5.8 (day 1) and 23.2 +/- 19.4 (day 4) ml/min. Recovery in urine on day 1 was 5.89% +/- 1.4% of the dose in 24 h for the parent compound and 18.4% +/- 6.8% for the SPX glucuronide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Penetration of clarithromycin into lung tissues from patients undergoing lung resection.

The concentrations of clarithromycin and its active principal metabolite, 14-(R)-hydroxy-clarithromycin, were determined in lung tissue obtained during lung resection and compared with concomitant concentrations in plasma. Concentrations of the parent and metabolite were determined by high-performance liquid chromatography. The 15 patients studied were given 500 mg orally every 12 h for a minimum of five doses to achieve steady-state concentrations. The mean concentrations of clarithromycin and 14-(R)-hydroxy-clarithromycin in plasma just prior to the final dose were 1.38 and 0.67 micrograms/ml, respectively, and those 4 h after the final dose (at the time of lung resection) were 1.89 and 0.80 microgram/mL, respectively. The concentrations of the parent and metabolite in lung tissue at the time of lung resection averaged 54.3 and 5.12 micrograms/g, respectively, with a mean calculated ratio of concentrations of the parent to metabolite being 11.3 in lung tissue and 2.4 in plasma. Clarithromycin and its active metabolite are extensively distributed into human lung tissue.     

Efficacy and Safety of Sumatriptan Tablets (25 mg, 50 mg, and 100 mg) in the Acute Treatment of Migraine: Defining the Optimum Doses of Oral Sumatriptan

That sumatriptan tablets are effective and well tolerated in the acute treatment of migraine has been established, but the relationship between dose and efficacy has not been adequately defined to date in clinical trials. This multinational double-blind trial (N=1003) in which patients treated up to three migraine attacks with sumatriptan 25 mg, 50 mg, 100 mg, or placebo, with a second independently randomized dose for headache recurrence, evaluated the efficacy and tolerability of three doses of sumatriptan. The results demonstrate that all doses of sumatriptan were superior ( P <0.05) to placebo in reducing moderate or severe predose headache to mild or no headache 4 hours postdose for each of the three treated attacks; sumatriptan 50 mg and 100 mg were each superior ( P <0.05) to sumatiptan 25 mg 4 hours postdose for two of three attacks. Sumatriptan (all doses) was similarly effective at relieving nausea and photophobia or phonophobia or both and at reducing clinical disability. Headache recurrence was experienced by similar proportions of patients across treatment groups (35% to 48% after placebo; 26% to 39% after sumatriptan). Relief of recurrent headache 2 hours after the second dose of study medication occurred in greater percentages of patients using any dose of sumatriptan compared with patients using placebo to treat recurrence. The incidence of adverse events with 25-mg and 50-mg sumatriptan tablets was similar to the incidence with placebo and lower than the incidence with 100-mg sumatriptan tablets. These data provide the first demonstration from a large well-controlled clinical trial that both the 50- and 100-mg doses are more effective than the 25-mg dose and that the 50-mg dose is associated with a lower incidence of adverse events than the 100-mg dose.     

Pharmacokinetics of lansoprazole,amoxicillin and clarithromycin after simultaneous and single administration

In a randomized, double-blind, placebo-controlled, four-way crossover study, possible influences of the triple therapy with amoxicillin, clarithromycin and the proton pump inhibitor lansoprazole on the pharmacokinetics of each of the drugs and the active 14-OH-clarithromycin metabolite were assessed. Twelve Helicobacter pylori-negative healthy male volunteers (age 27 +/- 4.3 years; creatinine clearance 7.0 +/- 2.0 L/h) were given lansoprazole 30 mg, amoxicillin 1 g and clarithromycin 500 mg, alone and in triple combination. Drug elimination intervals were at least 9 days between the dosing periods. The study medication was administered twice daily for 4 days. On the fifth day of each period, drugs were only given once in the morning, and blood and urine samples were collected for 12 h. The concentrations of the three substances administered, and 14-OH-clarithromycin, were determined by validated HPLC methods. Alterations in the serum kinetics were found for lansoprazole and the active 14-OH-clarithromycin metabolite (all data expressed as mean +/- S.D.). For lansoprazole, the elimination half-life (t(1/2)) was significantly prolonged (1.46 versus 1.7 h, P < 0.05) and the area under the concentration-time curve from 0 to 8 h (AUC(0-8)) was significantly increased (3.65 versus 4.59 mg.h/L, P < 0.05) by combination of the drugs. For 14-OH-clarithromycin, the peak concentration (C(max)) was 0.95 versus 1.18 mg/L and the AUC from 0 to 12 h (AUC(0-12)) was 8.3 versus 10.5 mg.h/L (augmented significantly, P < 0.05). The amoxicillin concentrations were slightly elevated by concomitant administration of lansoprazole and clarithromycin but without statistical significance (11.1 versus 12.6 mg/L). For clarithromycin, the time to maximum concentration of drug in serum (T(max)) was increased (2.73 versus 3.31 h, P < 0.05), whereas AUC and C(max) remained unchanged. Simultaneous administration of lansoprazole, amoxicillin and clarithromycin increases the serum concentrations of lansoprazole and the active 14-OH-clarithromycin metabolite significantly. These effects were not so pronounced as to have any therapeutic influence, making dosage adjustment unnecessary.