Pharmacokinetics and urinary excretion of amikacin in low-clearance unilamellar liposomes after a single or repeated intravenous administration in the rhesus monkey

Liposomal aminoglycosides have been shown to have activity against intracellular infections, such as those caused by Mycobacterium avium. Amikacin in small, low-clearance liposomes (MiKasome) also has curative and prophylactic efficacies against Pseudomonas aeruginosa and Klebsiella pneumoniae. To develop appropriate dosing regimens for low-clearance liposomal amikacin, we studied the pharmacokinetics of liposomal amikacin in plasma, the level of exposure of plasma to free amikacin, and urinary excretion of amikacin after the administration of single-dose (20 mg/kg of body weight) and repeated-dose (20 mg/kg eight times at 48-h intervals) regimens in rhesus monkeys. The clearance of liposomal amikacin (single-dose regimen, 0.023 +/- 0.003 ml min-1 kg-1; repeated-dose regimen, 0.014 +/- 0.001 ml min-1 kg-1) was over 100-fold lower than the creatinine clearance (an estimate of conventional amikacin clearance). Half-lives in plasma were longer than those reported for other amikacin formulations and declined during the elimination phase following administration of the last dose (from 81.7 +/- 27 to 30.5 +/- 5 h). Peak and trough (48 h) levels after repeated dosing reached 728 +/- 72 and 418 +/- 60 micrograms/ml, respectively. The levels in plasma remained > 180 micrograms/ml for 6 days after the administration of the last dose. The free amikacin concentration in plasma never exceeded 17.4 +/- 1 micrograms/ml and fell rapidly (half-life, 1.47 to 1.85 h) after the administration of each dose of liposomal amikacin. This and the low volume of distribution (45 ml/kg) indicate that the amikacin in plasma largely remained sequestered in long-circulating liposomes. Less than half the amikacin was recovered in the urine, suggesting that the level of renal exposure to filtered free amikacin was reduced, possibly as a result of intracellular uptake or the metabolism of liposomal amikacin. Thus, low-clearance liposomal amikacin could be administered at prolonged (2- to 7-day) intervals to achieve high levels of exposure to liposomal amikacin with minimal exposure to free amikacin.     

The activity of low-clearance liposomal amikacin in experimental murine tuberculosis.

Most of the amikacin in low-clearance liposomal amikacin is excreted very slowly, offering the possibility of maintaining effective treatment of pulmonary tuberculosis with widely separated supervised doses. As a preliminary to explorations in humans, its efficacy was assessed in acute experimental murine tuberculosis by weekly counts of viable bacilli in spleen and lungs over a 4 week period. Liposomal amikacin in dosages of 160, 80 and 40 mg/kg given iv three times a week was 2.4-5.0 times more active than free amikacin and 6.6-6.7 times more active than streptomycin with the non-liposomal drugs given im five times a week. When the free amikacin and the streptomycin were also given iv three times a week, liposomal amikacin was 2.7-2.9 times more active than free amikacin and 3.7-5.6 more active than streptomycin. In a model of chronic tuberculosis, initial BCG vaccination was followed by challenge with virulent Mycobacterium tuberculosis and a 2 week stabilization period. Thereafter, treatment with liposomal amikacin 160 and 80 mg/kg three times a week for the first 4 weeks and then once a week for a further 4 weeks, had greater initial bactericidal activity than free amikacin 160 mg/kg five times a week, but had less eventual sterilizing activity than five times a week oral isoniazid 25 mg/kg or rifampicin 15 mg/kg. Although low-clearance liposomes increased the safety, potency and dosing interval of amikacin in these models, all aminoglycosides, including liposomal amikacin, were only bactericidal in the presence of bacillary metabolism and growth.     

