Visiting Policies and Parental Presence During PICU Admission: A Survey in French Units.

OBJECTIVES: To describe the policies about parent visiting and involvement in care during admission to French PICUs. DESIGN: A structured questionnaire was emailed to the chief of each of 35 French PICUs. Data about visiting policies, involvement in care, evolution of policies, and general characteristics were collected from April 2021 to May 2021. A descriptive analysis was conducted. SETTING: Thirty-five PICUs in France. PATIENTS: None. INTERVENTIONS: None. MEASUREMENTS AND MAIN RESULTS: Twenty-nine of 35 (83%) PICUs replied. Twenty-four-hour access for parents was reported for all PICUs responding. Other allowed visitors were grandparents (21/29, 72%) and siblings (19/29, 66%) with professional support. Simultaneous visits were restricted to two visitors in 83% (24/29) of PICUs. Family presence was always permitted during medical rounds for 20 of 29 (69%) PICUs. Most of the units rarely or never allowed parental presence during the most invasive procedures, such as central venous catheter placement (18/29, 62%) and intubation (22/29, 76%). CONCLUSIONS: Unrestricted access to the PICU, for both parents, was available in all responding French units. There were, however, restrictions on the number of visitors and the presence of other family members at the bedside. Moreover, permission for parental presence during care procedures was heterogenous, and mainly restricted. National guidelines and educational programs are needed to support family wishes and promote acceptance by healthcare providers in French PICUs.

Effectiveness and Pharmacokinetic Exposures of First-Line Drugs Used to Treat Drug-Susceptible Tuberculosis in Children: A Systematic Review and Meta-Analysis.

BACKGROUND: Optimal doses of first-line drugs for treatment of drug-susceptible tuberculosis in children and young adolescents remain uncertain. We aimed to determine whether children treated using World Health Organization-recommended or higher doses of first-line drugs achieve successful outcomes and sufficient pharmacokinetic (PK) exposures. METHODS: Titles, abstracts, and full-text articles were screened. We searched PubMed, EMBASE, CENTRAL, and trial registries from 2010 to 2021. We included studies in children aged <18 years being treated for drug-susceptible tuberculosis with rifampicin (RIF), pyrazinamide, isoniazid, and ethambutol. Outcomes were treatment success rates and drug exposures. The protocol for the systematic review was preregistered in PROSPERO (no. CRD42021274222). RESULTS: Of 304 studies identified, 46 were eligible for full-text review, and 12 and 18 articles were included for the efficacy and PK analyses, respectively. Of 1830 children included in the efficacy analysis, 82% had favorable outcomes (range, 25%-95%). At World Health Organization-recommended doses, exposures to RIF, pyrazinamide, and ethambutol were lower in children than in adults. Children ≤6 years old have 35% lower areas under the concentration-time curve (AUCs) than older children (mean of 14.4 [95% CI 9.9-18.8] vs 22.0 [13.8-30.1] µg·h/mL) and children with human immunodeficiency virus (HIV) had 35% lower RIF AUCs than HIV-negative children (17.3 [11.4-23.2] vs 26.5 [21.3-31.7] µg·h/mL). Heterogeneity and small sample sizes were major limitations. CONCLUSIONS: There is large variability in outcomes, with an average of 82% favorable outcomes. Drug exposures are lower in children than in adults. Younger children and/or those with HIV are underexposed to RIF. Standardization of PK pediatric studies and individual patient data analysis with safety assessment are needed to inform optimal dosing.

Beta-lactam exposure and safety in intermittent or continuous infusion in critically ill children: an observational monocenter study.

