Estradiol and weight are covariates of paracetamol clearance in young women.

AIM: Paracetamol clearance differs between pregnant and non-pregnant women and between women with or without specific oral contraceptives (OCs). However, an association between female sex hormones and paracetamol clearance has never been explored. METHODS: In total, 49 women at delivery, 8 female control subjects without OC use, historical data of 14 women taking OCs, and 15 postpartum observations with and without OCs were pooled to explore covariates of paracetamol clearance. All received a single intravenous 2-gram paracetamol dose, and blood samples were collected up to 6 h after dosing. High-performance liquid chromatography was used to quantify paracetamol. The area under the curve to time infinity (AUC0-∞) was determined and clearance (l/h·m(2)) was calculated by dose/ AUC0-∞. In addition, estradiol and progesterone were quantified by ELISA with electro-chemiluminescence. RESULTS: Median paracetamol clearance at delivery was significantly higher when compared to postpartum or non-pregnant women (11.9 vs. 6.42 and 8.4 l/h·m(2), at least p < 0.05), while an association between paracetamol clearance and estradiol was observed (R = 0.494, p < 0.0001). In non-pregnant subjects, there was no impact of OC exposure on paracetamol clearance. Multiple regression revealed a linear association (Radj = 0.41, p < 0.001) between paracetamol clearance and weight (p = 0.0462) and estradiol (p < 0.0001). CONCLUSION: Estradiol and weight in part explain the variation in paracetamol clearance in young women.

Weight, pregnancy and oral contraceptives affect intravenous paracetamol clearance in young women.

OBJECTIVES: Because of the extensive variability in paracetamol clearance in young women, published data were pooled with newly collected observations in search of covariates of paracetamol pharmacokinetics (PK) within this specific population. SUBJECTS AND METHODS: PK estimates and clinical characteristics [pregnant, weight, exposure to oral contraceptives (OC)] in young women following IV loading dose (2 g paracetamol) were pooled, using a non-compartmental linear disposition model in individual time-concentration profiles. Data were reported by median and range. Rank correlation was used to link clearance (l/h) to weight, Mann Whitney U test to compare clearance (l/h.m-2) between subgroups (pregnant, OC exposure). Finally, a multiple regression model with clearance (l/h) in all women and all non-pregnant women was performed. RESULTS: Based on 73 paracetamol PK estimates, a 8-fold variability in clearance (range 7.1-62.2 l/h) was documented, in part explained by a correlation (r2=0.36) between clearance (l/h) and weight. Clearance (l/h and l/h.m-2) and distribution volume (l) at delivery (n=36) were higher compared to non-pregnant observations. In non-pregnant women, women on OC (n=20) had a higher paracetamol clearance (l/h.m-2) compared to women (n=17) not on OC (p = 0.023). Weight (p = 0.0043) and pregnancy (p = 0.02) were independent variables (r=0.56) of paracetamol clearance (l/h). In non-pregnant women, weight (p = 0.009) and OC exposure (p = 0.03) were independent variables (r=0.51). CONCLUSIONS: Weight, pregnancy and OC result in higher clearance of IV paracetamol in young women. Besides compound specific relevance, these findings also unveil covariates of drug metabolism in young women.

Pharmacokinetics of intravenous ketorolac following caesarean delivery.

BACKGROUND: Drug disposition is altered by pregnancy and the peripartum period but data on intravenous ketorolac pharmacokinetics following caesarean delivery have not been previously reported. METHODS: At the end of caesarean delivery, women received an intravenous bolus of ketorolac tromethamine 30 mg (immediate postpartum, Group IP). Plasma samples were collected at 1, 2, 4, 6 and 8h. A similar pharmacokinetic study was repeated in a subgroup of these women 4-5 months after delivery (late postpartum, Group LP) and in a group of unrelated, healthy non-pregnant female volunteers (controls, Group C). A non-compartmental linear disposition model was applied to analyse individual ketorolac time-concentration profiles. Results at delivery were compared with controls using unpaired or paired statistics as appropriate. Covariates of pharmacokinetic estimates at delivery were examined. RESULTS: Thirty-nine women were studied at caesarean delivery, of whom eight were re-evaluated 4-5 months later. In addition, eight volunteers were studied. Clearance in Group IP was higher compared to Groups LP and C (2.11 vs. 1.43 and 1.07 L/h·m(2) respectively, P<0.05). Volume of distribution was also increased in Group IP compared to Groups LP and C (0.24 vs. 0.16 and 0.17 L/kg respectively, P<0.05). No significant covariates of pharmacokinetic estimates, including gestational age, preterm vs. term, twin vs. singleton and maternal co-morbidity, were seen in Group IP. CONCLUSIONS: Ketorolac clearance and distribution volume are significantly increased following caesarean delivery. These data provide pharmacokinetic estimates on which to base studies on post caesarean analgesia.