Phase II dose-ranging trial of the early bactericidal activity of PA-824

PA-824 is a novel nitroimidazo-oxazine under evaluation as an antituberculosis agent. A dose-ranging randomized study was conducted to evaluate the safety, tolerability, pharmacokinetics, and early bactericidal activity of PA-824 in drug-sensitive, sputum smear-positive adult pulmonary-tuberculosis patients to find the lowest dose giving optimal bactericidal activity (EBA). Fifteen patients per cohort received oral PA-824 in doses of 50 mg, 100 mg, 150 mg, or 200 mg per kg body weight per day for 14 days. Eight subjects received once-daily standard antituberculosis treatment with isoniazid, rifampin, pyrazinamide, and ethambutol (HRZE) as a positive control. The primary efficacy endpoint was the mean rate of decline in log CFU of Mycobacterium tuberculosis in sputum incubated on agar plates from serial overnight sputum collections, expressed as log(10) CFU/day/ml sputum (± standard deviation). The mean 14-day EBA of HRZE was consistent with previous studies (0.177 ± 0.042), and that of PA-824 at 50 mg, 100 mg, 150 mg, and 200 mg was 0.063 ± 0.058, 0.091 ± 0.073, 0.078 ± 0.074, and 0.112 ± 0.070, respectively. Although the study was not powered for testing the difference between arms, there was a trend toward significance, indicating a lower EBA at the 50-mg dose. Serum PA-824 levels were approximately dose proportional with respect to the area under the time-concentration curve. All doses were safe and well tolerated with no dose-limiting adverse events or clinically significant QTc changes. A dose of 100 mg to 200 mg PA-824 daily appears to be safe and efficacious and will be further evaluated as a component of novel antituberculosis regimens for drug-sensitive and drug-resistant tuberculosis.     

Lack of pharmacokinetic interaction between cefepime and amikacin in humans.

The interaction potential between cefepime and amikacin was investigated in a steady-state pharmacokinetic study in 16 healthy male subjects. Eight subjects (group A) received a first course of 2,000 mg of cefepime; this was followed by a second course of 2,000 mg of cefepime with 300 mg of amikacin and a third course of 2,000 mg of cefepime. Eight other subjects (group B) received a first course of 300 mg of amikacin, a second course of 300 mg of amikacin with 2,000 mg of cefepime, and a third course of 300 mg of amikacin. Each course consisted of four consecutive doses administered every 8 h as 30-min intravenous infusions. Serial plasma and urine samples, which were collected after administration of the fourth dose of each course, were assayed for cefepime and/or amikacin by validated high-performance liquid chromatographic assays. Trough levels of cefepime and amikacin indicated that these antibiotics attained a steady state prior to administration of the fourth dose of each course. Key pharmacokinetic parameters for each antibiotic were determined by noncompartmental methods. The peak concentrations of cefepime and amikacin in plasma when the drugs were given alone were about 160 and 27 micrograms/ml, respectively. Levels of each antibiotic in plasma declined, with an apparent half-life of approximately 2.2 h. Urinary recovery of cefepime and amikacin accounted for more than 85% of the administered dose of each antibiotic. Mean renal clearances for cefepime and amikacin ranged from 79 to 95 ml/min and suggested that glomerular filtration is the primary excretion mechanism. The results of the statistical analyses indicated that the pharmacokinetic parameters of cefepime following the concurrent administration of amikacin and following the discontinuation of the amikacin following the concurrent administration of cefepime and following the discontinuation of the cefepime therapy were not significantly altered. Cefepime and amikacin can be coadministered to patients with normal renal function by using the standard recommended dosing regimens.     

PA-824 exhibits time-dependent activity in a murine model of tuberculosis

PA-824 is one of two nitroimidazoles in phase II clinical trials to treat tuberculosis. In mice, it has dose-dependent early bactericidal and sterilizing activity. In humans with tuberculosis, PA-824 demonstrated early bactericidal activity (EBA) at doses ranging from 200 to 1,200 mg per day, but no dose-response effect was observed. To better understand the relationship between drug exposure and effect, we performed a dose fractionation study in mice. Dose-ranging pharmacokinetic data were used to simulate drug exposure profiles. Beginning 2 weeks after aerosol infection with Mycobacterium tuberculosis, total PA-824 doses from 144 to 4,608 mg/kg were administered as 3, 4, 8, 12, 24, or 48 divided doses over 24 days. Lung CFU counts after treatment were strongly correlated with the free drug T(>MIC) (R(2) = 0.87) and correlated with the free drug AUC/MIC (R(2) = 0.60), but not with the free drug C(max)/MIC (R(2) = 0.17), where T(>MIC) is the cumulative percentage of the dosing interval that the drug concentration exceeds the MIC under steady-state pharmacokinetic conditions and AUC is the area under the concentration-time curve. When the data set was limited to regimens with dosing intervals of ≤72 h, both the T(>MIC) and the AUC/MIC values fit the data well. Free drug T(>MIC) of 22, 48, and 77% were associated with bacteriostasis, a 1-log kill, and a 1.59-log kill (or 80% of the maximum observed effect), respectively. Human pharmacodynamic simulations based on phase I data predict 200 mg/day produces free drug T(>MIC) values near the target for maximal observed bactericidal effect. The results support the recently demonstrated an EBA of 200 mg/day and the lack of a dose-response between 200 and 1,200 mg/day. T(>MIC), in conjunction with AUC/MIC, is the parameter on which dose optimization of PA-824 should be based.     

