Summary:A retrospective population pharmacokinetic (PPK) analysis was performed in 24 pediatric patients (PEDS) (0.45-16.7 years old) receiving i.v. busulfan/cyclophosphamide (i.v. Bu/Cy 4) regimen prior to allogeneic hematopoietic stem cell transplantation. I.V. Bu doses were given as a 2-hour infusion every 6 h over 4 days. Initial dosing of i.v. Bu was 1 mg/kg for children p4 years old and 0.8 mg/kg for patients 44 years old. Bu plasma concentrations at doses 1, 9 and 13 were analyzed through a multivariate NONMEM analysis. A close log-linear relationship between body weight (BW) and i.v. Bu clearance was demonstrated with no further age-dependency or gender effect. The interpatient coefficient of variation (CV) in Bu clearance significantly decreased from 56% (covariate-free model) to 19% (BW covariate model) and reproducible i.v. Bu exposure between doses was illustrated (intraindividual CV ¼ 9%). Based on the PPK model, a novel Bu dosing regimen (ie: doses in mg/kg adjusted to discrete weight categories) for a better AUC targeting was developed by simulation on 1000 patients. Age-based dosing was demonstrated not to be clinically relevant with i.v. Bu. Use of the new BW-based dosing appears to be more appropriate for the PEDS.
The objective of this study was to characterize the pharmacokinetics (PK) of intravenous busulfan in pediatric patients and provide dosing recommendations. Twenty-four pediatric patients were treated with intravenous busulfan, 1.0 or 0.8 mg/kg for ages < or = 4 years or > 4 years, respectively, 4 times a day for 4 days. Dense PK sampling was performed. Body weight, age, gender, and body surface area were explored for effects on PK, and Monte Carlo simulations were performed to assess different dosing regimens. The PK of intravenous busulfan was described by a 1-compartment model with clearance of 4.04 L/h/20 kg and volume of distribution of 12.8 L/20 kg. Simulations indicated that the mg/kg and mg/m2 regimens were similar and achieved the desired target exposure in approximately 60% of patients. This model suggests that patients < or = 12 kg should be dosed at 1.1 mg/kg and those > 12 kg dosed at 0.8 mg/kg. Therapeutic drug monitoring and dose adjustment will further improve therapeutic targeting.
Sodium oxybate, also known as gamma-hydroxybutyric acid (GHB), was discovered in 1960 and has been described both as a therapeutic agent with high medical value and, more recently, a substance of abuse. The naturally occurring form of this drug is found in various body tissues but has been studied most extensively in the CNS where its possible function as a neurotransmitter continues to be studied. Sodium oxybate has been approved in different countries for such varied uses as general anaesthesia, the treatment of alcohol withdrawal and addiction, and, most recently, cataplexy associated with narcolepsy. During the 1980s, easy access to GHB-containing products led to various unapproved uses, including weight loss, bodybuilding and the treatment of sleeplessness, sometimes with serious long-term effects. The availability of these unapproved and unregulated forms of the drug led to GHB and its analogues being popularised as substances of abuse and subsequent notoriety as agents used in drug-facilitated sexual assault, or 'date rape', eventually leading to the prohibition of GHB sales in the US. Legal efforts to control the sale and distribution of GHB and its analogues nearly prevented the clinical development of sodium oxybate for narcolepsy in the US. However, following extensive discussions with a variety of interested parties, a satisfactory solution was devised, including legislative action and the development of the Xyrem Risk Management Program. Amendments to the US Controlled Substances Act made GHB a schedule I drug, but also contained provisions that allow US FDA-approved products to be placed under schedule III. This unique, bifurcated schedule for sodium oxybate/GHB allowed the clinical development of sodium oxybate to proceed and, in July 2002, it was approved by the FDA as an orphan drug for the treatment of cataplexy in patients with narcolepsy as Xyrem(sodium oxybate) oral solution. To promote the safe use of sodium oxybate, as well as alleviate concerns over possible diversion and abuse following product approval, a proprietary restricted drug distribution system was created, called the Xyrem Success Program. Components of the programme include a centralised distribution and dispensing system, a physician and patient registry, compulsory educational materials for patients and physicians, a specially trained pharmacy staff, a method for tracking prescription shipments, and an initial post-marketing surveillance programme. The system has created a unique opportunity to provide both physician and patient education and ongoing patient counselling, promoting greater drug safety and enhanced patient compliance.
