Audrey Boulamery

EFFECTS OF L-DOPA ON CIRCADIAN RHYTHMS OF 6-OHDA STRIATAL LESIONED RATS: A RADIOTELEMETRIC STUDY

Temporal variation in the motor function of Parkinsons disease (PD) patients suggests the potential importance of a chronobiological and chronopharmacological approach in its clinical management. We previously documented the effects of striatal injection of 6-OHDA (as an animal model of PD) on the circadian rhythms of temperature (T), heart rate (HR), and locomotor activity (A). The present work assessed the possible influence of L-Dopa on these same rhythms in the 6-OHDA animal model of PD. The study began after a four-week recovery period following surgical implantation of telemetric devices to monitor the study variables and/or anaesthesia. The study was divided into an initial one-week control period (W1) for baseline measurement of T, HR, and A rhythms. Thereafter, stereotaxic 6-OHDA lesioning was done. and a second monitoring for two weeks followed (W2, W3). Rats were then randomly divided into two groups: eight control rats received, via a mini-osmotic pump implanted subcutaneously, the excipient saline; the other eight rats received L-Dopa (100 mg/kg SC/day). After a seven-day period (W4), the pumps were removed and the T, HR, and A rhythms were monitored for two weeks (W5 and W6). To control for 6-OHDA striatal dopamine-induced depletion, 12 other rats were injected by identical methods (eight rats with 6-OHDA and four controls with saline) and sacrificed at W1, W3, and W5 for dopamine striatal content determination. To verify the delivery of levodopa from the osmotic pumps, plasma levels of levodopa and its main metabolites 3-OMD, DOPAC, and HVA were determined on separate group of rats receiving the drug under the same experimental conditions (osmotic pumps delivering continuously 10 µl/h for seven days, 100 mg/kg/subcutaneously). Our results agree with previously reported rhythmic changes induced by 6-OHDA—loss of circadian rhythmicity or changes in the main parameters of the registered rhythms. When circadian rhythmicity was abolished, L-Dopa treatment improved or accelerated recovery of the circadian rhythms, the effect being more pronounced for the HR rhythm. When circadian rhythms were not abolished but perturbed, L-Dopa treatment did not improve the 6-OHDA-induced changes in the T and A mesor (24 h mean level), while a significant effect was observed for HR. It appears that constant-rate L-Dopa infusion is unable to totally balance dopamine depletion; taking into account the circadian pattern of many structures implicated in drug effect, a sinusoidal delivery of L-Dopa must be evaluated in future experiments. (Author correspondence: bernard.bruguerolle@univmed.fr)

Circadian rhythms of oxidative phosphorylation: effects of rotenone and melatonin on isolated rat brain mitochondria.

Mitochondrial experiments are of increasing interest in different fields of research. Inhibition of mitochondrian activities seems to play a role in Parkinsons disease and in this regard several animal models have used inhibitors of mitochondrial respiration such as rotenone or MPTP. Most of these experiments were done during the daytime. However, there is no reason for mitochondrial respiration to be constant during the 24h. This study investigated the circadian variation of oxidative phosphorylation in isolated rat brain mitochondria and the administration-time-dependent effect of rotenone and melatonin. The respiratory control ratio, state 3 and state 4, displayed a circadian fluctuation. The highest respiratory control ratio value (3.01) occurred at 04:00h, and the lowest value (2.63) at 08:00h. The highest value of state 3 and state 4 oxidative respiration occurred at 12:00h and the lowest one at 20:00h. The 24h mean decrease in the respiratory control ratio following incubation with melatonin and rotenone was 7 and 32%, respectively; however, the exact amount of the inhibition exerted by these agents varied according to the time of the mitochondria isolation. Our results show the time of mitochondrial isolation could lead to interindividual variability. When studies require mitochondrial isolation from several animals, the time between animal experiments has to be minimized. In oxidative phosphorylation studies, the time of mitochondria isolation must be taken into account, or at least specified in the methods section.