Population Modeling and Simulation Study of the Pharmacokinetics and Antituberculosis Pharmacodynamics of Isoniazid in Lungs

Among first-line antituberculosis drugs, isoniazid (INH) displays the greatest early bactericidal activity (EBA) and is key to reducing contagiousness in treated patients. The pulmonary pharmacokinetics and pharmacodynamics of INH have not been fully characterized with modeling and simulation approaches. INH concentrations measured in plasma, epithelial lining fluid, and alveolar cells for 89 patients, including fast acetylators (FAs) and slow acetylators (SAs), were modeled by use of population pharmacokinetic modeling. Then the model was used to simulate the EBA of INH in lungs and to investigate the influences of INH dose, acetylator status, and M. tuberculosis MIC on this effect. A three-compartment model adequately described INH concentrations in plasma and lungs. With an MIC of 0.0625 mg/liter, simulations showed that the mean bactericidal effect of a standard 300-mg daily dose of INH was only 11% lower for FA subjects than for SA subjects and that dose increases had little influence on the effects in either FA or SA subjects. With an MIC value of 1 mg/liter, the mean bactericidal effect associated with a 300-mg daily dose of INH in SA subjects was 41% greater than that in FA subjects. With the same MIC, increasing the daily INH dose from 300 mg to 450 mg resulted in a 22% increase in FA subjects. These results suggest that patients infected with M. tuberculosis with low-level resistance, especially FA patients, may benefit from higher INH doses, while dose adjustment for acetylator status has no significant impact on the EBA in patients with low-MIC strains.     

Multiple-dose pharmacokinetics of amikacin and ceftazidime in critically ill patients with septic multiple-organ failure during intermittent hemofiltration.

The pharmacokinetic parameters of amikacin and ceftazidime were assessed in four patients undergoing hemofiltration for septic shock. The parameters were assessed during hemofiltration and in the interim period. The concentration-time profiles of these two drugs in plasma, urine, and ultrafiltrate were investigated after intravenous perfusion (30 min). In all cases a 1-g dose of ceftazidime was administered; for amikacin, the dosage regimen was adjusted according to the patient's amikacin levels (250 to 750 mg). Concentrations of drug in all samples were assayed by high-performance liquid chromatography with UV detection for ceftazidime and by enzyme multiplied immunoassay for amikacin. The elimination half-life (t1/2) and the total clearance of amikacin ranged from 31.1 to 138.2 h and from 5.4 to 8.9 ml/min, respectively, during the interhemofiltration period in anuric patients. Hemofiltration substantially decreased the t1/2 (3.5 +/- 0.49 h) and increased the total clearance (89.5 +/- 11.8 ml/min). The hemofiltration clearance of amikacin represented 71% of the total clearance, and the hemofiltration process removed, on average, 60% of the dose. During hemofiltration, the elimination t1/2 of ceftazidime (2.8 +/- 0.69 h) was greatly reduced and the total clearance increased (74.2 +/- 11.2 ml/min) compared with those in the interhemofiltration period (9 to 43.7 h and 7.4 to 16.8 ml/min, respectively). About 55% of the administered dose was recovered in the filtrate, and the hemofiltration clearance of ceftazidime was 46 +/- 14.3 ml/min. A redistribution phenomenon (rebound) in the amikacin and ceftazidime concentrations in plasma (35 and 28%, respectively) was reported after hemofiltration in two patients. The MICs for 90% of the most important pathogens were exceeded by the concentrations of the two drugs in plasma during the whole treatment of these patients.     

