A Simultaneous Mixed-Effects Pharmacokinetic Model for Nefopam, N-desmethylnefopam, and Nefopam N-Oxide in Human Plasma and Urine.

BACKGROUND AND OBJECTIVE: Nefopam is a non-opioid, non-steroidal, central analgesic thought to act via multiple mechanisms including potent inhibition of serotonin-norepinephrine reuptake and modulation of voltage-sensitive calcium and sodium channels. There has been a resurgence in its use for postoperative pain and neuropathic pain. Dosing route-dependent metabolism and clinical effects have been described following intravenous and oral nefopam. N-desmethylnefopam and nefopam N-oxide are metabolites of clinical interest. We sought to develop a joint pharmacokinetic model to simultaneously describe the plasma and urinary pharmacokinetics of nefopam and the two metabolites following an oral pharmacological dose of [14C]-nefopam to healthy volunteers, and to estimate inter-individual variability in their pharmacokinetics. METHODS: Pharmacokinetic data for the parent and metabolites were analyzed simultaneously using NONMEM® (nonlinear mixed-effect modeling) v7.3. The modeling process evaluated, in part, one- and two-compartment linear pharmacokinetic models for nefopam and a single compartment for each of the two metabolites. Pathways for presystemic metabolism of both metabolites were explored. RESULTS: The final structural model simultaneously described the plasma and urinary pharmacokinetics of nefopam and the two metabolites. It consists of a central compartment for nefopam and for each of the two metabolites, as well as a peripheral compartment for the parent, and the associated urine compartments. The rapid formation and appearance of the N-oxide in plasma, characterized by concentrations that peak earlier than the parent, could be described by presystemic formation in the gastrointestinal tract. CONCLUSIONS: A descriptive, robust and predictive parent-metabolite model has been developed using a population mixed-effects approach to characterize the pharmacokinetics of nefopam and its metabolites simultaneously in healthy subjects following oral administration of nefopam. The model may be used for dose selection, analysis of sparse data, identification of intrinsic and extrinsic factors, and to model the clinical effects of each analyte.

Pharmacokinetics, metabolism, and excretion of nefopam, a dual reuptake inhibitor in healthy male volunteers.

1. The disposition of nefopam, a serotonin-norepinephrine reuptake inhibitor, was characterized in eight healthy male volunteers following a single oral dose of 75 mg [(14)C]-nefopam (100 µCi). Blood, urine, and feces were sampled for 168 h post-dose. 2. Mean (± SD) maximum blood and plasma radioactivity concentrations were 359 ± 34.2 and 638 ± 64.7 ngEq free base/g, respectively, at 2 h post-dose. Recovery of radioactive dose was complete (mean 92.6%); a mean of 79.3% and 13.4% of the dose was recovered in urine and feces, respectively. 3. Three main radioactive peaks were observed in plasma (metabolites M2 A-D, M61, and M63). Intact [(14)C]-nefopam was less than 5% of the total radioactivity in plasma. In urine, the major metabolites were M63, M2 A-D, and M51 which accounted for 22.9%, 9.8%, and 8.1% of the dose, respectively. An unknown entity, M55, was the major metabolite in feces (4.6% of dose). Excretion of unchanged [(14)C]-nefopam was minimal.

Nefopam Hydrochloride: A Fatal Overdose.

Nefopam is a non-opiate analgesic commonly used for the treatment of moderate to severe pain. A case of a 37-year-old male who was found dead in the morning is presented. An autopsy was performed and femoral venous blood, heart blood, urine, and vitreous humor were submitted for toxicological analysis. A general drug screen detected the presence of nefopam, caffeine, nicotine, citalopram, gabapentin, amitriptyline, diazepam and paracetamol in cardiac blood. Nefopam was quantitated by high-performance liquid chromatography with diode-array detection. Nefopam was found at the following concentrations: 13.6 mg/L in unpreserved femoral blood; 14.7 mg/L in preserved (fluoride-oxalate) femoral blood; 21.2 mg/L in unpreserved cardiac blood and 4.5 mg/L in preserved vitreous. Citalopram was present at a concentration of 0.7 mg/L (femoral blood) and 0.9 mg/L (cardiac blood). Ethanol analyzed by headspace gas chromatography (GC-FID) was detected in preserved (fluoride-oxalate) vitreous (14 mg/100 mL) and preserved (fluoride-oxalate) urine 50 mg/100 mL. Death was attributed to atherosclerotic coronary artery disease and therapeutic drug toxicity.

