Dalbavancin: Quantification in human plasma and urine by a new improved high performance liquid chromatography-tandem mass spectrometry method.

Dalbavancin is a novel second-generation lipoglycopeptide antibiotic with activity against broad range of Gram-positive pathogens. In order to determine the pharmacokinetics (PK) of dalbavancin in pediatric patients, a new High Performance Liquid Chromatography-Tandem Mass Spectrometry (HPLC-MS/MS) bioanalytical method has been developed for quantification of dalbavancin in plasma and in urine. The plasma method was validated for dalbavancin in the linear range from 0.5 µg/mL to 500 µg/mL using 50 µL of K(2) EDTA plasma. For dalbavancin spiked in urine, non-specific binding (NSB) of the drug to polypropylene (PP) urine collection containers was observed. The loss amounted to about 10% per transfer. After successfully establishing the collection/sampling procedure for urine by addition of Triton X-100 to the collection vessels (with a purpose of preventing NSB), the method was validated for dalbavancin in the range from 0.05 µg/mL to 50 µg/mL, using 100 µL of urine. These methods were used to quantify dalbavancin in plasma and urine of hospitalized children in a pediatric dalbavancin PK study. Eighteen percent of the total number of plasma study samples was reassayed for incurred samples reproducibility (ISR) and all the reassayed dalbavancin concentrations were within the ± 20% limits. For urine, all the collected samples were reassayed for ISR and the original dalbavancin concentration was confirmed within the ± 20% limits for 17 (94%) samples; the one remaining urine sample had its reassayed concentration confirmed within ± 25% of the original result.

The pharmacokinetics of teicoplanin in infants and children.

The pharmacokinetics of teicoplanin were assessed after a single dose and under multidose conditions in 12 infants and children. Study patients ranged in age from 2.4 to 11 years. Each patient received teicoplanin 6 mg/kg body weight given intravenously over 20-30 min, once daily for five consecutive days. Multiple timed blood and urine samples were obtained over the 6 day sampling period and were analysed for teicoplanin by both microbiological assay and HPLC. Three-compartment pharmacokinetic analysis was used to describe the drug's disposition characteristics. Peak and 24 h trough serum teicoplanin concentrations averaged 39.3 and 1.8 mg/L after the first dose with little accumulation observed after 5 days of therapy. Teicoplanin disposition was variable; V(d)ss ranged from 0.31 to 0.68 L/kg, t(1/2)gamma from 6.5 to 18.1 h and CI from 29 to 51 mL/h/kg. A substantial amount of the administered drug distributed rapidly to the largest, third compartment, with egress approximately four-fold slower than ingress. The majority of the drug was excreted unchanged in the urine. Teicoplanin administration was well tolerated by all study subjects. Using the teicoplanin pharmacokinetic data derived in our study, a dose of teicoplanin 8 mg/kg body weight administered every 12 h should achieve target serum trough concentrations averaging 11 mg/L in children. Higher doses, e.g. 15 mg teicoplanin/kg administered every 12 h, may be needed for the treatment of deep-seated staphylococcal infections and/or endocarditis.

[Therapeutic monitoring of teicoplanin in a severely burned patient]. / Suivi thérapeutique de la teicoplanine chez un sujet gravement brûlé.

The authors report the study of the kinetics in serum and urine and the clinical safety of a high dose of teicoplanin administered in a 19 year-old patient with major burns (60% of body surface area, the half of which consisting of third-degree burns and UBS at 150) and S aureus meticillin-resistant infection. At day 1, he was given two loading infusions of 12 mg.kg-1 teicoplanin followed by 12 mg.kg-1 per day of treatment. At all times, Cmin concentrations were below the limit value of 8 mg.mL-1. Therefore the therapeutic regimen was increased on several occasions. On days 5, 8 and 15, Cmin were measured by FPIA. Pharmacokinetic analysis was performed at day 16, (i.e., 20 mg.kg-1) and urine was also collected over at least 12 hours. At day 16, serum and urine samples were assayed by HPLC. Data were analyzed with a noncompartmental method. The duration of treatment was 20 days and no adverse events were noted. Bacteriological tests performed at the end of treatment demonstrated the elimination of the agent responsible over the infection. While pharmacokinetics were not assessed at plateau, Cmin remained very low. Vss was similar to values obtained in healthy subjects while total clearance was increased. This phenomenon was explained by the increase of total clearance and a nonrenal translesional diffusion suggested by the body surface area affected by third-degree burns. Finally, the cost of increasing doses of teicoplanin must be taken in account.

Effect of morphine or phenobarbital on teicoplanin elimination pharmacokinetics.

Elimination kinetics following a single dose of teicoplanin in rats pre-treated with morphine sulphate (MS), phenobarbital sodium (Pb), and normal saline (NS) were determined. A microbioassay was used to measure teicoplanin levels. A significant increase in the total clearance of teicoplanin was found in rats pre-treated with MS as compared to controls (P < 0.048). Wide variability was observed in the renal and non-renal clearances of teicoplanin. The mean renal clearance for rats pre-treated with MS, Pb and NS was 0.61 +/- 0.07.mL/min/kg, 0.60 +/- 0.13 mL/min/kg, and 0.46 +/- 0.02 mL/min/kg, respectively; the mean non-renal clearance was 0.33 +/- 0.18 mL/min/kg, 0.17 +/- 0.15 mL/min/kg, and 0.08 +/- 0.03 mL/min/kg, respectively. The differences among the groups for renal and non-renal clearance were not statistically significant. The mean apparent volume of distribution of teicoplanin at steady state was significantly lower in the Pb-pre-treated rats as compared to controls (P < 0.043). The mean half-life for MS-, Pb-, and NS pre-treated groups was 8.1 +/- 3.1 h, 5.9 +/- 3.3 h, and 34.6 +/- 20.7 h, respectively. The differences in mean half-life among the groups achieved statistical significance (P < 0.016). The increase in the total clearance of teicoplanin can best be explained by an increase in both renal elimination and hepatic metabolic pathways.

Teicoplanin metabolism in humans.

Teicoplanin, a lipoglycopeptide antibiotic, consists of five major components (A2-1 through A2-5), one hydrolysis component (A3-1), and four minor components (RS-1 through RS-4). All the major components contain an N-acyl-beta-D-glucosamine, but they differ in the lengths and branchings of their acyl-aliphatic chains. Previous studies with radiolabeled teicoplanin in rats and humans have shown that the drug is eliminated by the renal route and that metabolic transformation is very minor, about 5%. A possible metabolic transformation of teicoplanin into A3-1 was also suggested. In the present study in humans, two metabolites (metabolites 1 and 2; 2 to 3% of total teicoplanin) were isolated after intravenous administration of radiolabeled teicoplanin. After purification, their structures were determined by fast atom bombardment mass spectroscopy and 1H nuclear magnetic resonance spectroscopy on the basis of the well-known correlations established in this field, and they were found to be new teicoplaninlike molecules, bearing 8-hydroxydecanoic and 9-hydroxydecanoic acyl moieties. This metabolic transformation is likely due to hydroxylation in the omega-2 and omega-1 positions for metabolites 1 and 2, respectively, of the C-10 linear side chain of component A2-3. This might explain the low extent of metabolism of teicoplanin if we consider that only component A2-3 has a linear chain that is susceptible to such oxidation.