Pharmacokinetics and pharmacodynamics of TMC207 and its N-desmethyl metabolite in a murine model of tuberculosis

TMC207 is a first-in-class diarylquinoline with a new mode of action against mycobacteria targeting the ATP synthase. It is metabolized to an active derivative, N-desmethyl TMC207, and both compounds are eliminated with long terminal half-lives (50 to 60 h in mice) reflecting slow release from tissues such as lung and spleen. In vitro, TMC207 is 5-fold more potent against Mycobacterium tuberculosis than N-desmethyl TMC207, and the effects of the two compounds are additive. The pharmacokinetic and pharmacodynamic (PK-PD) response was investigated in the murine model of tuberculosis (TB) infection following oral administration of different doses of TMC207 or N-desmethyl TMC207 at 5 days per week for 4 weeks starting the day after intravenous infection with M. tuberculosis and following administration of different doses of TMC207 at various dosing frequencies for 6 weeks starting 2 weeks after infection. Upon administration of N-desmethyl TMC207, maximum plasma concentration (C(max)), area under the plasma concentration-time curve from time zero to 168 h postdose (AUC(168h)), and minimum plasma concentration (C(min)) were approximately dose proportional between 8 and 64 mg/kg, and the lung CFU counts were strongly correlated with these pharmacokinetic parameters using an inhibitory sigmoid maximum effect (E(max)) model. Administration of the highest dose (64 mg/kg) produced a 4.0-log(10) reduction of the bacillary load at an average exposure (average concentration [C(avg)] or AUC(168h) divided by 168) of 2.7 μg/ml. Upon administration of the highest dose of TMC207 (50 mg/kg) 5 days per week for 4 weeks, the total reduction of the bacillary load was 4.7 log(10). TMC207 was estimated to contribute to a 1.8-log(10) reduction and its corresponding exposure (C(avg)) was 0.5 μg/ml. Optimal bactericidal activity with N-desmethyl TMC207 was reached at a high exposure compared to that achieved in humans, suggesting a minor contribution of the metabolite to the overall bactericidal activity in TB-infected patients treated with TMC207. Following administration of TMC207 at a total weekly dose of 15, 30, or 60 mg/kg fractionated for either 5 days per week, twice weekly, or once weekly, the bactericidal activity was correlated to the total weekly dose and was not influenced by the frequency of administration. Exposures (AUC(168h)) to TMC207 and N-desmethyl TMC207 mirrored this dose response, indicating that the bactericidal activity of TMC207 is concentration dependent and that AUC is the main PK-PD driver on which dose optimization should be based for dosing frequencies up to once weekly. The PK-PD profile supports intermittent administration of TMC207, in agreement with its slow release from tissues.     

In vivo efficacy of continuous infusion versus intermittent dosing of ceftazidime alone or in combination with amikacin relative to human kinetic profiles in a Pseudomonas aeruginosa rabbit endocarditis model

Ceftazidime and amikacin were administered in a Pseudomonas aeruginosa rabbit endocarditis model using computer-controlled intravenous (iv) infusion pumps to simulate human serum concentrations for the following regimens: continuous (constant rate) infusion of 4, 6 or 8 g of ceftazidime over 24 h or intermittent dosing of 2 g every 8 h either alone or in combination with amikacin (15 mg/kg once daily). The in vivo activities of these regimens were tested on four Pseudomonas aeruginosa strains. Animals were killed 24 h after the beginning of treatment. Efficacy was assessed by comparing the effects of the different groups on bacterial counts in vegetations for each strain tested. For a susceptible reference strain (ATCC 27853; MICs of ceftazidime and amikacin 1 and 2 mg/L, respectively), continuous infusion of 4 g alone or with amikacin was as effective as intermittent dosing with amikacin. For a clinical isolate producing an oxacillinase (MICs of ceftazidime and amikacin 8 and 32 mg/L, respectively), continuous infusion of 6 g was equivalent to intermittent dosing. For a clinical isolate producing a TEM-2 penicillinase (MIC of ceftazidime and amikacin 4 mg/L), continuous infusion of 6 g, but not intermittent dosing, had a significant in vivo effect. For a clinical isolate producing an inducible, chromosomally encoded cephalosporinase (MIC of ceftazidime and amikacin 8 and 4 mg/L, respectively), neither continuous infusion nor intermittent dosing proved effective. Determination of ceftazidime concentrations in vegetations showed that continuous infusion produced tissue concentrations at the infection site far greater than the MIC throughout the treatment. It is concluded that continuous infusion of the same total daily dose provides significant activity as compared with fractionated infusion. This study confirms that a concentration of 4-5 x MIC is a reasonable therapeutic target in most clinical settings of severe P. aeruginosa infection.     