The aim of this study was to assess the pharmacokinetic (PK) exposure and clinical toxicity for three beta-lactams: cefotaxime, piperacillin/tazobactam, and meropenem, depending on two lengths of infusion: continuous and intermittent, in critically ill children. This single center observational prospective study was conducted in a pediatric intensive care unit. All hospitalized children who had one measured plasma concentration of the investigated antibiotics were included. Plasma antibiotic concentrations were interpreted by a pharmacologist, using a Bayesian approach based on previously published population pharmacokinetic models in critically ill children. Exposure was considered optimal, low, or high according to the PK target 100% fT> 4 × MIC and a trough concentration below the toxic concentration (50 mg.L-1 for cefotaxime, 150 mg.L-1 for piperacillin, and 44 mg.L-1 for meropenem). Between May 2019 and January 2020, 80 patients were included and received 106 antibiotic courses: 74 (70%) were administered in intermittent infusion (II) and 32 (30%) in continuous infusion (CI). Compared to II, CI provided more optimal PK exposure (n = 22/32, 69% for CI versus n = 35/74, 47% for II, OR 1.2, 95%CI 1.01-1.5, p = 0.04), less underexposure (n = 4/32, 13% for CI versus n = 36/74, 49% for II, OR 0.7, 95%CI 0.6-0.84, p < 0.001), and more overexposure (n = 6/32, 19% for CI versus n = 3/74, 4% for II, OR 1.2, 95%CI 1.03-1.3, p = 0.01). Five adverse events have been reported during the study period, although none has been attributed to beta-lactam treatment. CONCLUSION: CI provided a higher probability to attain an optimal PK target compared to II, but also a higher risk for overexposure. Regular therapeutic drug monitoring is recommended in critically ill children receiving beta-lactams, regardless of the length of infusion. WHAT IS KNOWN: • Since beta-lactams are time-dependent antibiotics, the probability to attain the pharmacokinetic target is higher with continuous infusion compared to that with intermittent infusion. • In daily practice, continuous or extended infusions are rarely used despite recent guidelines, and toxicity is hardly reported. WHAT IS NEW: • Continuous infusion provided a higher probability to attain an optimal pharmacokinetic target compared to intermittent infusion, but also a higher risk of overexposure. • Regular therapeutic drug monitoring is recommended in critically ill children receiving beta-lactams, regardless of the length of infusion.

Piperacillin Population Pharmacokinetics and Dosing Regimen Optimization in Critically Ill Children Receiving Continuous Renal Replacement Therapy.

We aimed to develop a piperacillin population pharmacokinetic (PK) model in critically ill children receiving continuous renal replacement therapy (CRRT) and to optimize dosing regimens. The piperacillin plasma concentration was quantified by high-performance liquid chromatography. Piperacillin PK was investigated using a nonlinear mixed-effect modeling approach. Monte Carlo simulations were performed to compute the optimal scheme of administration according to the target of 100% interdose interval time in which concentration is one to four times above the MIC (100% fT > 1 to 4× MIC). A total of 32 children with a median (interquartile range [IQR]) postnatal age of 2 years (0 to 11), body weight (BW) of 15 kg (6 to 38), and receiving CRRT were included. Concentration-time courses were best described by a one-compartment model with first-order elimination. BW and residual diuresis (Qu) explained some between-subject variabilities on volume of distribution (V), where [Formula: see text], and clearance (CL), where [Formula: see text], where CLpop and Vpop are 6.78 L/h and 55.0 L, respectively, normalized to a 70-kg subject and median residual diuresis of 0.06 mL/kg/h. Simulations with intermittent and continuous administrations for 4 typical patients with different rates of residual diuresis (0, 0.1, 0.25, and 0.5 mL/kg/h) showed that continuous infusions were appropriate to attain the PK target for patients with residual diuresis higher than 0.1 mL/kg/h according to BW and MIC, while for anuric patients, less frequent intermittent doses were mandatory to avoid accumulation. Optimal exposure to piperacillin in critically ill children on CRRT should be achieved by using continuous infusions with escalating doses for high-MIC bacteria, except for anuric patients who require less frequent intermittent doses.

Meropenem Population Pharmacokinetics and Dosing Regimen Optimization in Critically Ill Children Receiving Continuous Renal Replacement Therapy.

