A gentamicin pharmacokinetic population model and once-daily dosing algorithm for neonates

STUDY OBJECTIVE: To develop a gentamicin pharmacokinetic population model and once-daily dosing algorithm for neonates younger than 10 days. DESIGN: Prospective, open-label study. SETTING: Neonatal intensive care unit. PATIENTS: One hundred thirty-nine neonates prescribed gentamicin. MEASUREMENTS AND MAIN RESULTS: Gentamicin peak and trough serum concentrations were collected from 139 neonates divided into three groups who were receiving one of the following intravenous 24-hour gentamicin regimens during the first 10 days of life, based on gestational age and birth weight (group 1, < 28 wks, 2.5 mg/kg; group 2, 28-34 wks, 3 mg/kg; and group 3, > 34 wks, 4 mg/kg). A structural model was developed in ADAPT II software using a MAP Bayesian approach. Final population parameter estimates were calculated using iterative two-stage analysis. The median (range) gestational age and birth weight, respectively, were 32 weeks (23-42 wks) and 1.92 kg (0.47-5.00 kg). The final one-compartmental linear model had a median (range) gentamicin total clearance, half-life, and volume of distribution of 0.0709 L/hour (0.0151-0.246 L/hr), 8.59 hours (4.88-16.9 hrs), and 0.262 L (0.0903-0.929 L), respectively. Total clearance increased as gestational age increased (p<0.001). Group 1 (10.2 hrs) had a significantly longer half-life than either group 2 (8.89 hrs, p<0.01) or group 3 (6.98 hrs, p<0.01). Total clearance was associated with gestational age and birth weight: clearance (L/hr) = (0.00504 + [0.00108 x gestational age]) x birth weight (coefficient of determination [r2] = 0.897), and volume of distribution was associated with birth weight (r2 = 0.700). The following dosing algorithm was designed to reach a therapeutic 24-hour area under the curve (87.5 mg/L x hr) in neonates during the first 10 days after birth: 24-hour gentamicin dose (mg) = (0.441 + [0.0945 x gestational age]) x birth weight. CONCLUSION: This dosing algorithm provides a new approach for determining initial gentamicin dosing regimens in neonates; however, clinical validation is required.     

Population pharmacokinetics and dosing of amoxicillin in (pre)term neonates

Amoxicillin plasma concentrations, pharmacokinetic parameters, and the influence of demographic, anthropometric, and clinical covariates were investigated in 150 neonates. Gestational age (GA) ranged from 25 to 42 weeks and mean postnatal age (PNA) was 0.8 days. Amoxicillin concentrations were measured with reversed-phase HPLC in surplus plasma from routine assays of coadministered gentamicin. Mean total body clearance corrected for body weight (CL/W) was 0.096 +/- 0.036 L/kg(-1)h(-1), mean elimination half-life (t(1/2)) was 5.2 +/- 1.9 hours, and mean volume of distribution corrected for body weight (V/W) was 0.65 +/- 0.13 L/kg. Multiple regression equations were calculated for the prediction of CL/W amoxicillin. CL/W gentamicin, V/W gentamicin, and GA were significant predictors of CL/W amoxicillin. Amoxicillin peak and trough concentrations after the second dose and the time the concentration exceeds the minimum inhibitory concentration (T>MIC), reached with the current dosage regimen, were evaluated. Toxic plasma concentrations were reached in several patients. Therefore, the authors have proposed a lower dosage regimen, based on GA, population pharmacokinetic parameters, bacterial susceptibility (T>MIC), and possible toxicity: 15 mg/kg per 8 hours and 20 mg/kg per 8 hours for neonates with GA < or = 34 and GA>34 weeks, respectively. Simulation with this new dosage regimen indicated that satisfactory plasma concentrations were reached in all 150 neonates. Therefore, use of therapeutic drug monitoring and pharmacokinetic calculations for dosage adjustment is generally not necessary.     