Pharmacokinetics and absolute bioavailability of phenobarbital in neonates and young infants, a population pharmacokinetic modelling approach

Phenobarbital is widely used for treatment of neonatal seizures. Its optimal use in neonates and young infants requires information regarding pharmacokinetics. The objective of this study is to characterize the absolute bioavailability of phenobarbital in neonates and young infants, a pharmacokinetic parameter which has not yet been investigated. Routine clinical pharmacokinetic data were retrospectively collected from 48 neonates and infants (weight: 0.7–10 kg; patients postnatal age: 0–206 days; GA: 27–42 weeks) treated with phenobarbital, who were administered as intravenous or suspension by oral routes and hospitalized in a paediatric intensive care unit. Total mean dose of 4.6 mg/kg (3.1–10.6 mg/kg) per day was administered by 30‐min infusion or by oral route. Pharmacokinetic analysis was performed using a nonlinear mixed‐effect population model software). Data were modelled with an allometric pharmacokinetic model, using three‐fourths scaling exponent for clearance (CL). The population typical mean [per cent relative standard error (%RSE)] values for CL, apparent volume of distribution (Vd) and bioavailability (F) were 0.0054 L/H/kg (7%), 0.64 L/kg (15%) and 48.9% (22%), respectively. The interindividual variability of CL, Vd, F (%RSE) and residual variability (%RSE) was 17% (31%), 50% (27%), 39% (27%) and 7.2 mg/L (29%), respectively. The absolute bioavailability of phenobarbital in neonates and infants was estimated. The dose should be increased when switching from intravenous to oral administration.

Chronopharmacokinetics of Imipenem in the Rat

There are no studies indicating a possible modification of imipenem pharmacokinetics related to the hour (i.e., circadian time) of its administration. The aim of this study was to evaluate the influence of different times of intramuscular imipenem administration on its disposition in Wistar AF EOPS rats. Four groups of eight animals were given a single intramuscular injection of 140 mg/kg of imipenem either at 10∶00, 16∶00, 22∶00, or 04∶00 h. Blood samples were collected 0.5, 1, 2, 3, 4, 6, and 8 h after drug injection, and the main pharmacokinetic parameters determined were Cmax, Tmax, elimination half‐life (t1/2), area under the concentration‐versus‐time curve (AUC), total serum clearance (CL/F), and volume of distribution (V/F). Circadian variation of Cmax (49%), Tmax (92%), and AUC (19%) was observed leading to variability of imipenem exposure. Clearance and volume of distribution were modified according to the circadian time of drug injection but did not reach statistical significance. The results suggest that varying the time of administration induces intra‐individual variability.

Effects of induced hyperthermia on pharmacokinetics of ropivacaine in rats.

Ropivacaine is a local anaesthetic used for epidural anaesthesia and postoperative pain relief. Hyperthermia is a very common sign of infection associated with variations in physiological parameters, which may influence drugs pharmacokinetics. The aim of this study was to determine the effects of induced hyperthermia on ropivacaine pharmacokinetics in rats. Two groups of six rats were given a single subcutaneous ropivacaine injection. Hyperthermia‐induced animals were placed in a water bath to obtain a stable mean core temperature of 39.7 °C. After blood samples collection, ropivacaine serum concentrations and pharmacokinetic parameters were determined. Two other groups of six rats were sacrificed 30 min after ropivacaine injection to determine serum and tissues (brain and heart) concentrations. Our results (median ± inter quartile range) reveal a significant increase of the total apparent clearance (0.0151 ± 0.000800 L/min vs. 0.0134 ± 0.00134 L/min), apparent volume of distribution (Vd) (2.19 ± 0.27 L vs. 1.57 ± 0.73 L) and a significant decrease in exposure (488 ± 50.6 mg.min/L vs. 572 ± 110 mg.min/L) in induced‐hyperthermia group. We observed a significant increase in brain ropivacaine concentration in hyperthermic rats (8.39 ± 8.42 μg/g vs. 3.48 ± 3.26 μg/g) and no significant difference between cardiac concentrations in the two groups (5.38 ± 4.83 μg/g vs. 3.73 ± 2.44 μg/g). Results suggest a higher tissular distribution of ropivacaine and an increase in blood–brain barrier permeability during hyperthermia. The hyperthermia‐induced increase in Vd could be responsible for an increase in cerebral ropivacaine toxicity. These experimental data provide a basis for future clinical investigations in relation to local anaesthetic use in hyperthermic patients.