Narcolepsy, a rare disease with a prevalence of 0.05% in the general population, affects an estimated 140,000 patients in the United States. Patients have been able to lead fuller personal and professional lives since the Food and Drug Administration approved sodium oxybate (Xyrem) in 2002 for treatment of cataplexy in patients with narcolepsy. Previously, gamma-hydroxybutyrate (GHB), the active ingredient of sodium oxybate, had been a substance of abuse, most notoriously as a date-rape drug. Public Law 106-172, the date-rape prohibition act enacted in 2000, was modified to allow the drug to be legally administered for medical purposes. Because of the apprehension regarding the risk of possible drug diversion after the approval of sodium oxybate and concerns about safety, the Xyrem Risk Management Program was created. This program has been successful in satisfying the needs of patients and physicians while ensuring responsible distribution of the drug.
Iron accumulation and overload in beta thalassaemia patients are associated with significant morbidity and mortality. Iron chelators are used to manage iron accumulation but side effects and compliance issues restrict the use of available chelators. Deferitrin (Genzyme Corporation) is an orally available iron chelator intended for iron overload. Method: Patients were dosed in 4 cohorts, receiving 5, 10, 15 and 25 mg/kg/day of deferitrin. Deferitrin dosing in cohorts 1–3 was once daily for 12 weeks. Cohort 4 received deferitrin twice daily (BD) for 48 weeks (12.5mg/kg BD, 25 mg/kg/day). Pharmacokinetics (PK) were assessed in a subset of up to 5 patients in each cohort, pre-dose and 1, 2, 4 and 8 hours post dose. All patients had trough levels assessed at weeks 1, 6 and 12 (all Cohorts) and additionally at weeks 24, 36 and 48 for Cohort 4. PK parameters were determined by model independent (non-compartmental) analyses. Safety was assessed by collection of adverse events and laboratory assessments with renal parameters measured weekly due to observations of renal toxicity in preclinical testing. Efficacy (change in liver iron concentration (LIC)) was assessed by SQUID (superconducting quantum interference device) in Turin, Italy, between screening and end of study. Iron excretion and intake were estimated by calculation:Iron excretion due to deferitrin = Iron Intake (mg/kg/day) - TBI (mg/kg/day)Iron Intake (mg/kg/day) = [total mL pRBC (exclude last BT×) × 1.08] / [Weight (kg) × Days (Between 1st & last BT×)]TBI (mg/kg/day) = Change in LIC (mg Fe/g dry weight) × [10.6 (Angelucci Factor) / D (Days on deferitrin)] Key: pRBC = packed red blood cells, BT× = blood transfusion, TBI=Total Body Iron. Results: PK: PK for deferitrin dosed once daily was linear and dose proportional. The serum half-life was 1.3–1.8 hrs, clearance was 226–340 mL/min and mean residence time was 2.8–3.4 hrs for once daily dosing. PK data from BD dosing is not yet available. Safety: Deferitrin dosed once daily was generally well tolerated (Cohorts 1–3). Slight rises in transaminases were seen at 10 and 15 mg/kg/day. A large proportion of enrolled patients were hepatitis C positive (73%). When dosed BD (12.5 mg/kg BD in Cohort 4), 3 patients developed renal toxicity after 4–5 weeks of treatment. Two patients experienced increased proteinuria (max 3.73 g/L & 3.29 g/L) and one patient suffered acute renal failure (peak serum creatinine 4.1 mg/dL, lowest GFR 27 mmol/L). All patients recovered normal renal function after stopping treatment. No patients were re-challenged with deferitrin. Dosing was terminated in all patients because of safety concerns. Efficacy: Mean iron excretion in mg/kg/day (S.D) for Cohort 1 was 0.22 (0.22), Cohort 2 was 0.45 (0.14) and Cohort 3 was 0.33 (0.12). The reasons for the lack of dose proportionality in iron excretion are unclear. Efficacy could not be assessed in Cohort 4 due to early termination of the study. Conclusions: Deferitrin dosed once daily was generally well tolerated and associated with a mean iron excretion of 0.34 mg/kg/day. Deferitrin dosed BD (12.5mg/kg BD) was associated with unacceptable renal toxicity and led to study termination. Deferitrin does not appear to have an acceptable therapeutic margin to allow sufficient iron excretion for long-term administration.
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