Cefazolin plasma protein binding and its covariates in neonates.

Cefazolin (CFZ) is highly and saturably bound to human serum albumin (HSA) in adults. We aim to describe CFZ protein binding and its covariates in neonates. In neonates to whom intravenous CFZ (50 mg/kg) was administered prior to a surgical procedure, total and unbound CFZ plasma concentrations (mg/l) were determined at 0.5, 2, 4 and 8 h after CFZ administration. Linear and multiple regression analyses were used to document covariates of unbound CFZ fraction. The Wilcoxon signed-rank test was used for the paired analysis of unbound CFZ fractions. In 40 patients with a median weight of 2,767 (range 830-4,200) g and a postmenstrual age (PMA) of 39 (25-45) weeks, 131 samples were collected. The median unbound CFZ fraction was 0.39 (0.10-0.73). Linear regression of unbound CFZ fraction versus unbound CFZ plasma concentration (R (2) = 0.39) had a slope significantly different from zero (p < 0.001). In a multiple regression analysis, albuminaemia, total CFZ concentration, indirect bilirubinaemia and PMA resulted in an R (2) value of 0.496. The median unbound CFZ fraction at the peak concentration (0.46, range 0.28-0.69) was significantly higher compared to the trough level (0.36, range 0.17-0.73) (p < 0.001). The between- and within-patient saturability of CFZ plasma protein binding were documented in neonates. The median unbound CFZ fraction in neonates is higher than in adults and depends partly on albuminaemia, total CFZ concentration, indirect bilirubinaemia and PMA. Integration of CFZ protein binding in future pharmacokinetic/pharmacodynamic research is warranted in order to optimise neonatal CFZ dosing. We recommend protein binding assessment in the neonatal pharmacokinetic evaluation of highly protein-bound or clinically relevant drugs.

Dantrolene is neuroprotective in vitro, but does not affect survival in SOD1(G9³A) mice.

Amyotrophic Lateral Sclerosis (ALS) is a devastating progressive neurodegenerative disease. One of the proposed disease mechanisms is excitotoxicity, in which excessive cytosolic calcium causes neuronal death. Although most calcium may originate from the extracellular space through activation of calcium-permeable AMPA receptors, we investigated in this study the contribution of endoplasmic reticulum calcium release by blocking the ryanodine receptor (RyR) using dantrolene. In vitro, dantrolene provides a significant protection to motor neurons exposed to a brief excitotoxic insult. However, daily administration of dantrolene to mice overexpressing superoxide dismutase 1 glycine to alanine at position 93 (SOD1(G93A)) does affect neither survival nor the number of motor neurons and ubiquitin aggregates indicating that calcium release through RyRs does not contribute to the selective motor neuron death in this animal model for ALS.

Pharmacokinetics of a loading dose of intravenous paracetamol post caesarean delivery.

BACKGROUND: The postpartum period affects drug disposition, but data of intravenous paracetamol loading dose pharmacokinetics immediately following caesarean delivery have not yet been reported. METHODS: Immediately following caesarean delivery, women received a 2-g loading dose of intravenous paracetamol. Plasma samples were collected at 1, 2, 4 and 6 h. Individual pharmacokinetics were calculated assuming a linear one-compartment model with instantaneous input and first-order output. Data were reported using median and range. RESULTS: Twenty-eight patients undergoing caesarean delivery were recruited (age 31.5 [20-42] years, weight 79 [57-110] kg, body surface area 1.9 [1.5-2.4]m(2)). Median paracetamol plasma concentrations after 1, 2, 4 and 6 h were 22.5, 15.25, 7.9, and 3.9 mg/L respectively. Paracetamol clearance was 20.3 (11.8-62.8) L/h or 10.9 (7-23.8)L/hm(2), distribution volume 58.3 (42.9-156) L or 0.72 (0.52-1.56) L/kg. CONCLUSION: Pharmacokinetics of intravenous paracetamol have been estimated following caesarean delivery. Although limited to a loading dose shortly after surgery, the results are clinically relevant since this is the first description in this patient population. These data provide evidence on which to base further integrated pharmacokinetic/pharmacodynamic studies in peripartum analgesia.