BACKGROUND AND OBJECTIVE: We aimed to develop a meropenem population pharmacokinetic model in critically ill children receiving continuous renal replacement therapy and simulate dosing regimens to optimize patient exposure. METHODS: Meropenem plasma concentration was quantified by high-performance liquid chromatography. Meropenem pharmacokinetics was investigated using a non-linear mixed-effect modeling approach. Monte Carlo simulations were performed to compute the optimal scheme of administration, according to the target of a 100% inter-dose interval time in which concentration is one to four times above the minimum inhibitory concentration (100% fT>1-4×MIC). RESULTS: A total of 27 patients with a median age of 4 [interquartile range 0-11] years, a median body weight of 16 [range 7-35] kg receiving continuous renal replacement therapy were included. Concentration-time courses were best described by a one-compartment model with first-order elimination. Body weight (BW) produced significant effects on volume of distribution (V) and BW and continuous renal replacement therapy effluent flow rate (Qeff) produced significant effects on clearance (CL): [Formula: see text] and [Formula: see text], where Vpop and CLpop estimates were 32.5 L and 5.88 L/h, respectively, normalized to a 70-kg BW and median Qeff at 1200 mL/h. Using this final model and Monte Carlo simulations, for patients with Qeff over 1200 mL/h, meropenem continuous infusion was adequate in most cases to attain 100% fT>1-4xMIC. For bacterial infections with a low minimum inhibitory concentration (≤2 mg/L), meropenem intermitent administration was appropriate for patients weighing more than 20 kg with Qeff <500 mL/h and for patients weighing more than 10 kg with Qeff <100 mL/h. CONCLUSIONS: Meropenem exposure in critically ill children receiving continuous renal replacement therapy needs dosing adjustments to the minimum inhibitory concentration that take into account body weight and the continuous renal replacement therapy effluent flow rate.

Cefepime population pharmacokinetics and dosing regimen optimization in critically ill children with different renal function.

OBJECTIVE: Cefepime is commonly used in pediatric intensive care units, where unpredictable variations in the patients' pharmacokinetic (PK) variables may require drug dose adjustments. The objectives of the present study were to build a population PK model for cefepime in critically ill children and to optimize individual initial dosing regimens. METHODS: Children (aged from 1 month to 18 years; body weight >3 kg) receiving cefepime were included. Cefepime total plasma concentrations were measured using high performance liquid chromatography. Data were modelled using nonlinear, mixed-effect modeling software, and Monte Carlo simulations were performed with a PK target of 100% fT > MIC. RESULTS: Fifty-nine patients (median (range) age: 13.5 months (1.1 months to 17.6 years)) and 129 cefepime concentration measurements were included. The cefepime concentration data were best fitted by a one-compartment model. The selected covariates were body weight with allometric scaling and estimated glomerular filtration rate on clearance. Mean population values for clearance and volume were 1.21 L/h and 4.8 L, respectively. According to the simulations, a regimen of 100 mg/kg/d q12 h over 30 min or 100 mg/kg/d as a continuous infusion was more likely to achieve the PK target in patients with renal failure and in patients with normal or augmented renal clearance, respectively. DISCUSSION: Appropriate cefepime dosing regimens should take renal function into account. Continuous infusions are required in critically ill children with normal or augmented renal clearance, while intermittent infusions are adequate for children with acute renal failure. Close therapeutic drug monitoring is mandatory, given cefepime's narrow therapeutic window.

Therapeutic Drug Monitoring of Antibiotics in Critically Ill Children: An Observational Study in a Pediatric Intensive Care Unit.

