Hilde Vandenberghe scite author profile

The pharmacokinetics of amikacin administered intravenously at currently recommended doses (7.5 mg/kg every 12 h for infants with less than 7 days of life; 7.5 mg/kg every 8 h for infants with greater than 7 days of life) were studied in 28 preterm infants weighing less than 2,500 g (mean + standard deviation, 1.38 0.47 kg; postconceptional age, 30.50 ± 2.86 weeks). The medication was infused over 45 min. Trough and peak serum samples as well as two additional samples were taken at steady state. The results showed a statistically significant inverse relationship between half-life (8.42 ± 2.55 h) and postconceptional age (P = 0.002) and a direct correlation between total body clearance (0.84 ± 0.28 ml/min per kg) and postconceptional age (P = 0.02). These pharmacokinetic data were used to calculate a new dosage schedule for preterm infants. The derived intravenous dosage of amikacin for infants of less than 30 weeks of postconceptional age was 9 mg/kg every 18 h. For infants of greater than 30 weeks of postconceptional age, the dosage was 9 mg/kg every 12 h. Peak and trough levels of amikacin in serum that fell within the therapeutic range were compared by using the currently recommended dosage schedule and the dosage schedule derived from our pharmacokinetic data. There was a reduction in the number of peak and trough levels that fell outside the accepted therapeutic range which was not statistically significant. Extension of the dosing interval and a further increase in the dosage may result in further improvement. Based on these data, the current recommendations are inadequate for the preterm infant. Our derived dosage schedule improved but did not eliminate high trough and low peak levels of amikacin in all infants. The current recommendations should be adjusted for the preterm infant. Ongoing therapeutic drug monitoring is essential to tailor the amikacin dosage to the individual patient.

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Performance evaluation of three liquid chromatography mass spectrometry methods for broad spectrum drug screening

Lynch

Breaud²,

Vandenberghe

et al. 2010

Clinica Chimica Acta

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BACKGROUND Liquid chromatography-mass spectrometry (LC-MS) and tandem LC-MS (LC-MS/MS) are increasingly used in toxicology laboratories as a complementary method to gas chromatography-mass spectrometry (GC-MS) and liquid chromatography-ultraviolet detection (LC-UV) for comprehensive drug screening (CDS). This study was designed to characterize the sensitivity and specificity of three LC-MS(/MS) vendor-supplied methods for targeted CDS and identify the current limitations associated with the use of these technologies. METHODS Five methods for broad spectrum CDS, including LC-UV (REMEDi), full scan GC-MS, LC-MS (ZQ™-Mass Detector with MassLynx™-software), LC-QTRAP-MS/MS (3200-QTRAP® with Cliquid®-software) and LC-LIT-MS/MS (LXQ™ Linear Ion Trap with ToxID™-software) were evaluated based on their ability to detect drugs in 48 patient urine samples. RESULTS The tandem MS methods identified 15% more drugs than the single stage MS or LC-UV methods. Use of two broad spectrum screening methods identified more drugs than any single system alone. False negatives and false positives generated by the LC-MS(/MS) software programs were identified upon manual review of the raw data. CONCLUSIONS The LC-MS/MS methods detected a broader menu of drugs; however, it is essential to establish manual data review criteria for all LC-MS(/MS) drug screening methods. Use of an EI-GC-MS and ESI-LC-MS/MS combination for targeted CDS may be optimal due to the complementary nature of the chromatographic and ionization techniques.

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Ranitidine kinetics and dynamics: I. Oral dose studies

Lebert

MacLeod

Mahon

et al. 1981

Clin Pharmacol Ther

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Ranitidine, an H2-receptor antagonist, has been shown to reduce pentagastrin-stimulated gastric secretion. We examined the relationship between inhibition of gastric secretion and ranitidine serum concentration. Twelve normal male subjects received 20, 40, or 80 mg of ranitidine orally 90 min before starting a 3-hr continuous infusion of pentagastrin, 2 micrograms/kg/hr. Ranitidine, 20, 40, and 80 mg, reduced hydrogen ion output by 29%, 50%, and 70% and secretion volume by 21%, 37%, and 47%. Pepsin activity was reduced by 8%, 50%, and 49% by the same doses. Peak serum concentration was correlated positively with percent reduction in hydrogen ion output (r = 0.81, P less than 0.001) and volume (r = 0.71, P less than 0.01) over a 2-hr period. A 50% inhibition of hydrogen ion output was associated with a peak ranitidine serum concentration of 165 micrograms/l and subjects reached peak serum concentration 60 to 120 min after oral dosing. An appropriate therapeutic effect should be achieved with 8 hourly doses of 80 mg ranitidine. No clinically significant subjective or toxic biochemical effect of ranitidine was seen after single doses. White blood cell count was reduced in 11 of 12 subjects 7 days after ranitidine, an observation which calls for further investigation.

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