Evaluation of an empirical dosing schedule for gentamicin in neonates

The standard gentamicin dosing recommendations for neonates appear to be inappropriate because they fail to consider the influence of neonatal development on gentamicin pharmacokinetics. Recent reports have emphasized that the standard regimens of 2.5 mg/kg q8-12h produce steady-state trough serum concentrations greater than 2 micrograms/ml in up to 91 percent of preterm infants of less than 35 weeks' gestation. A new dosing schedule based on postconceptional age (PCA) was developed to provide a better guideline for initiating and maintaining gentamicin therapy in neonates: PCA greater than 34 weeks, 2.5 mg/kg iv q12h; PCA 28-34 weeks, 2.5 mg/kg iv q16h; PCA less than 28 weeks, 2.5 mg/kg iv q24h. The new dosing schedule reduced the number of neonates with elevated trough concentrations (greater than 2 micrograms/ml) from 68.4 percent to 33-40 percent. Pharmacokinetic parameters for gentamicin in the various PCA groups were determined. Volume of distribution was constant across age groups (0.5 +/- 0.09 L/kg). Elimination rate constants (kel), half-lives, and clearance rates (Cl) ranged from 0.069 +/- 0.02 to 0.14 +/- 0.04 h-1, 10.71 +/- 2.92 to 6.04 +/- 1.24 h, and 0.58 +/- 0.25 to 0.93 +/- 0.24 ml/kg/min, respectively. Significant relationships were found between kel and Cl and patient age and weight; significant correlations were found between actual and estimated (based on PCA and weight) kel and Cl. Variability in kel and Cl estimated was considerable in spite of the correlations. The observed variability stresses again the need for pharmacokinetic monitoring of gentamicin therapy in neonates.     

Population pharmacokinetics and dosing of flucloxacillin in preterm and term neonates

In total 235 flucloxacillin total (free+protein bound) plasma concentrations were determined in 55 neonates (gestational age 26 to 42 weeks, postnatal age 0 to 44 days) with reversed-phase HPLC in surplus plasma samples from routine gentamicin assays. Population pharmacokinetic parameters were calculated according to an one compartment open model with iterative two-stage Bayesian fitting (MWPHARM 3.50, Mediware, The Netherlands). Mean clearance corrected for weight was 0.18+/-0.10 L kgh and volume of distribution corrected for weight was 0.54+/-0.17 L/kg. Pearson correlations between the individual pharmacokinetic parameters and covariates, like gestational age, plasma creatinine, and gentamicin clearance, were low and therefore not relevant for use in clinical practice. Total plasma concentrations above 200 mg/L were considered toxic and T>MIC (time above minimum inhibitory free plasma concentration) of more than 40% was considered effective. Protein binding was assumed to be 86.3% in all neonates, based on literature. The current dosage regimen, 25 or 50 mg/kg every 8 or 12 hours, did not result in effective plasma concentrations for the treatment of Staphylococcus aureus in 17 (31%) of the 55 neonates. Therefore, the authors suggest an initial dose of 25 mg/kg/4 h for all neonates, irrespective of their age, based on the breakpoint MIC value of flucloxacillin for Staphylococcus aureus (2.0 mg/L). After isolation of the causative agent of infection, flucloxacillin administration ought to be reconsidered based on the expected susceptibility pattern of the isolate. When oxacillin sensitive coagulase negative staphylococci are isolated, the initial dose should be reduced to 10 mg/kg/6 h, based on the breakpoint MIC value of 0.25 mg/L. Simulation with these new dosage regimens indicated that satisfactory plasma concentrations were reached in 52 of the 55 neonates. However, the regimens need prospective verification. Moreover, the exact role of neonatal protein binding needs to be further investigated.     