Transplacental transfer of anthracyclines, vinblastine, and 4-hydroxy-cyclophosphamide in a baboon model.

OBJECTIVE: The paucity of data on the fetal effects of prenatal exposure to chemotherapy prompted us to study transplacental transport of chemotherapeutic agents. METHODS: Fluorouracil-epirubicin-cyclophosphamide (FEC) and doxorubicin-bleomycin-vinblastine-dacarbazine (ABVD) were administered to pregnant baboons. At predefined time points over the first 25 h after drug administration, fetal and maternal blood samples, amniotic fluid (AF), urine, fetal and maternal tissues, and cerebrospinal fluid (CSF) were collected. High-performance liquid chromatography (HPLC) and liquid chromatography-mass spectrometry (LC-MS) were used for bioanalysis of doxorubicin, epirubicin, vinblastine, and cyclophosphamide. RESULTS: In nine baboons, at a median gestational age of 139 days (range, 93-169), FEC 100% (n = 2), FEC 200% (n=1), ABVD 100% (n = 5), and ABVD 200% (n = 1) were administered. The obtained ratios of fetal/maternal drug concentration in the different simultaneously collected samples were used as a measure for transplacental transfer. Fetal plasma concentrations of doxorubicin and epirubicin averaged 7.5 ± 3.2% (n = 6) and 4.0 ± 1.6% (n = 8) of maternal concentrations, respectively. Fetal tissues contained 6.3 ± 7.9% and 8.7 ± 8.1% of maternal tissue concentrations for doxorubicin and epirubicin, respectively. Vinblastine concentrations in fetal plasma averaged 18.5 ± 15.5% (n=9) of maternal concentrations. Anthracyclines and vinblastine were neither detectable in maternal nor in fetal brain/CSF. 4-Hydroxy-cyclophosphamide concentrations in fetal plasma and CSF averaged 25.1 ± 6.3% (n = 3) and 63.0% (n = 1) of the maternal concentrations, respectively. CONCLUSION: This study shows limited fetal exposure after maternal administration of doxorubicin, epirubicin, vinblastine, and 4-hydroxy-cyclophosphamide.

Urinary propofol metabolites in early life after single intravenous bolus.

BACKGROUND: /st> Propofol clearance is lower in neonates than in adults and displays extensive interindividual variability, in part explained by postmenstrual age (PMA) and postnatal age (PNA). Since propofol is almost exclusively cleared metabolically, urinary propofol metabolites were determined in early life and compared with similar observations reported in adults. METHODS: /st> Twenty-four hours urine collections were sampled after a single i.v. bolus of propofol (3 mg kg(-1)) in neonates undergoing procedural sedation. Clinical characteristics (PMA, PNA, weight, and cardiopathy) were recorded. Urine metabolites [propofol glucuronide (PG), 1- and 4-quinol glucuronide (QG)] were quantified using high-pressure liquid chromatography. Urine recovery (% administered dose) and the contribution of PG and QG to urinary elimination were calculated. Data were reported by median and range, analysed by Mann-Whitney U or Spearman's rank. RESULTS: /st> Eleven neonates (median PNA 11 days, PMA 38 weeks) were included. Median propofol metabolite recovery was 64% (range 34-98%). PG contributed 34% (range 8-67%) and QG 65% (range 33-92%). There was no significant correlation between either PMA, PNA, or cardiopathy and propofol metabolites. Compared with adults, the contribution of PG (34% vs 77%) was lower and the contribution of QG (65% vs 22%) was higher in neonates. CONCLUSIONS: /st> Propofol metabolism in neonates differs from adults, reflecting the age-dependent limited glucuronidation capacity. Hydroxylation to quinol metabolites already contributes to propofol metabolism. These differences likely explain the PMA- and PNA-dependent reduced propofol clearance in neonates.

Developmental pharmacology: neonates are not just small adults...