Isoniazid bactericidal activity and resistance emergence: integrating pharmacodynamics and pharmacogenomics to predict efficacy in different ethnic populations

Isoniazid, administered as part of combination antituberculosis therapy, is responsible for most of the early bactericidal activity (EBA) of the regimen. However, the emergence of Mycobacterium tuberculosis resistance to isoniazid is a major problem. We examined the relationship between isoniazid exposure and M. tuberculosis microbial kill, as well as the emergence of resistance, in our in vitro pharmacodynamic model of tuberculosis. Since single-nucleotide polymorphisms of the N-acetyltransferase-2 gene lead to two different clearances of isoniazid from serum in patients, we simulated the isoniazid concentration-time profiles encountered in both slow and fast acetylators. Both microbial kill and the emergence of resistance during monotherapy were associated with the ratio of the area under the isoniazid concentration-time curve from 0 to 24 h (AUC(0-24)) to the isoniazid MIC. The time in mutant selection window hypothesis was rejected. Next, we utilized the in vitro relationship between the isoniazid AUC(0-24)/MIC ratio and microbial kill, the distributions of isoniazid clearance in populations with different percentages of slow and fast acetylators, and the distribution of isoniazid MICs for isonazid-susceptible M. tuberculosis clinical isolates in Monte Carlo simulations to calculate the EBA expected for approximately 10,000 patients treated with 300 mg of isoniazid. For those patient populations in which the proportion of fast acetylators and the isoniazid MICs were high, the average EBA of the standard dose was approximately 0.3 log(10) CFU/ml/day and was thus suboptimal. Our approach, which utilizes preclinical pharmacodynamics and the genetically determined multimodal distributions of serum clearances, is a preclinical tool that may be able to predict the EBAs of various doses of new antituberculosis drugs.     

Adaptive resistance of Pseudomonas aeruginosa induced by aminoglycosides and killing kinetics in a rabbit endocarditis model.

Adaptive resistance following the first exposure to aminoglycosides is a recently described in vitro phenomenon in Pseudomonas aeruginosa and other aerobic gram-negative bacilli. We investigated the in vivo relevance of adaptive resistance in P. aeruginosa following a single dose of amikacin in the experimental rabbit endocarditis model. Rabbits with P. aeruginosa endocarditis received either no therapy (control) or a single intravenous (i.v.) dose of amikacin (80 mg/kg of body weight) at 24 h postinfection, after which they were sacrificed at 5, 8, 12, 16, or 24 h postdose. Excised aortic vegetations were subsequently exposed ex vivo to amikacin at 2.5, 5, 10 or 20 times the MIC for 90 min. In vivo adaptive resistance was identified when amikacin-induced pseudomonal killing within excised aortic vegetations was less in animals receiving single-dose amikacin in vivo than in vegetations from control animals not receiving amikacin in vivo. Maximal adaptive resistance occurred between 8 and 16 h after the in vivo amikacin dose, with complete refractoriness to ex vivo killing by amikacin seen at 12 h postdose. By 24 h postdose, bacteria within excised vegetations had partially recovered their initial amikacin susceptibility. In a parallel treatment study, we demonstrated that amikacin given once daily (but not twice daily) at a total dose of 80 mg/kg i.v. for 1-day treatment significantly reduced pseudomonal densities within aortic vegetations versus those in untreated controls. When therapy was continued for 3 days with the same total daily dose (80 mg/kg/day), amikacin given once or twice daily significantly reduced intravegetation pseudomonal densities versus those in controls. However, amikacin given once daily was still more effective than the twice-daily regimen. These data confirm the induction of aminoglycoside adaptive resistance in vivo and further support the advantages of once-daily aminoglycoside dosing regimens in the treatment of serious pseudomonal infections.     

Comparison of azlocillin, ceftizoxime, cefoxitin, and amikacin alone and in combination against Pseudomonas aeruginosa in a neutropenic-site rabbit model.