Amoxicillin pharmacokinetics in (preterm) infants aged 10 to 52 days: effect of postnatal age

The pharmacokinetic parameters of amoxicillin were determined in 32 newborn infants aged 10 to 52 days (mean postnatal age, 24.7 +/- 12.4 days) to improve amoxicillin dosing in this age group. Amoxicillin plasma concentrations were determined using reversed-phase high-performance liquid chromatography in surplus plasma samples from routine gentamicin assays. Amoxicillin pharmacokinetic parameters (mean +/- SD) were as follows: first-order elimination constant (K(el)) = 0.27 +/- 0.10 h(-1), volume of distribution corrected for body weight (V/W) = 0.66 +/- 0.27 L/kg, total body clearance corrected for body weight (CL/W) = 0.18 +/- 0.10 Lkg(-1)h(-1), and elimination half-life (t(1/2)) = 3.0 +/- 1.3 hours. Amoxicillin body clearance was approximately twofold greater in our patients compared with published values in younger neonates (mean postnatal age, 0.76 +/- 1.57 days). Simulation studies using the observed amoxicillin pharmacokinetic data suggest an amoxicillin dose of 40 mg/kg administered every 8 hours in infants older than 9 days postnatal age, independent of gestational age and postconceptional age, to achieve satisfactory target plasma amoxicillin concentrations less than 140 mg/L and time above minimum inhibitory concentration of at least 40%. Prospective evaluation of this suggested new dosage regimen is necessary before implementation in the care of ill neonates.     

Time course of trough serum gentamicin concentrations in preterm and term neonates.

Trough serum concentrations (Cmin) of gentamicin were followed during up to 96h of treatment in 44 neonates (17 preterm and 27 term), treated with intramuscular gentamicin 2.5 +/- 0.3 mg/kg (mean +/- SD) twice daily, a dosage that was not changed during the follow-up period. Relationships with patients' gestational age, postnatal age, postconceptional age and bodyweight were analysed to identify circumstances in which gentamicin should be monitored. Gentamicin Cmin values after 24h correlated better with neonate's postconceptional age (r = -0.42) or gestational age (r = -0.37) than with postnatal age or bodyweight. Correlations with postconceptional age and gestational age improved after 96h (r = -0.71 and r = -0.67, respectively). From 24 to 96h Cmin increased from 1.5 to 2 mg/L (p < 0.001) in the preterm neonates and from 1.5 to 2.5 mg/L (p < 0.01) in those preterm neonates < or = 32 weeks of gestational age, while differences between neonates < or = 3 days and > 3 days of postnatal age were nonsignificant. The Cmin at 24h was potentially toxic (> 2 mg/L) in 9% of the neonates (12% of preterm and 7% of term neonates). At 96h, the percentage of neonates with toxic Cmin values increased to 25% (65% of all preterm neonates and 100% of preterm neonates < or = 32 weeks of gestational age), whereas in term neonates it decreased to 0%. In conclusion, in preterm neonates < or = 32 weeks of gestational age a dosage of 2.5 mg/kg every 24h should be used, and gentamicin concentrations should be monitored. However, in term neonates > 7 days of postnatal age a dosage of 3.5 mg/kg twice daily should be recommended.     

The effect of sepsis upon gentamicin pharmacokinetics in neonates

AIM: To investigate the effect of sepsis upon the volume of distribution (Vd) of gentamicin in neonates. METHODS: A retrospective chart review was conducted of neonates admitted to Dunedin Hospital who had gentamicin concentrations performed between 1st January 2000 and 30th October 2003. Data from 277 neonates, including a total of 576 gentamicin concentrations, were included in the pharmacokinetic analysis. Fifteen (5.4%) of the neonates had confirmed sepsis. Pharmacokinetic analyses were performed with NONMEM using a one compartment first order elimination model. Duration of infusion (D) was included as a parameter in the model. Covariates included sepsis (SEP), chronological age, gestational age (GA), birth weight, current weight, gender, Apgar score at 1 (AP1) and 5 (AP2) minutes, plasma C-reactive protein and serum creatinine. RESULTS: The initial model provided a mean estimates of clearance (CL) of 0.0460 l kg(-1) h(-1), volume of distribution (Vd) of 0.483 l kg(-1) and D of 0.748 h. The magnitudes of interpatient variability, expressed as CV%, were 29.2% for CL, 20.8% for Vd and 71.5% for D. The magnitude of residual variability in gentamicin concentrations was 88.0%. The final pharmacokinetic model was: CL = (0.0177 + 0.00147.(GA-20) + 0.000635.AP2) l kg(-1) h(-1), Vd = (0.483 +0.0656. sepsis) l kg(-1), D = 0.672 h. The interpatient variability (CV%) was 22.8% for CL, 22.8% for Vd and 97.7% for D. The magnitude of residual variability in gentamicin concentrations was 83.3%. CONCLUSIONS: The 14% increase in Vd in septic neonates implies that larger doses may be required to achieve peak therapeutic concentrations in the presence of sepsis. D is an important parameter in neonatal pharmacokinetic models.     