Neonatal drug dosing needs to be based on the physiological characteristics of the newborn and the pharmacokinetic parameters of the drug. Size-related changes can in part be modelled based on allometry and relates to the observation that metabolic rate relates to weight by a kg 0.75 trend. Until adult metabolic activity has been reached, ontogeny, i.e. isoenzyme-specific maturation and maturation of renal clearance also contributes to drug metabolism, making isoenzyme-specific documentation of maturation necessary. Changes in body composition and ontogeny are most prominent in neonates. The body fat content (/kg) is markedly lower and the body water content (/kg) is markedly higher in neonates. These findings have an impact on the distribution volume of both lipophilic and hydrophilic drugs. Drugs are cleared either by metabolism or elimination. While the first is mainly hepatic, the second route is mainly renal. Both hepatic metabolism and renal clearance display maturation in early life although other covariables (e.g. polymorphisms, co-administration of drugs, first pass metabolism, disease characteristics) further contribute to the interindividual variability in drug disposition. Documentation of these maturational processes based on in vivo 'case' studies is of value since these drug-specific observations can subsequently be extrapolated to other drugs which are either already being prescribed or even considered for use in neonates by the introduction of these observations in 'generic physiologically-based pharmacokinetic' models.

Both postnatal and postmenstrual age contribute to the interindividual variability in tramadol glucuronidation in neonates.

INTRODUCTION: Although of pharmacokinetic and -dynamic relevance, data on ontogeny of UDP-glucuronosyltransferase (UGT) activity in neonates are scant. We therefore wanted to assess the impact of both postnatal and postmenstrual age (PNA/PMA) on the interindividual variability of glucuronidation to overall tramadol urinary elimination in neonates. METHODS: O-demethyl tramadol (M1) and M1-glucuronide (M1G) were determined in 24 hour urine collections during continuous intravenous tramadol administration in neonates. Glucuronidation fraction (%) was calculated by the ratio of M1G to the sum of M1G and M1 free (M1total). Fractions (%) in early (

Inter-individual variability in propofol pharmacokinetics in preterm and term neonates.

BACKGROUND: To document covariates which contribute to inter-individual variability in propofol pharmacokinetics in preterm and term neonates. METHODS: Population pharmacokinetics were estimated (non-linear mixed effect modelling) based on the arterial blood samples collected in (pre)term neonates after i.v. bolus administration of propofol (3 mg kg(-1), 10 s). Covariate analysis included postmenstrual age (PMA), postnatal age (PNA), gestational age, weight, and serum creatinine. RESULTS: Two hundred and thirty-five arterial concentration-time points were collected in 25 neonates. Median weight was 2930 (range 680-4030) g, PMA 38 (27-43) weeks, and PNA 8 (1-25) days. In a three-compartment model, PMA was the most predictive covariate for clearance (P<0.001) when parameterized as [CL(std).(PMA/38)(11.5)]. Standardized propofol clearance (CL(std)) at 38 weeks PMA was 0.029 litre min(-1). The addition of a fixed value in neonates with a PNA of >/=10 days further improved the model (P<0.001) and resulted in the equation [CL(std).(PMA/38)(11.5) +0.03] for neonates >/=10 days. Values for central volume (1.32 litre), peripheral volume 1 (15.4 litre), and peripheral volume 2 (1.29 litre) were not significantly influenced by any of the covariates (P>0.001). CONCLUSIONS: PMA and PNA contribute to the inter-individual variability of propofol clearance with very fast maturation of clearance in neonatal life. This implicates that preterm neonates and neonates in the first week of postnatal life are at an increased risk for accumulation during either intermittent bolus or continuous administration of propofol.

Urinary metabolites to assess in vivo ontogeny of hepatic drug metabolism in early neonatal life.

In addition to size-dependent allometric metabolic activity, most isoenzymes display age-dependent isoenzyme-specific ontogeny. We therefore need probe drugs to describe isoenzyme-specific ontogeny to develop more sophisticated, physiologically based models. We illustrate the feasibility and the relevance of in vivo assessment of hepatic metabolism, based on observations on urinary elimination of paracetamol and tramadol metabolites in neonates. On the basis of the observations on tramadol disposition, we were able to document that O-demethylation phenotypic activity developed sooner when compared with N-demethylation. During repeated administration of intravenous paracetamol, it was documented that, in addition to postmenstrual and postnatal age (PNA), repeated administration also contributed to the urinary excretion of glucuronidated paracetamol. In both probe drugs evaluated, age only in part explained the interindividual variability observed. Urine metabolites to assess in vivo metabolism of drugs routinely administered in neonates likely increase both the feasibility and clinical relevance of studies on in vivo isoenzyme-specific ontogeny in neonates.