BACKGROUND: Septic critically ill children are at a high risk of inadequate antibiotic exposure, requiring them to undergo therapeutic drug monitoring (TDM). The aim of this study was to describe the use of TDM for antibiotics in critically ill children. METHODS: The authors conducted a single-center observational study between June and December 2019, with all children treated with antibiotics in a pediatric intensive care unit located in a French university hospital. Standard clinical and laboratory data were recorded. Blood samples were collected for routine laboratory tests, and plasma antibiotic levels were assayed using validated analytical methods. RESULTS: A total of 209 children received antibiotics. TDM was performed in 58 patients (27.8%) who had a greater mean organ dysfunction (according to the International Pediatric Sepsis Consensus Conference) (3 versus 1 in the non-TDM group; P < 0.05) and were treated with antibiotics for longer. A total of 208 samples were analyzed. The median [interquartile range] assay turnaround time was 3 (1-5) days, and 48 (46.2%) of the 104 initial antibiotic concentration values were below the pharmacokinetic/pharmacodynamic targets. A total of 34 (46%) of the 74 off-target TDM measurements available before the end of the antibiotic treatment prompted dose adjustment. This dose adjustment increased the proportion of on-target TDM measurements (70% versus 20% without adjustment). Subsequent measurements of the minimum inhibitory concentration showed that the use of the European Committee on Antimicrobial Susceptibility Testing's epidemiological cutoff values led to underestimation of pharmacokinetic/pharmacodynamic target attainment in 10 cases (20%). CONCLUSIONS: TDM seems to be an effective means of optimizing antibiotic exposure in critically ill children. This requires timely plasma antibiotic assays and minimum inhibitory concentration measurements. It is important to define which patients should undergo TDM and how this monitoring should be managed.

Influence of NAT2 Genotype and Maturation on Isoniazid Exposure in Low-Birth-Weight and Preterm Infants With or Without Human Immunodeficiency Virus (HIV) Exposure.

BACKGROUND: Isoniazid (INH) metabolism depends on the N-acetyl transferase 2 (NAT2) enzyme, whose maturation process remains unknown in low birth weight (LBW) and preterm infants. We aimed to assess INH exposure and safety in infants receiving oral tuberculosis prevention. METHODS: This population pharmacokinetics (PK) analysis used INH and N-acetyl-isoniazid (ACL) concentrations in infants (BW ≤ 4 kg), including preterm, with follow-up for 6 months. PK parameters were described using nonlinear mixed effects modeling. Simulations were performed to assess INH exposure and optimal dosing regimens, using 2 targets: Cmax at 3-6 mg/L and area under the curve (AUC) ≥ 10.52 mg h/L. RESULTS: We included 57 infants (79% preterm, 84% LBW) in the PK analysis, with a median (range) gestational age of 34 (28.7-39.4) weeks. At the time of sampling, postnatal age was 2.3 (0.2-7.3) months and weight (WT) was 3.7 (0.9-9.3) kg. NAT2 genotype was available in 43 (75.4%) patients (10 slow, 26 intermediate, and 7 fast metabolizers). Ninety percent of NAT2 maturation was attained by 4.4 post-natal months. WT, postmenstrual age, and NAT2 genotype significantly influenced INH exposure, with a 5-fold difference in AUC between slow and fast metabolizers for the same dose. INH appeared safe across the broad range of exposure for 61 infants included in the safety analysis. CONCLUSIONS: In LBW/preterm infants, INH dosing needs frequent adjustment to account for growth and maturation. Pharmacogenetics-based dosing regimens is the most powerful approach to deliver safe and equalized exposures for all infants, because NAT2 genotype highly impacts INH pharmacokinetic variability.

Assessment of the Effects of a High Amikacin Dose on Plasma Peak Concentration in Critically Ill Children.

OBJECTIVES: This study aimed to assess the incidence of amikacin plasma peak concentration (Cmax) below 60 mg·L-1 in critically ill children receiving an amikacin dosing regimen of 30 mg kg-1·day-1. Secondary objectives were to identify factors associated with low Cmax and to assess the incidence of acute kidney injury (AKI). METHODS: A retrospective observational study was performed in two French pediatric intensive care units. All admitted children who received 30 mg·kg-1 amikacin and had a Cmax measurement were eligible. Clinical and biological data, amikacin dose, and concentrations were collected. RESULTS: In total, 30 patients were included, aged from 3 weeks to 7 years. They received a median amikacin dosage of 30 mg kg-1·day-1 (range 29-33) based on admission body weight (BW), corresponding to 27 mg kg-1·day-1 (range 24-30) based on actual BW. Cmax was < 60 mg·L-1 in 21 (70%) children and none had a Cmax ≥ 80 mg·L-1. Among the 15 patients with a measured minimum inhibitory concentration (MIC), 13 (87%) had a Cmax/MIC ratio > 8. Univariate analysis showed that factors associated with Cmax < 60 mg·L-1 were high estimated glomerular filtration rate (p = 0.015) and low blood urea concentration (p = 0.001). AKI progression or occurrence was observed after amikacin administration in two (7%) and six (21%) patients, respectively. CONCLUSIONS: Despite the administration of the maximal recommended amikacin dose, Cmax was below the pharmacokinetic target in 70% of our pediatric population. Further studies are needed to develop a pharmacokinetic model in a population of critically ill children to optimize target attainment.