Monitoring serum levels of gentamicin to develop a new regimen for gentamicin dosage in newborns

The newborns studied had gestational ages ranging between 23-44 weeks, weights ranging between 725-4510 g, and were treated with standard doses of gentamicin (5.2 +/- 1.0 mg/kg/day). The gentamicin serum peak and trough levels were unrelated to administered doses, and a large proportion of patients had low (peak less than 4 micrograms/ml in 12%) or potentially toxic concentrations (trough greater than 2 micrograms/ml in 55%). The pharmacokinetic parameters (t1/2e, 8.2 +/- 4.8 h and Vd, 0.64 +/- 0.22 L/kg) varied markedly between patients. The newborn's weight, age, gestational age, and serum creatinine were factors of importance for the variability of gentamicin serum levels. The newborns were divided into four groups: gestational period less or more than 37 weeks and age below or above 7 days. These groups had different gentamicin serum levels and pharmacokinetic parameters. The results suggest that a gentamicin dosage regimen based on the division of newborn patients into subgroups or calculated from individual pharmacokinetic characteristics would decrease the risk of obtaining potentially toxic or subtherapeutic gentamicin concentrations after the use of standard doses.     

Population pharmacokinetics of gentamicin in preterm neonates: evaluation of a once-daily dosage regimen.

Population pharmacokinetic parameters of gentamicin in preterm neonates on a once-daily dosage regimen of 3.0 mg/kg given intravenously every 24 hours were established prospectively. In 34 preterm neonates with a mean gestational age of 32 +/- 4 (SD), 182 serum gentamicin levels (91 peak/trough pairs) were determined. Individual adjustments of dose or dosage interval were calculated by computer-aided Bayesian forecasting. The parameters Vd, ke, and CL for each patient were obtained by the nonparametric estimation of maximization method. The predictive power of the model was calculated and the pharmacokinetic estimates were statistically analyzed with SPSS/PC. Cluster analysis showed a division into 2 subpopulations (designated 1 and 2) on the basis of postnatal age. The mean +/- SD postnatal age of subpopulation 1 (n = 29) was 6 +/- 2 days (range 1-7) and of subpopulation 2 (n = 5) 15 +/- 4 days (range 12-24). The mean +/- SD gentamicin relative clearances of subpopulation 1 and subpopulation 2 were 0.0515 +/- 0.0128 and 0.1026 +/- 0.0102 L kg(-1) hr(-1), respectively (p < 0.05). The mean +/- SD values for Vd (Lkg(-1)) in both populations 1 and 2 were 0.6916 +/- 0.1670 and 0.7509 +/- 0.1961, respectively (not significantly different). For ke these data were 0.0744 +/- 0.0200 and 0.1366 +/- 0.0522 (p < 0.05). Statistics showed that the data for Vd and ke of subpopulation 1 were normally distributed (Vd and ke skewness 1.61 and 1.46; kurtosis 3.09 and 3.10 respectively). The model yielded a bias of -0.11 mg/L and a precision of 0.36 mg/L. It is recommended that gentamicin be started in a dosage of 3.5 mg/kg intravenously once-daily under close monitoring.     