The efficacy of beta-lactam antibiotics and amikacin alone and in various combinations against Pseudomonas aeruginosa was studied in a rabbit model simulating a closed-space infection in a locally neutropenic site. Six strains of P. aeruginosa were studied in semipermeable chambers placed subcutaneously in rabbits. Therapy was begun 4 h after inoculation of 5 X 10(4) CFU of bacteria per ml of pooled rabbit serum into the chambers. Antibiotics were administered intramuscularly every 6 h for 16 doses. Quantitative bacteriology was measured at the start of therapy and at 20, 44, and 92 h thereafter. Antibiotic concentrations were measured in blood and chamber fluid. Results were compared with in vitro tests of susceptibility and synergy. No single-agent therapy eradicated any of the six test organisms. Azlocillin (100 mg/kg per dose) plus amikacin (20 mg/kg per dose) eliminated five of six organisms by 92 h, and ceftizoxime (100 mg/kg per dose) plus amikacin (20 mg/kg per dose) eliminated three of six test strains. Azlocillin plus ceftizoxime (each 100 mg/kg per dose) failed to eliminate any of the six strains. To eliminate P. aeruginosa in this model, two drugs were required, with one being an aminoglycoside. In vitro susceptibility tests of synergy were predictive of successful therapy whenever the antibiotic concentrations (free and total) at the infection site exceeded the MBC for both the aminoglycoside alone and the beta-lactam when tested in combination with amikacin.     

Quantification of amikacin in bronchial epithelial lining fluid in neonates

Amikacin efficacy is based on peak concentrations and the possibility of reaching therapeutic levels at the infection site. This study aimed to describe amikacin concentrations in the epithelial lining fluid (ELF) through bronchoalveolar lavage (BAL) in newborns. BAL fluid was collected in ventilated neonates treated with intravenous (i.v.) amikacin. Clinical characteristics, amikacin therapeutic drug monitoring serum concentrations, and the concentrations of urea in plasma were extracted from the individual patient files. Amikacin and urea BAL fluid concentrations were determined using liquid chromatography with pulsed electrochemical detection (LC-PED) and capillary electrophoresis with capacitively coupled contactless conductivity detection (CE-C(4)D), respectively. ELF amikacin concentrations were converted from BAL fluid concentrations through quantification of dilution (urea in plasma/urea in BAL fluid) during the BAL procedure. Twenty-two observations in 17 neonates (postmenstrual age, 31.9 [range, 25.1 to 41] weeks; postnatal age, 3.5 [range, 2 to 37] days) were collected. Median trough and peak amikacin serum concentrations were 2.1 (range, 1 to 7.1) mg/liter and 39.1 (range, 24.1 to 73.2) mg/liter; the median urea plasma concentration was 30 (8 to 90) mg/dl. The median amikacin concentration in ELF was 6.5 mg/liter, the minimum measured concentration was 1.5 mg/liter, and the maximum (peak) was 23 mg/liter. The highest measured ELF concentration was reached between 6 and 14.5 h after i.v. amikacin administration, and an estimated terminal elimination half-life was 8 to 10 h. The median and highest (peak) ELF amikacin concentrations observed in our study population were, respectively, 6.5 and 23 mg/liter. Despite the frequent use of amikacin in neonatal (pulmonary) infections, this is the first report of amikacin quantification in ELF in newborns.     

Pharmacokinetics and in vivo activity of liposome-encapsulated gentamicin.

Gentamicin sulfate was encapsulated in liposomes composed solely of egg phosphatidylcholine and administered via intravenous injection to rats and mice. The total gentamicin activity (regardless of whether it was free or liposome associated) in serum and selected tissues was determined for 24 h (serum) or up to 15 weeks (tissues) by using a microbiological assay. The mean half-lives in serum of a single 20-mg/kg dose of free (nonencapsulated) gentamicin in mice and rats were estimated to be 1.0 and 0.6 h, respectively, whereas a similar dose of encapsulated drug had apparent mean half-lives of 3.8 h in mice and 4.0 h in rats. In both species, the apparent half-life in serum of the liposomal formulation increased as the dose increased. Liposome encapsulation resulted in higher and more prolonged activity in organs rich in reticuloendothelial cells (especially spleen and liver). In acute septicemia infections in mice, the liposomal formulation showed enhanced prophylactic activity (as determined by calculation of the 50% protective dose). In a model of murine salmonellosis, liposomal gentamicin greatly enhanced survival when given as a single dose (10 mg/kg) at 1 or 2 days after infection as well as up to 7 days before infection.     

Determination of optimal dosage regimen for amikacin in healthy volunteers by study of pharmacokinetics and bactericidal activity.