Simultaneous determination of 8 HIV protease inhibitors in human plasma by isocratic high-performance liquid chromatography with combined use of UV and fluorescence detection: amprenavir, indinavir, atazanavir, ritonavir, lopinavir, saquinavir, nelfinavir and M8-nelfinavir metabolite.

A simple, accurate and fast method was developed for determination of the commonly used HIV protease inhibitors (PIs) amprenavir, indinavir, atazanavir, ritonavir, lopinavir, nelfinavir, M8-nelfinavir metabolite and saquinavir in human plasma. Liquid-liquid extraction was used with hexane/ethylacetate from buffered plasma samples with a borate buffer pH 9.0. Isocratic chromatographic separation of all components was performed on an Allsphere hexyl HPLC column with combined UV and fluorescence detection. Calibration curves were constructed in the range of 0.025-10 mg/l. Accuracy and precision of the standards were all below 15% and the lowest limit of quantitation was 0.025 mg/l. Stability of quality control samples at different temperature conditions was found to be below 20% of nominal values. The advantages of this method are: (1) inclusion and determination of the newly approved atazanavir, (2) simultaneous isocratic HPLC separation of all compounds and (3) increased specificity and sensitivity for amprenavir by using fluorescence detection. This method can be used for therapeutic drug monitoring of all PIs currently commercialised and is now part of current clinical practice.

Maturational changes in the in vivo activity of CYP3A4 in the first months of life.

OBJECTIVE: To document maturational changes of the in vivo activity of CYP3A4 in the first months of life. METHODS: The contribution of tramadol (M), O-demethyl tramadol (M1, CYP2D6-mediated) and N-demethyl tramadol (M2, CYP3A4-mediated) to the overall elimination of tramadol and the log M/M2 was assessed in 24-hour urine collections during continuous intravenous tramadol administration. Correlations with perinatal characteristics (postnatal age (PNA) and postmenstrual age (PMA)) were studied. RESULTS: Of the total amount of tramadol administered in a 24-hour interval to 25 neonates and young infants (PMA 25 - 53 weeks), 34.5% (SD 6.1) were retrieved in the urine as parent compound or metabolite in a 24-hour interval. This retrieved material consisted primarily of tramadol 79% (SD 18), M1 10% (SD 17) and M2 3% (SD 3.4). The contribution of M (r2 = -0.53), M1 (r2 = 0.46) and M2 (r2 = 0.16) to overall M elimination correlated with increasing PMA. The mean log M/M2 was 1.44 (SD 0.46) and there was an inverse correlation between the log M/M2 ratio and PMA (r2 = -0.43, 95% CI for r = -0.84 to -0.34, p = 0.0006) and PNA (r2 = -0.25, 95% CI for r = -0.78 to -0.16, p = 0.008). The maturational half-life of the log M/M2 ratio was 16 - 20 weeks. In a multiple regression model, PMA was the only significant variable accounting for the interindividual variability in log M/M2. CONCLUSIONS: PMA was found to be the most important maturational change determing the in vivo activity of CYP3A4. The activity of CYP3A4 is relatively delayed in the first months of life compared to the developmental changes in CYP2D6 activity described earlier, however, the overall weak correlations reflect that PMA explains only in part the interindividual variability observed.

Symptomatic hypoglycemia in a patient with chronic hemodialysis.

We describe the case of a 71-years-old man in chronic hospital hemodialysis who was admitted to the hospital because of symptomatic hypoglycemia. We discovered that this was due to a documented intoxication with cibenzoline, an antiarrhythmic drug, used to treat (supra-)ventricular tachyarrhythmia. In addition we made a short review of the literature concerning cibenzoline intoxication.

O-demethylation of tramadol in the first months of life.