Population kinetics of tobramycin in neonates

The population kinetics of tobramycin were studied in 140 neonates (100/40 patients for the index/validation groups, respectively) of 30 to 42 weeks' gestational age and 0.8 to 4.25 kg current body weight in their first 2 weeks of life, undergoing routine therapeutic drug monitoring of their tobramycin serum levels. The 365 tobramycin concentration measurements obtained were analyzed by use of NONMEM according to a one-compartment open model with zero-order absorption and first-order elimination. The effect of a variety of demographic, developmental, and clinical factors (gender, height, birth weight, current weight, gestational age, postnatal age, postconceptional age, and serum creatinine concentration) on clearance and volume of distribution was investigated. Forward selection and backward elimination regression identified significant covariates. The final pharmacostatistical model with influential covariates was as follows (full population): clearance (L/h) = 0.0508 x current weight (kg), multiplied by 0.843 if birth weight was 2.5 kg or less (low-birthweight infants), and volume of distribution (L) = 0.533 x current weight (kg). Using the proportional error model for the random-effects parameters, interindividual variability for clearance and for volume of distribution was determined to be 25.8% and 21.9%, respectively, and the residual variability was 19.2%. In this study, the use of the NONMEM gave significant and consistent information on the pharmacokinetics and the determinants of the pharmacokinetic variability of tobramycin in neonates when compared with available bibliographic information. Moreover, the final population pharmacokinetic model may be used to design a priori recommendations for tobramycin and to improve the dosing readjustments through Bayesian estimation.     

The effect of postnatal age on gentamicin pharmacokinetics in neonates

STUDY OBJECTIVE: To determine if gentamicin serum concentrations obtained from newborns on day 2 of life versus days 3-4 yield significantly different pharmacokinetic parameter values. DESIGN: Retrospective chart review. SETTING: Neonatal intensive care unit. PATIENTS: Two hundred and sixty-seven infants who had peak and trough gentamicin serum concentrations determined on days 2, 3, or 4 of life. INTERVENTION: Determination of peak and trough serum gentamicin concentrations on days 2, 3, or 4 of life. MEASUREMENTS AND MAIN RESULTS: The elimination rate constant, serum half-life, volume of distribution, and clearance of gentamicin were calculated using a one-compartment pharmacokinetic model. Gestational age, birthweight, gentamicin dosage, peak and trough gentamicin concentrations, and hours after birth at which serum concentrations were drawn were recorded for all infants. Infants were stratified into three groups based on gestational age: 28 weeks or younger, older than 28 weeks but younger than 37 weeks, and 37 weeks or older. Birthweight and calculated pharmacokinetic parameters were compared by 2-tailed Student t test to determine if significant differences existed between pharmacokinetics parameters determined on day 2 of life versus days 3 or 4 within each of the gestational age groups. These analyses revealed only one significant difference between parameters assessed on day 2 versus days 3 or 4: at day 2, the mean trough concentration of gentamicin in infants of gestational age between 28 and 37 weeks was 1.63 +/- 0.44 mg/L, whereas at days 3 or 4, the same parameter for patients of the same gestational age was 1.4 +/- 0.48 mg/L (p=0.005). CONCLUSIONS: With one exception--elevated trough concentrations in infants in the gestational age group between 28 and 37 weeks--pharmacokinetic parameters calculated using gentamicin serum concentrations determined on day 2 of life are not significantly different from those derived from gentamicin serum concentrations determined on days 3 or 4. This suggests that gentamicin serum concentrations and subsequent dosage adjustments can be determined on day 2 of life.     