The pharmacokinetics and serum killing curves of amikacin, which was administered by a 30-minute intravenous infusion of single doses of 7.5 mg/kg and then 15 mg/kg, were investigated in six healthy volunteers who received the two doses in a crossover study with a washout period of 20 days. The serum killing curves were determined for four bacterial species: Escherichia coli, Serratia marcescens, Enterobacter cloacae, and Pseudomonas aeruginosa. All strains were serum resistant, and the bactericidal activity was analyzed by separating the early phase (first 5 h) and the late phase (24 h) of the killing curve. For the early phase, the bactericidal activity was evaluated by correlating an index of surviving bacteria with amikacin concentrations. This methodology allowed determination of two parameters: the maximal effective concentration and the lowest effective concentration. For the late phase, the threshold values separating bacteriostatic and bactericidal activities were lower than 10 mg/liter for each strain. The concentration dependence of amikacin bactericidal activity was confirmed for Escherichia coli and Enterobacter cloacae and, to a lesser extent, for Serratia marcescens and Pseudomonas aeruginosa. Correlation of these data with amikacin pharmacokinetic data in volunteers indicated that a daily dose of 15 mg/kg may be effective in the treatment of Escherichia coli and Enterobacter cloacae infections. For Pseudomonas aeruginosa and Serratia marcescens, the partially time-dependent activity probably necessitates two daily administrations and combination with another antibiotic.     

Activity of micafungin (FK463) against an itraconazole-resistant strain of Aspergillus fumigatus and a strain of Aspergillus terreus demonstrating in vivo resistance to amphotericin B

We compared the activity of four doses of micafungin (FK463) with that of amphotericin B, liposomal amphotericin B and itraconazole in a murine model of disseminated aspergillosis. Temporarily neutropenic mice were infected with a lethal dose of either an itraconazole-resistant Aspergillus fumigatus isolate or Aspergillus terreus, a species that is less susceptible to amphotericin B. Treatment was started 24 h after infection and lasted for 7 days. Mice were treated with either amphotericin B (0.5 or 5 mg/kg), liposomal amphotericin (5 or 25 mg/kg), itraconazole (25 or 75 mg/kg) or FK463 (either 1, 2, 5 or 10 mg/kg). Treatment of the A. fumigatus model with either amphotericin B, liposomal amphotericin or FK463 prolonged survival. Doses of FK463 5 and 10 mg/kg had a 100% survival. Treatment of A. terreus infection with either itraconazole or FK463, but not amphotericin B, also prolonged survival. Doses of liposomal amphotericin of 5 and 25 mg/kg were ineffective against A. terreus infection. No treatment regime was able to totally clear the liver or kidneys in either model. The data indicate that FK463 may have a clinical role in the treatment of life-threatening invasive aspergillosis.     

结核分支杆菌对阿米卡星的耐药性研究

目的了解阿米卡星对耐药结核分支杆菌是否有效。方法5种不同浓度的抗结核药物培养基内加入结核分支杆菌浓度为0．1mg／mL的菌液0．1mL,4周后观察耐药情况。结果5种抗结核药物不同浓度,对结核分支杆菌有不同的敏感性和耐药性,其中以加入阿米卡星药物抗菌活性良好。结论阿米卡星为二线抗结核药物,对治疗耐药结核分支杆菌有效。     

Pharmacokinetic and pharmacodynamic approach for comparing two therapeutic regimens using amikacin.

The efficiencies of two dosage schedules of amikacin (2 x 10 mg/kg of body weight per 24 h and 1 x 20 mg/kg/24 h intramuscularly for 5 days) against Pseudomonas aeruginosa sepsis in rabbits were compared. Blood samples were drawn at various times after the first application, and amikacin concentrations in serum were assayed microbiologically. The dynamics of the bactericidal effect of amikacin was simulated in vitro with the same strain of P. aeruginosa. No regrowth was found with the 20-mg/kg dose when the bacterial inoculum was in contact with experimental and theoretically predicted serum amikacin concentrations. The killing effect was present even when the drug levels decreased considerably below the MIC. The interrelationship between simulated amikacin concentrations in serum and the corresponding average killing rates was described appropriately by the standard Emax model. The higher amikacin dose performed its bacterial effect faster and the drug persisted longer in the blood. The two amikacin regimens were therapeutically equivalent, but the once-daily schedule had some advantages over the twice-daily drug administration which became evident when both the pharmacokinetic and the pharmacodynamic parameters of the drug were considered.     