Pediatric Patients With Solid or Hematological Tumor Disease: Vancomycin Population Pharmacokinetics and Dosage Optimization.

Background: In pediatric cancer patients, determination of optimal vancomycin dosage is essential because of high risk of inadequate concentrations and bacterial resistance. The aim of this study was to determine vancomycin pharmacokinetic parameters in this population and propose dosage optimization to achieve optimal concentration. Methods: We retrospectively reviewed the use of vancomycin in pediatric cancer patients with febrile neutropenia (hematological or solid tumor disease). Vancomycin was administered by continuous infusion, and dosages were adapted according to therapeutic drug monitoring results. Blood cultures were performed before the first dose of antibiotic. Vancomycin pharmacokinetic population parameters were determined using NONMEM software, and dosage simulations were performed according to the target concentration (20–25 mg/L). Results: One hundred twenty-one patients were included in this study, representing 301 vancomycin concentrations. Blood cultures were positive in 37.5% of patients, and observed pathogens were mainly Staphylococcus spp. (43.8% methicillin resistant). Volume of distribution (95% confidence interval) was 34.7 L (17.3–48.0), and total apparent clearance (CL) (95% confidence interval) was correlated to body weight, tumor disease, and cyclosporine coadministration: CL = &thgr;CL × (WT/70)0.75 L/h with &thgr;CL = 3.49 (3.02–3.96), 4.66 (3.98–5.31), and 4.97 (4.42–5.41) in patients managed for hematological malignancies with or without cyclosporine coadministration and for solid malignancies, respectively. Based on simulation results, vancomycin dosage (milligram per kilogram) should be adapted to each child on the basis of its body weight and cyclosporine coadministration. Conclusions: Our results highlight the requirement to adapt vancomycin dosage in cancer pediatric population. Simulations have allowed to describe new dosage schedules, and a chart was created for clinicians to adapt vancomycin dosage.

Nicotine and metabolites determination in human plasma by ultra performance liquid chromatography-tandem mass spectrometry: a simple approach for solving contamination problem and clinical application.

A quantitative method using ultra performance liquid chromatography–tandem mass spectrometry is described for simultaneous determination of nicotine and its metabolites (cotinine and trans‐3′‐ hydroxycotinine) in human plasma. Aliquots of 0.25 mL of plasma specimens were used for analysis, and 3 analytes were extracted by liquid–liquid extraction. The main problem was blank plasma contamination with environmental nicotine. Activated charcoal was used to avoid this analytical interference. For optimized chromatographic performance, a basic mobile phase consisting of 0.2% ammonia in water (mobile phase A, pH10.6) and acetonitrile (mobile phase B) was selected. The analytes were separated on a 50 mm × 2.1 mm BEH C18 column, 1.7 μm particle size, and quantified by MS/MS using multiple‐reaction monitoring (MRM) in positive mode. The chromatographic separation was achieved in 3 min followed by 1.2 min of column equilibration. The calibration curves were linear in the concentration range of 10–1000 ng/mL with correlation coefficients exceeding 0.99. Within‐day precisions and between‐day precisions (CV, %) were <15 %. The accuracy expressed as bias was within ±15% for all analytes. The recovery values ranged from 50% to 97%. The ions used for quantification of nicotine, cotinine and 3‐OH‐cotinine were 166.9 > 129.7; 176.9 > 79.7; 192.9 > 79.7 m/z, respectively. The original blank sample preparation solved the problem of contamination in a cost‐effective and efficient way. The validated method has been routinely used for analysis of nicotine and metabolites and determination of hydroxycotinine/cotinine metabolic ratio. This biomarker seems to be interesting at predicting response of nicotine patch replacement therapies.