Gentamicin monitoring in neonates

The elimination of gentamicin (G) was studied in 103 neonates (30 premature) during the first month of life after 2.5 mg/kg i.v. (as infusion) over 20-30 min. G plasma levels, measured by EMIT assay, were obtained before and at 1, 2, 3, and 6 h after infusion. We derived individual first-order kinetic parameters and designed optimal dose regimens. G plasma clearance, half-life, and recommended dose (mg/kg/h) changed exponentially with postnatal age during the first 14 days of life. No significant changes in kinetic values were noted during the first 3 days of life; however, they varied linearly with gestational age when they were measured during this period. Apgar score at 10 min and blood urea nitrogen significantly influenced the same parameters. The predictive value of a designed dose regimen was evaluated at steady-state, after dosage adjustment using two plasma concentration values: the minimum plasma concentration was below 2 mg/L in 93% of the patients; the plasma concentration observed within 1 h after completion of the infusion was (mean +/- SD) 5.33 +/- 0.97 mg/L. Our data suggest that 2.5 mg/kg every 12 h is appropriate in most neonates except for 0-2-day-old premature infants who require 2.5 mg/kg every 18 h. Monitoring of G plasma levels is advisable in infants with low Apgar score and/or renal failure.     

Population pharmacokinetics of gentamicin in South African newborns

Objective Gentamicin population pharmacokinetics in newborns were studied with special reference to possible gender effects.Methods Steady-state serum levels (n=139) were obtained from 79 neonates with a mean birth weight of 2.1 kg, mean gestational age of 35.1 weeks and mean age at the time of sampling of 4.2 days. The data were analysed using the non-linear mixed effects model (NONMEM). A one-compartment model was used to fit the data.Results The final models for clearance (CL) and volume of distribution (V) were: CL(l/h)=0.001×WGT×GA×P and V(l)=0.472×WGT, where WGT=birth weight (kg), GA=gestational age (weeks) and P=1.2 for girls and 1.0 for boys. The values of inter-individual variability in CL and V were 34% and 35%, respectively. Intra-individual variability was 5% (proportional) and 7.2% (additive). Mean (95% confidence interval) values of CL and half-life were 0.042 l h^–1 kg^–1 (0.041, 0.043 l h^–1 kg^–1) and 8.0 h (7.7, 8.3 h), while V was 0.472 (0.428, 0.516) l/kg for all patients.Conclusion Mean population pharmacokinetic values were similar to those obtained with NONMEM for gentamicin in other neonates of similar age. Gender was found to be a determinant of CL, with girls clearing faster than boys.     

Population pharmacokinetics of ibuprofen enantiomers in very premature neonates

The objective of the present study was to evaluate the pharmacokinetic parameters for both S- and R-ibuprofen enantiomers in very premature neonates (gestational age strictly inferior to 28 weeks) and possible relationships between the pharmacokinetic parameters and various covariates. Newborns were randomized to receive ibuprofen or placebo for the prophylactic treatment of patent ductus arteriosus (PDA) at an initial dose of 10 mg/kg ibuprofen within 6 hours after birth, followed by two 5-mg/kg doses at 24-hour intervals (n = 52). If a PDA was still present afterwards, a curative course of ibuprofen using the same dosage regimen was administered (n = 10). A sparse sampling strategy was used because only 2 samples were collected after the third prophylactic injection and 1 after the third curative injection. A model including the chiral transformation of R- to S-ibuprofen was fitted to the concentration-time data using a population approach (NONMEM). R- and S-ibuprofen t(1/2) were about 10 hours and 25.5 hours, respectively. After prophylactic treatment, the mean clearance of R-ibuprofen (CLR = 12.7 mL/h) was about 2.5-fold higher than for S-ibuprofen (CLS = 5.0 mL/h). In addition, clearance of R- and S-ibuprofen increased significantly with gestational age. The mean estimation of R-ibuprofen clearance was found to be higher than for S-ibuprofen, and the clearance of both enantiomers increased with gestational age. This should be considered to assess pharmacokinetic-pharmacodynamic relationships of ibuprofen in premature neonates and subsequently to understand and refine the use of ibuprofen in managing PDA either as a prophylactic or curative treatment.     