Estimation of piperacillin clearance with different glomerular filtration rate formulas in critically ill children.

AIMS: Glomerular filtration rate (GFR) is difficult to assess in critically ill children using gold standard method and alternatives are needed. This study aimed to determine the most accurate GFR estimation formula for assessing piperacillin clearance in critically ill children, using a published piperacillin pharmacokinetics (PK) population model. METHODS: All children hospitalized in the paediatric intensive care unit of a single institution who were receiving piperacillin were included. PK were described using the nonlinear mixed effect modelling software MONOLIX. In the initial PK model, GFR was estimated according to the Schwartz 1976 formula. We evaluated a set of 12 additional validated formulas, developed using plasma creatinine and/or cystatin C concentrations, in the building model to assess the lowest between-subject variability for piperacillin clearance. RESULTS: We included 20 children with a median (range) postnatal age of 1.9 (0.1-19) years, body weight of 12.5 (3.5-69) kg. Estimated GFR according to the Schwartz 1976 formula was 160.5 (38-315) mL min-1 1.73 m-2 . Piperacillin clearance was best predicted by the Bouvet combined formula. CONCLUSION: The combined Bouvet formula was the most accurate GFR estimation formula for assessing piperacillin clearance in critically ill children.

Are ß-lactam concentrations adequate in severe sepsis and septic shock in children?

AIM OF THE STUDY: Early administration of appropriate antibiotic therapy with adequate concentration is the cornerstone of the severe sepsis and septic shock's treatment. We aim to describe the plasma concentration of the most used ß-lactams in critically ill children, to describe the rate of patients with suboptimal exposure, and associated clinical and biological factors. METHODS: From January 2016 to May 2017, children less than 18 years old with severe sepsis or septic shock were included. Samples were collected in pediatric intensive care unit for children with severe sepsis or septic shock. ß-lactam plasma concentrations were analysed using high performance liquid chromatography. RESULTS: Among the 37 enrolled patients, 24 (64.9%) had insufficient concentration [cefotaxime 7/14 (43%); piperacillin-tazobactam, 10/13 (77%); amoxicillin 6/7 (86%); meropenem 3/6 (50%), cefazolin 1/4 (25%), imipenem 0/2 (0%); ceftazidime 0/1 (0%)]. Insufficient concentrations were associated with early measurements [<72hours from the sepsis' onset (P=0.035) and an increased creatinine clearance (P=0.01)]. CONCLUSION: ß-lactams current dosing in critically ill septic children could be suboptimal.

Early Bacterial Infections After Pediatric Liver Transplantation in the Era of Multidrug-resistant Bacteria: Nine-year Single-center Retrospective Experience.

BACKGROUND: Early bacterial infection is a major and severe complication after liver transplantation (LT). The rise of antimicrobial resistance, especially extended-spectrum beta-lactamase-producing Enterobacteriaceae (ESBL-PE), is a growing concern for these patients. This study aimed to assess the epidemiology of early bacterial infections in a pediatric population, including those caused by multidrug-resistant (MDR) pathogens, and to identify risk factors for infection. METHODS: We conducted a monocentric retrospective study including 142 consecutive LTs performed in 137 children between 2009 and 2017. RESULTS: Ninety-three bacterial infections occurred after 67 (47%) LTs. Among the 82 isolated pathogens, the most common was Klebsiella pneumoniae (n = 19, 23%). Independent risk factors for early bacterial infection were low weight [odds ratio (OR) = 0.96; 95% confidence interval (CI): 0.9-0.99; P = 0.03] and the presence of a prosthetic mesh (OR = 2.4; 95% CI: 1.1-5.4; P = 0.046). Sixty-one children (45%) carried MDR bacteria and 16 infections were caused by MDR pathogens, especially ESBL-producing K. pneumoniae (n = 12). ESBL-PE stool carriage was associated with ESBL-PE infection (OR = 4.5; 95% CI: 1.4-17.4; P = 0.02). Four children died from an infection, three due to ESBL-producing K. pneumoniae. CONCLUSIONS: This study confirmed a shift toward a predominance of Gram-negative early bacterial infections after pediatric LT. The risk factors for infection were low weight and the presence of a prosthetic mesh. ESBL-PE stool carriage was associated with ESBL-PE infection. Adapted antimicrobial prophylaxis and personalized antibiotherapy are mandatory to reduce infection prevalence and mortality.