OBJECTIVE: Assess in vivo O-demethylation activity in the first months of life. METHODS: Time-concentration profiles of tramadol (M) and O-demethyl tramadol (M1) in plasma and urine were simultaneously collected in the first 24 h of continuous intravenous tramadol administration in neonates and young infants. M and M1 were determined by high performance liquid chromatography. Correlations between perinatal characteristics [postnatal age (PNA), postmenstrual age (PMA)] and the contribution of metabolites (M, M1) to overall tramadol elimination and to the plasma and urine log M/M1 were calculated. RESULTS: Plasma samples were available in 20/29 and complete 24-h urine collections were available in 25/29 neonates (25-53 weeks PMA). Mean plasma log M/M1 value (>4 h, n=86) was 0.8 (SD 0.4). A significant correlation between plasma log M/M1 and PMA (r=-0.73, P<0.0001) and PNA (r=-0.58, P<0.005) was observed. In a multiple regression model, only PMA remained an independent variable. Mean urine log M/M1 was 0.94 (SD 0.7). Significant correlations of the urine log M/M1 ratio with PMA (r=-0.73, P<0.0001) and PNA (r=-0.56, P=0.0035) were observed. In a multiple regression model with the urine log M/M1 ratio as dependent variable, only PMA remained an independent variable. The maturational half-life of the log M/M1 ratio in early neonatal life in the age range evaluated is about 12-16 weeks without plateau. CONCLUSIONS: O-demethylation activity was already observed in early neonatal life. A significant correlation with PMA was documented, but PMA can only partially explain the observed variability in O-demethylation activity. Polymorphism therefore likely already contributes to the interindividual variability observed in neonates.

Tramadol disposition in the very young: an attempt to assess in vivo cytochrome P-450 2D6 activity.

BACKGROUND: Tramadol is potentially a very useful pain relief medication in neonates and infants. It is primarily metabolized into O-demethyl tramadol (M1) by CYP2D6. Data concerning tramadol disposition and CYP2D6 activity in young infants are not available. METHODS: A population pharmacokinetic analysis of tramadol and M1 time-concentration profiles was undertaken using non-linear mixed-effects models (NONMEM), based on newly collected data on tramadol and M1 time-concentration profiles in neonates and young infants (n=20) and published studies on intravenous tramadol in children and adults. M1 formation served as a surrogate for CYP2D6 activity. RESULTS: Tramadol clearance was described using a two-compartment linear model with zero-order input and first-order elimination. Clearance increased from 25 weeks post-conception age (PCA) (5.52 litre h(-1) [70 kg](-1)) to reach 84% of the mature value by 44 weeks PCA (standardized to a 70 kg adult using allometric '1/4 power' models). The central volume of distribution decreased from 25 weeks PCA (256 litre [70 kg](-1)) to reach 120% of its mature value by 87 weeks PCA. Formation clearance to M1 contributed 43% of tramadol clearance, but had no relationship with PCA. There was a weak non-linear relationship between PCA and M1 metabolite clearance. CONCLUSIONS: Maturational clearance of tramadol is almost complete by 44 weeks PCA. A target concentration of 300 microg litre(-1) is achieved after a bolus of tramadol hydrochloride 1 mg kg(-1) and can be maintained by infusion of tramadol hydrochloride 0.09 mg kg(-1) h(-1) at 25 weeks PCA, 0.14 mg kg(-1) h(-1) at 30 weeks PCA, 0.17 mg kg(-1) h(-1) at 35 weeks PCA, 0.18 mg kg(-1) h(-1) at 40 weeks, 0.19 mg kg(-1) h(-1) at 50 weeks PCA to 1 yr, 0.18 mg kg(-1) h(-1) at 3 yr and 0.12 mg kg(-1) h(-1) in adulthood. CYP2D6 activity was observed as early as 25 weeks PCA, but the impact of CYP2D6 polymorphism on the variability in pharmacokinetics, metabolism and pharmacodynamics of tramadol remains to be established.

Tramadol concentrations in blood and in cerebrospinal fluid in a neonate.

Based on blood and cerebrospinal fluid samples collected in a full-term neonate, the penetration of tramadol in the central nervous system is described. Following intravenous administration of tramadol, a lag time of about 4 h was observed until full blood-brain equilibration was achieved. This pharmacokinetic observation is in line with a recent pharmacodynamic evaluation of the central opioid effects of tramadol in adults.