Bayesian pharmacokinetics of gentamicin in a haemodialysis population

BACKGROUND: Aminoglycosides are commonly used in the haemodialysis population. Standard pharmacokinetic approaches require multiple sampling to describe the parameters of drug distribution and elimination in the intra- and interdialytic periods. OBJECTIVE: To characterise the pharmacokinetics of gentamicin in a haemodialysis population by using Bayesian pharmacokinetic methods and only two plasma concentrations. DESIGN AND PARTICIPANTS: Prospective case series of 13 adult (aged 36-70 years) haemodialysis patients (Fresenius F80 dialysers were used) receiving gentamicin. METHODS: Patients with suspected or confirmed Gram-negative infections were given gentamicin. At 48 hours after receiving the dose (at the next haemodialysis session), patients provided two blood samples, one immediately before the dialysis session and another 1 hour after haemodialysis. Data on dosage, timing and plasma concentrations for all subjects were analysed with PASTRX version 10.6 and Bayesian pharmacokinetic analysis. Volume of distribution (Vd), interdialytic elimination rate constant (k(inter)), interdialytic elimination half-life (t1/2beta, inter)) and interdialytic clearance (CL(inter)) were determined from a single predialysis plasma concentration. Elimination rate constant (k(dial)), elimination half-life (t1/2beta, dial)) and clearance (CL(dial)) during 3.5-4 hours of dialysis were also determined from the pre- and post-plasma concentrations. RESULTS: Pharmacokinetic parameters (mean +/- SD) were: Vd 0.288 +/- 0.002 L/kg, k(inter) 0.015 +/- 0.004h(-1), t1/2beta, inter) 48 +/- 11h, CL(inter) 5.9 +/- 2.4 mL/min, k(dial) 0.25 +/- 0.05 h(-1), t1/2beta, dial) 3.0 +/- 1.0h and CL(dial) 91 +/- 24 mL/min. CONCLUSIONS: The rate of elimination of gentamicin was 17-fold greater (95% CI 13.7-20.7) on haemodialysis with a Fresenius F80 than off haemodialysis. All of the pharmacokinetic parameters of interest were determined using Bayesian pharmacokinetic procedures and only two plasma gentamicin concentrations.     

Performance of gentamicin population kinetic parameters in Portuguese neonates

Aim To evaluate the performance of eight different sets of gentamicin populational pharmacokinetic parameters, regarding potential implementation in clinical pharmacokinetic software as prior information. Methods The study involved 49 patients of 31.3±4.1 weeks of gestational age (GA), receiving gentamicin, and for whom peak and trough concentrations were obtained. Accuracy and precision were assessed by mean prediction error (ME), mean squared prediction error (MSE) and root mean squared prediction error (RMSE). Weighted prediction-error analysis was carried out in order to evaluate peak and trough concentrations together (ME_w, MSE_w and RMSE_w). Results The analysis showed CL=0.036 l/h/kg (<34 weeks GA) or CL=0.051 l/h/kg (≥34 weeks GA), and V _d =0.5 l/kg (≤37 weeks GA) or V _d =0.4 l/kg (>37 weeks of GA) as the most accurate and precise set of pharmacokinetic parameters (Set 4), presenting the highest percentage of clinically acceptable estimates (Error_Peak<1 μg/ml, and Error_Trough <0.375 μg/ml). Conclusion The adoption of the previously mentioned set of parameters as population estimates seems to be the best option, bearing in mind the obtained results. However, we strongly believe that pharmacokinetic parameter determination of gentamicin should be carried out whenever possible in order to improve the rationale and cost-effectiveness of therapy.     