Population pharmacokinetics of meropenem in critically ill children with different renal functions.

PURPOSE: We aimed to develop a meropenem population pharmacokinetic (PK) model in critically ill children and simulate dosing regimens in order to optimize patient exposure. METHODS: Meropenem plasma concentration was quantified by high-performance liquid chromatography. Meropenem PK was investigated using a non-linear mixed-effect modeling approach. RESULTS: Forty patients with an age of 16.8 (1.4-187.2) months, weight of 9.1 (3.8-59) kg, and estimated glomerular filtration rate (eGFR) of 151 (19-440) mL/min/1.73 m2 were included. Eleven patients received continuous replacement renal therapy (CRRT). Concentration-time courses were best described by a two-compartment model with first-order elimination. Body weight (BW), eGFR, and CRRT were covariates explaining the between-subject variabilities on central/peripheral volume of distribution (V1/V2), inter-compartment clearance (Q), and clearance (CL): V1i = V1pop × (BW/70)1, Qi = Qpop × (BW/70)0.75, V2i = V2pop × (BW/70)1, CLi = (CLpop × (BW/70)0.75) × (eGFR/100)0.378) for patients without CRRT and CLi = (CLpop × (BW/70)0.75) × 0.9 for patients with CRRT, where CLpop, V1pop, Qpop, and V2pop are 6.82 L/h, 40.6 L, 1 L/h, and 9.2 L respectively normalized to a 70-kg subject. Continuous infusion, 60 and 120 mg/kg per day, is the most adequate dosing regimen to attain the target of 50% fT > MIC and 100% fT > MIC for patients infected by bacteria with high minimum inhibitory concentration (MIC) value (> 4 mg/L) without risk of accumulation except in children with severe renal failure. CONCLUSION: Continuous infusion allows reaching the fT > MIC targets safely in children with normal or increased renal clearance.

Piperacillin Population Pharmacokinetics and Dosing Regimen Optimization in Critically Ill Children with Normal and Augmented Renal Clearance.

BACKGROUND: Critically ill children frequently display observed alterations of pharmacokinetic (PK) parameters, leading to a reduction in ß-lactam concentrations. This study aimed to develop a PK population model for piperacillin in order to optimize individual dosing regimens. METHODS: All children aged ≤ 18 years, weighing more than 2.5 kg, and receiving piperacillin infusions were included in this study. Piperacillin was quantified by high-performance liquid chromatography, and PK were described using the non-linear mixed-effect modeling software MONOLIX. Monte Carlo simulations were used to optimize dosing regimens in order to attain two PK targets: 50% fT>MIC and 100% fT>MIC. RESULTS: We included 50 children with a median (range) postnatal age of 2.3 years (0.1-18), body weight (BW) of 11.9 kg (2.7-50), Pediatric Logistic Organ Dysfunction-2 (PELOD-2) severity score of 4 (0-16), and estimated glomerular filtration rate (eGFR) of 142 mL.min-1.1.73 m-2 (29-675). A one-compartment model with first-order elimination adequately described the data. Median (range) values for piperacillin clearance (CL) and volume of distribution were 3 L.h-1 (0.71-10) and 0.33 L.kg-1 (0.21-0.86), respectively. BW was integrated with the allometric relationship. eGFR and PELOD-2 severity score were the covariates explaining between-subject variability in CL and volume, respectively. According to the simulations, extended and continuous infusion provided the highest probability of reaching the target of 50% fT>MIC and 100% fT>MIC for normal and augmented renal clearance, respectively. CONCLUSIONS: Unlike standard intermittent piperacillin dosing regimens, extended and continuous infusion allows the PK targets to be reached, for children with normal or augmented renal clearance. TRIAL REGISTRATION NUMBER: Registered at http://www.clinicaltrials.gov (NCT02539407).