Positive interference of the analgesic nefopam in the urine immunoassay for benzodiazepines in a secure setting.

An inpatient on a secure unit with a history of bipolar affective disorder and physical complaints including pain was prescribed carbamazepine, quetiapine, dihydrocodeine, nefopam, paracetamol and various aperients. A benzodiazepine urine test by immunoassay was positive. Initial literature searches did not suggest a candidate drug for positive interference. Other explanations were excluded. Positive results continued, despite room searches and other disruptive security measures. Further literature searches revealed one experimental series demonstrating positive interference of nefopam in the relevant assay. Benzodiazepine assays were negative after cessation of nefopam. This is the first such clinical case to our knowledge.

Effect of route of administration on the pharmacokinetic behavior of enantiomers of nefopam and desmethylnefopam.

Nefopam hydrochloride is a non-narcotic analgesic used parenterally and orally as a racemic mixture for the relief of postoperative pain. However, no information is presently available on the oral kinetics of (+) and (-) nefopam in humans. Also, nefopam is metabolized by N-demethylation but it is not known whether the desmethylnefopam enantiomers (DES1 and DES2) are present in plasma following intravenous (I.V.) or oral administration of parent drug. To address these issues, 24 healthy white male subjects received two treatments using a double-blind, placebo-controlled crossover design: oral administration of 20 mg nefopam hydrochloride solution or a placebo solution on a sugar cube, simultaneously with a continuous infusion of 20 mg nefopam hydrochloride or placebo infusion. A chiral assay using LC-MS was developed for the simultaneous determination of both enantiomers of the parent drug and its metabolite in plasma and urine. Following I.V. administration, the kinetics of (+) and (-) nefopam could be fitted to a bi-exponential equation but exhibited no stereoselectivity. Both enantiomers had large clearances (53.7 and 57.5 L/hr) and volumes of distribution (390 and 381 L) and half-lives around 5 hours. Following oral administration, (+) and (-) nefopam were rapidly absorbed with bioavailabilities of 44% and 42%, respectively, probably due to a first-pass effect. After I.V. administration, the enantiomers of desmethylnefopam exhibited lower concentrations and longer half-lives (20.0 h for DES1 and 25.3 h for DES2) relative to nefopam enantiomers. Following oral administration, desmethylnefopam enantiomers' plasma concentrations peaked earlier and higher than after I.V. administration (P < 0.05). Following I.V. and oral administration, desmethylnefopam enantiomers showed stereoselectivity in AUC and Cmax values. Urinary excretion of parent and metabolite enantiomers was less than 5% of dose. This study shows that desmethylnefopam enantiomers can contribute to the analgesic effect of racemic nefopam only when it is administered orally.

Sensitive determination of nefopam and its metabolite desmethyl-nefopam in human biological fluids by HPLC.

Nefopam (NEF) and desmethyl-nefopam (DMN) were assayed simultaneously in plasma, globule and urine samples using imipramine as internal standard. A liquid-liquid extraction procedure was coupled with a reverse phase high-performance liquid chromatography system. This system requires a mobile phase containing buffer (15 mM KH(2)PO(4) with 5 mM octane sulfonic acid: pH 3.7) and acetonitrile (77:33, v/v) through (flow rate=1.5 ml/min) a C(18) Symmetry column (150x4.6 I.D., 5 micrometer particle size: Waters) and a UV detector set at 210 nm. Internal standard was added to 1 ml of plasma or globule sample or 0.5 ml of urine sample, prior to the extraction under alkaline ambiance with n-hexane. The limits of quantification were 1 and 2 ng/ml for both molecules in plasma and globule, respectively; 5 and 10 ng/ml for NEF and DMN in urine, respectively. The method proved to be accurate and precise: the relative error at three concentrations ranged from -13.0 to +12.3% of the nominal concentration for all molecule and biological fluid; the within-day and between-day precision (relative standard deviation %) ranged from 1.0 to 10.1% for all the molecules and biological fluids. The method was linear between 1 and 60 ng/ml for both molecules in the plasma; 2 and 25 ng/ml for both molecules in the globule; 25 and 250 ng/ml for NEF and 50 and 500 ng/ml for DMN in the urine: correlation coefficients of calibration curves (determined by least-squares regression) of each molecule were higher than 0.992 whatever the biological fluid and during the pre-study and in-study validations. This method was successfully applied to a bio-availability study of NEF in healthy subjects.