Kinetic disposition of lorazepam with focus on the glucuronidation capacity, transplacental transfer in parturients and racemization in biological samples

The present study investigates the kinetic disposition with focus on the racemization, glucuronidation capacity and the transplacental transfer of lorazepam in term parturients during labor. The study was conducted on 10 healthy parturients aged 18-37 years with a gestational age of 36-40.1 weeks, treated with a single oral dose of 2 mg racemic lorazepam 2-9 h before delivery. Maternal venous blood and urine samples were obtained over a 0-48 h interval and the umbilical cord sample was obtained immediately after clamping. Lorazepam enantiomers were determined in plasma and urine samples by LC-MS/MS using a Chiralcel OD-R column. In vitro racemization of lorazepam required the calculation of the pharmacokinetic parameters as isomeric mixtures. The data were fitted to two-compartment model and the pharmacokinetic parameters are reported as means (95% CI): t(1/2a) 3.2h (2.6-3.7 h), K(a) 0.23 h(-1) (0.19-0.28 h(-1)), t(1/2) 10.4h (9.4-11.3h), beta 0.068 h(-1) (0.061-0.075h(-1)), AUC(0-infinity) 175.3(ngh)/ml (145.7-204.8(ngh)/ml), Cl/F 2.6 ml/(minkg) (2.3-2.9 ml/(minkg)), Vd/F178.8l (146.5-211.1l), Fel 0.3% (0.1-0.5%), and Cl(R) 0.010 ml/(minkg) (0.005-0.015 ml/(minkg)). Placental transfer of lorazepam evaluated as the ratio of vein umbilical/maternal vein plasma concentrations, obtained as an isomeric mixture, was 0.73 (0.52-0.94). Pregnancy changes the pharmacokinetics of lorazepam, with an increase in the apparent distribution volume, an increase in apparent oral clearance, and a reduction of elimination half-life. The increase in oral clearance may indicate an increase in glucuronidation capacity, with a possible reduction in the plasma concentrations of drugs depending on glucuronidation capacity as the major metabolic pathway.     

Clinical pharmacokinetics of phenobarbital in neonates.

Demographic and clinical pharmacokinetic data collected from term and preterm neonates who were treated with intravenous phenobarbital have been analysed to evaluate the role of patient characteristics in pharmacokinetic parameters. Significant relationships between total body weight (TBW) or body surface area (BSA) and volume of distribution (Vd) and total body clearance (CL) were found. Coefficients of determination were: 0.55 and 0.59 for Vd, and 0.76 and 0.72 for CL against TBW and BSA, respectively. In addition, significant relationships between height of the infants and volume of distribution of phenobarbital and total body clearance were observed. Coefficients of determination were 0.58 for Vd and 0.56 for CL. A weaker but significant correlation existed between gestational age and Vd or CL of phenobarbital. Coefficients of determination were 0.43 and 0.64, respectively. There was no correlation between volume of distribution per kg body weight or total body clearance per kg body weight and any patient parameter investigated. However, these latter pharmacokinetic parameters tended to decrease with increasing gestational age and height of the neonates. The results obtained were used to develop new loading and maintenance doses for phenobarbital in neonates based on total body weight and body surface area and based on height and gestational age for cases that weight is not available.     

Clinical pharmacokinetics in optimal gentamicin dosing regimen in neonates

Gentamicin is readily used for suspected or proven sepsis in neonates, yet it shows considerable inter-individual pharmacokinetic variability, which limits achievements of therapeutic levels. Hence, the aim of this study was to compare peak and trough gentamicin concentrations according to dosing regimen, to evaluate pharmacokinetic parameters, and to consider adjustments of dosing regimen. Babies with infection were treated with 1 h infusion, and daily dose of 5 or 7.5 mg/kg depending on the age. Patients were randomized into two groups: I — dosing interval 12 h (n=8), II — 24 h (n=11). Two steady-state blood samples were obtained. Pharmacokinetic parameters were calculated using one-compartment model. The results showed a difference (p<0.05) in peak gentamicin concentrations between the groups, and tendency of lower trough levels in the group II. Calculated pharmacokinetic parameters included the volume of distribution (Vd) 0.52±0.47 l/kg, clearance (CL) 0.055±0.036 l/hkg and a half-life (t_1/2) of 6.89±3.21 h. Based on the method for dosing regimen adjustments, there was a need to extend dosing interval to 36 h in 6 patients