Parents' and children's comprehension and decision in a paediatric early phase oncology trial: a prospective study.

OBJECTIVE: To analyse parents' and children's understanding of consent information and assess their decision-making process in paediatric oncology. DESIGN: Prospective observational study. SETTINGS: Eleven French paediatric oncology units. PATIENTS: Parents and children who have been asked to give consent for participation in an early phase trial. INTERVENTIONS: Thirty-seven children and 119 parents were questioned using an audio-recorded semistructured interview. MAIN OUTCOME MEASURES: The participants' understanding of nine elements of the informed consent was assessed by comparing their answers with the informed consent leaflet. Their decision-making process was also evaluated. RESULTS: Most parents and children had an excellent understanding regarding their participation in a clinical trial (respectively 88.2% and 48.6%), the right to withdraw (76.5% and 43.2%) and the prospects of collective benefits (74.8% and 48.6%). By contrast, less than half of the parents and few of the children correctly understood the alternatives (respectively 47.5% and 27%), the risks related to participation (44.5% and 10.8%), the prospects of individual benefits (33.6% and 10.8%) and the purpose of the clinical trial (12.6% and 2.7%). Twenty-six (70.3%) children participated in the decision-making process. Most parents and children felt they had no choice but to participate in the trial to have access to a new anticancer treatment. CONCLUSIONS: What might appear to be a poor understanding of the research protocol may actually correspond to the families' interpretation of the situation as a coping mechanism. All children (except infants) should get age-tailored information in order for them to have a meaningful involvement in research.

Population Pharmacokinetic Model to Optimize Cefotaxime Dosing Regimen in Critically Ill Children.

BACKGROUND: During sepsis, optimal plasma antibiotic concentrations are mandatory. Modifications of pharmacokinetic parameters could lead to low drug concentrations and therefore, insufficient therapeutic levels. OBJECTIVE: The aim of this study was to build a population pharmacokinetic model for cefotaxime and its metabolite desacetylcefotaxime in order to optimize individual dosing regimens for critically ill children. METHODS: All children aged < 18 years, weighing more than 2.5 kg, and receiving intermittent cefotaxime infusions were included in this study. Cefotaxime and desacetylcefotaxime were quantified by high-performance liquid chromatography. Pharmacokinetics were described using the non-linear mixed-effect modeling software MONOLIX, and Monte Carlo simulations were used to optimize dosing regimen in order to maintain serum concentrations above the target concentration (defined at 2 mg·L-1) throughout the dosing interval. RESULTS: We included 49 children with a median (range) postnatal age of 23.7 (0.2-229) months, and median body weight (range) of 10.9 (2.5-68) kg. A one-compartment model with first-order elimination adequately described the data. Median (range) values for cefotaxime clearance, desacetylcefotaxime clearance, and volume of distribution were 0.97 (0.3-7.1) L·h-1, 3.2 (0.6-16.3) L·h-1, and 0.3 (0.2-0.41) L·kg-1, respectively. Body weight and postnatal age were statistically significant covariates. Cefotaxime-calculated residual concentrations were low, and no patient succeeded in attaining the target. Unlike intermittent administration, a dosing regimen of 100 mg·kg-1·day-1 administered by continuous infusion provided a probability of target attainment of 100%, regardless of age and weight. CONCLUSIONS: Standard intermittent cefotaxime dosing regimens in critically ill children are not adequate to reach the target. We showed that, for the same daily dose, continuous infusion was the only administration that enabled the target to be attained, for children over 1 month of age. As continuous administration is achievable in the pediatric intensive care unit, it should be considered for clinical practice. TRIAL REGISTRATION NUMBER: Registered at http://www.clinicaltrials.gov , NCT02539407.