Population pharmacokinetics of ertapenem in juvenile and old rats

Ertapenem is a parenteral broad‐spectrum carbapenem active against Gram‐negative pathogens, which has been approved for treatment of different infectious situations in adults and children. Favourable pharmacokinetics and pharmacodynamics have been established in young adults. In the elderly, dosing regimen adaptations are not recommended. Nevertheless, pharmacokinetic studies in paediatrics have not been published yet. The aim of this study was to document whether age influenced ertapenem disposition by comparing its pharmacokinetics in three groups of rats. Rats were separated into three groups: very young rats 21‐day‐old, 10‐week‐old and 7‐month‐old rats. A population pharmacokinetic model was built and evaluated, using the NONMEM software. Pharmacokinetic parameters, interindividual variability and residual variability were estimated. The final model was evaluated by a bootstrap procedure and visual predictive check. The ertapenem concentration–time data were best described by a one‐compartment model with zero‐order input and first‐order elimination. Effect of very young and old ages was estimated on central volume and clearance. Model evaluation indicated that the model was robust and parameter estimates were accurate. Central volume was found to be dependent on age and increase with age. Although the dosing regimen was weight adjusted, clearance was found to depend not only on age but also on weight. This study clearly documents changes in ertapenem pharmacokinetics according to group of age. These results suggest that paediatric dosing regimen cannot be directly extrapolated from a pharmacokinetic model in young adults unless it took into account age‐induced modifications.

Vancomycin: Predictive Performance of a Population Pharmacokinetic Model and Optimal Dose in Neonates and Young Infants

Introduction: Model evaluation is an important issue in population pharmacokinetic analyses. The objectives were to evaluate the predictive performance of previously published pediatric population pharmacokinetic models for vancomycin in a new data set and to propose an optimal dose to obtain a vancomycin concentration target. Methods: External evaluation was conducted for all the published models of vancomycin in neonates and young infants with a new data set of 70 patients. Bias and accuracy were calculated. Advanced analyses were performed to evaluate the predictive performance of the best model. This population pharmacokinetic analysis was performed to simulate doses of vancomycin according to the appropriate target concentration. Results: All models gave almost the same results, except 2 that were not acceptable. Nevertheless, the model described by Oudin et al presented the best results with a bias and accuracy of 4.0% and 27.8%, respectively. Simulations showed that the maintenance dose should be adjusted more precisely to each neonate based on his or her weight and serum creatinine value. Conclusion: Simulations have allowed the authors to describe new dosage schedules, and a chart was created to help clinicians to adapt dosage of vancomycin. Because of pharmacokinetic variability, vancomycin still requires therapeutic drug monitoring.

EFFECTS OF A SEVEN-DAY CONTINUOUS INFUSION OF ROPIVACAINE ON CIRCADIAN RHYTHMS IN THE RAT

The present study was conducted to evaluate the effect of a 7 d continuous infusion of ropivacaine on the 24 h rhythms of body temperature, heart rate, and locomotor activity. After an initial 7 d baseline, rats were randomly divided into two groups of 4 rats each to receive ropivacaine or saline via an osmotic pump for 7 consecutive days. The pumps were removed thereafter and observed during a 7 d recovery span. The studied circadian rhythms were measured by radiotelemetry throughout each of the 7 d periods. An additional group of 4 rats was studied under the same experimental conditions to assess the plasma levels of ropivacaine on days 3 and 8 following pump implantation. Our results indicate that ropivacaine does not induce loss of the circadian rhythms of body temperature, heart rate, or locomotor activity; a prominent period of 24 h was found for all variables in all animals, before, during, and after ropivacaine treatment. However, ropivacaine treatment did modify some characteristics of the rhythms; it increased the MESOR (24 h mean) of the heart rate and locomotor activity rhythms and advanced the acrophase (peak time) of the locomotor activity circadian rhythm. The present study indicates that the circadian rhythms of heart rate and locomotor activity are modified after continuous infusion of ropivacaine, which is of particular interest, given the potential cardiotoxicity of this local anesthetic agent.