Pharmacokinetics, excretion, and mass balance of liposomal amphotericin B (AmBisome) and amphotericin B deoxycholate in humans

The pharmacokinetics, excretion, and mass balance of liposomal amphotericin B (AmBisome) (liposomal AMB) and the conventional formulation, AMB deoxycholate (AMB-DOC), were compared in a phase IV, open-label, parallel study in healthy volunteers. After a single 2-h infusion of 2 mg of liposomal AMB/kg of body weight or 0.6 mg of AMB-DOC/kg, plasma, urine, and feces were collected for 168 h. The concentrations of AMB were determined by liquid chromatography tandem mass spectrometry (plasma, urine, feces) or high-performance liquid chromatography (HPLC) (plasma). Infusion-related side effects similar to those reported in patients, including nausea and back pain, were observed in both groups. Both formulations had triphasic plasma profiles with long terminal half-lives (liposomal AMB, 152 +/- 116 h; AMB-DOC, 127 +/- 30 h), but plasma concentrations were higher (P < 0.01) after administration of liposomal AMB (maximum concentration of drug in serum [C(max)], 22.9 +/- 10 microg/ml) than those of AMB-DOC (Cmax, 1.4 +/- 0.2 microg/ml). Liposomal AMB had a central compartment volume close to that of plasma (50 +/- 19 ml/kg) and a volume of distribution at steady state (Vss) (774 +/- 550 ml/kg) smaller than the Vss of AMB-DOC (1,807 +/- 239 ml/kg) (P < 0.01). Total clearances were similar (approximately 10 ml hr(-1) kg(-1)), but renal and fecal clearances of liposomal AMB were 10-fold lower than those of AMB-DOC (P < 0.01). Two-thirds of the AMB-DOC was excreted unchanged in the urine (20.6%) and feces (42.5%) with >90% accounted for in mass balance calculations at 1 week, suggesting that metabolism plays at most a minor role in AMB elimination. In contrast, <10% of the liposomal AMB was excreted unchanged. No metabolites were observed by HPLC or mass spectrometry. In comparison to AMB-DOC, liposomal AMB produced higher plasma exposures and lower volumes of distribution and markedly decreased the excretion of unchanged drug in urine and feces. Thus, liposomal AMB significantly alters the excretion and mass balance of AMB. The ability of liposomes to sequester drugs in circulating liposomes and within deep tissue compartments may account for these differences.     

Revisiting the loading dose of amikacin for patients with severe sepsis and septic shock

Introduction

It has been proposed that doses of amikacin of >15 mg/kg should be used in conditions associated with an increased volume of distribution (V_d), such as severe sepsis and septic shock. The primary aim of this study was to determine whether 25 mg/kg (total body weight) of amikacin is an adequate loading dose for these patients.

Methods

This was an open, prospective, multicenter study in four Belgian intensive care units (ICUs). All consecutive patients with a diagnosis of severe sepsis or septic shock, in whom amikacin treatment was indicated, were included in the study.

Results

In 74 patients, serum samples were collected before (t = 0 h) and 1 hour (peak), 1 hour 30 minutes, 4 hours 30 minutes, 8 hours, and 24 hours after the first dose of amikacin. Blood amikacin levels were measured by using a validated fluorescence polarization immunoassay method, and an open two-compartment model with first-order elimination was fitted to concentrations-versus-time data for amikacin (WinNonlin). In 52 (70%) patients, peak serum concentrations were >64 μg/ml, which corresponds to 8 times the clinical minimal inhibitory concentration (MIC) breakpoints defined by EUCAST for Enterobacteriaceae and Pseudomonas aeruginosa (S<8, R>16 μg/ml). V_d was 0.41 (0.29 to 0.51) L/kg; elimination half-life, 4.6 (3.2 to 7.8) hours; and total clearance, 1.98 (1.28 to 3.54) ml/min/kg. No correlation was found between the amikacin peak and any clinical or hemodynamic variable.

Conclusions

As patients with severe sepsis and septic shock have an increased V_d, a first dose of ≥ 25 mg/kg (total body weight) of amikacin is required to reach therapeutic peak concentrations. However, even with this higher amikacin dose, the peak concentration remained below therapeutic target levels in about one third of these patients. Optimizing aminoglycoside therapy should be achieved by tight serum-concentration monitoring because of the wide interindividual variability of pharmacokinetic abnormalities.