Vecuronium pharmacokinetics in patients with major burns.

BACKGROUND: Burn patients develop resistance to non-depolarizing neuromuscular blocking agents (NDNMBAs) and require a significantly large dose to produce a desired clinical response. Pathophysiological changes related to burn injury may alter pharmacokinetics (PK) and pharmacodynamics of NDNMBAs. The purpose of this study was to compare vecuronium PK in burns vs non-burns. METHODS: Twenty adults, aged 23-58 yr, with 27-81% total body surface area (TBSA) burn, were studied at 4-57 post-burn days and compared with age- and sex-matched, non-burn controls. Vecuronium 0.12 mg kg(-1) was given i.v. as a single bolus within 10 s. Blood samples (n=20) were collected over 12 h at predetermined time points. NONMEM was used to describe plasma drug concentration-time profiles for burns and non-burns. RESULTS: A three-compartment model best described vecuronium concentration-time profiles. Burn patients showed enhanced distributional clearance at the terminal phase (0.12 vs 0.095 litre min(-1), P<0.0001), which yielded shorter elimination half-life for vecuronium (5.5 vs 6.6 h, P<0.001). BURN was the single most significant covariate that explained the altered vecuronium disposition in burns. CONCLUSIONS: The altered drug distribution between tissues may partially explain the known resistance to vecuronium in patients with major burns.

Quantitative Systems Pharmacology Model of NO Metabolome and Methemoglobin Following Long-Term Infusion of Sodium Nitrite in Humans.

A long-term sodium nitrite infusion is intended for the treatment of vascular disorders. Phase I data demonstrated a significant nonlinear dose-exposure-toxicity relationship within the therapeutic dosage range. This study aims to develop a quantitative systems pharmacology model characterizing nitric oxide (NO) metabolome and methemoglobin after sodium nitrite infusion. Nitrite, nitrate, and methemoglobin concentration-time profiles in plasma and RBC were used for model development. Following intravenous sodium nitrite administration, nitrite undergoes conversion in RBC and tissue. Nitrite sequestered by RBC interacts more extensively with deoxyhemoglobin, which contributes greatly to methemoglobin formation. Methemoglobin is formed less-than-proportionally at higher nitrite doses as characterized with facilitated methemoglobin removal. Nitrate-to-nitrite reduction occurs in tissue and via entero-salivary recirculation. The less-than-proportional increase in nitrite and nitrate exposure at higher nitrite doses is modeled with a dose-dependent increase in clearance. The model provides direct insight into NO metabolome disposition and is valuable for nitrite dosing selection in clinical trials.CPT: Pharmacometrics & Systems Pharmacology (2013) 2, e60; doi:10.1038/psp.2013.35; published online 31 July 2013.