Intranasal niosomes of nefopam with improved bioavailability: preparation, optimization, and in-vivo evaluation.

OBJECTIVE: One of the greatest challenges drug formulation is facing is poor bioavailability via oral route. In this regard, nasal drug delivery has been commonly used as an alternative route to improve drug bioavailability. Nefopam hydrochloride (NF) is an analgesic drug that suffers from poor bioavailability due to extensive metabolism in liver. Accordingly, the goal of the present study was to improve NF bioavailability via niosomal-based formulation designed for intranasal delivery. MATERIALS AND METHODS: Vesicles were developed by mixing surfactants (Span 20, Span 40, Span 80, and Span 85) at four molar ratios of 1:1, 1:2, 1:3, and 1:4 of cholesterol to surfactant. Entrapment efficiency, particle size, zeta potential, release percentage, ex-vivo permeation parameters, and niosomes' stability were determined. Also, the pharmacokinetic parameters of the optimized formula in in-situ gel base were measured in rats. RESULTS: Niosomes showed entrapment efficiency .80%, particle size ,550 nm, and zeta potential ranging from -16.8±0.13 to -29.7±0.15. The produced vesicles showed significantly higher amounts of drug permeated across nasal mucosa (2.5 folds) and prolonged NF release compared with NF solution. Stability studies of optimum formula showed nonsignificant changes in niosomes parameters over a storage period of 6 months. The in-vivo studies showed a 4.77-fold increase in bioavailability of optimized nasal niosomes compared with oral solution of drug. CONCLUSION: The obtained results revealed the great ability of the produced NF-loaded nio-somes to enhance drug penetration through nasal mucosa and improve its relative bioavailability compared with NF oral solution.

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, distribution, metabolism, and excretion of the dual reuptake inhibitor [(14)C]-nefopam in rats.

1. This study examined the pharmacokinetics, distribution, metabolism, and excretion of [(14)C] nefopam in rats after a single oral administration. Blood, plasma, and excreta were analyzed for total radioactivity, nefopam, and metabolites. Metabolites were profiled and identified. Radioactivity distribution was determined by quantitative whole-body autoradiography. 2. The pharmacokinetic profiles of total radioactivity and nefopam were similar in male and female rats. Radioactivity partitioned approximately equally between plasma and red blood cells. A majority of the radioactivity was excreted in urine within 24 hours and mass balance was achieved within 7 days. 3. Intact nefopam was a minor component in plasma and excreta. Numerous metabolites were identified in plasma and urine generated by multiple pathways including: hydroxylation/oxidation metabolites (M11, M22a and M22b, M16, M20), some of which were further glucuronidated (M6a to M6c, M7a to M7c, M8a and M8b, M3a to M3d); N-demethylation of nefopam to metabolite M21, which additionally undergoes single or multiple hydroxylations or sulfation (M9, M14, M23), with some of the hydroxylated metabolites further glucuronidated (M2a to M2d). 4. Total radioactivity rapidly distributed with highest concentrations found in the urinary bladder, stomach, liver, kidney medulla, small intestine, uveal tract, and kidney cortex without significant accumulation or persistence. Radioactivity reversibly associated with melanin-containing tissues.

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.

The effect of modulated electro-hyperthermia on the pharmacokinetic properties of nefopam in healthy volunteers: A randomised, single-dose, crossover open-label study.

PURPOSE: Nefopam is a widely available analgesic for the management of pain. The aim of this study was to reveal the effect of regional hyperthermia of the abdominal area on the pharmacokinetics of nefopam. MATERIALS AND METHODS: A randomised, single-dose, crossover, open-label study was conducted to reveal the effect of hyperthermia using modulated electro-hyperthermia on the pharmacokinetics of nefopam. The pharmacokinetics of orally administered nefopam without hyperthermia was studied in 12 healthy volunteers and then 7 days later they were treated with nefopam plus modulated electro-hyperthermia to the abdominal area for 1 h. Blood samples were collected up to 24 h after the drug administration. From the blood concentration-time curve, the maxinum plasma concentration (C(max)), time to C(max) (T(max)) and the area under the curve (AUC) were obtained. The safety and tolerability of these treatments were also assessed. RESULTS: The geometric mean ratios (GMRs) ((nefopam + modulated electro-hyperthermia)/nefopam) and the associated 90% confidence intervals (CIs) for C(max), AUC(last) and AUC(inf) were 1.2804 (1.1155∼1.4696), 1.0512 (0.9555∼1.1566) and 1.0612 (0.9528∼1.1819), respectively. The increase in C(max) was statistically significant, and T(max) was significantly shortened. CONCLUSIONS: The significant increase in C(max) and decrease in T(max) indicated that modulated electro-hyperthermia increased the absorption of the orally administered nefopam, thereby transitionally increasing the blood concentration of the drug. The AUC is an important parameter that contributes to the therapeutic effect of drugs. The lack of significant change in AUC suggests that modulated electro-hyperthermia may increases the absorption of orally administered drugs without increasing the systemic adverse effect of the drugs.

Pharmacokinetics of dexamethasone and nefopam administered alone or in combination using a newly developed prefilled multi-drug injector in rats.

BACKGROUND/AIM: It is significant for patients with traumatic brain injury (TBI) to receive prehospital emergency treatment as early as possible to reduce mortality. Therefore, a new prefilled multi-drug injector was developed to improve the treatment of TBI. Here, we studied the pharmacokinetics of dexamethasone (DXM) and nefopam using the injector to investigate the significance of drug interactions and the necessity of dose adjustment. METHODS: Rats were administered DXM and nefopam intramuscularly alone or in combination using the injector. The concentrations of DXM and nefopam were measured by means of HPLC. The noncompartmental approach was used to calculate pharmacokinetic parameters. RESULTS: All animals appeared to tolerate the injection very well. The maximum concentration 90% confidence interval (CI) of nefopam was in the bioequivalence range when nefopam was co-administered with DXM. However, the AUC 90% CI of nefopam was out of the range. A statistically significant alteration was also observed in the clearance of nefopam. The co-administration exhibited no significant influence on the pharmacokinetic parameters of DXM. CONCLUSIONS: These results indicate that the co-administration of DXM and nefopam using the prefilled multi-drug injector significantly alters some pharmacokinetic parameters of nefopam and has a minor effect on DXM pharmacokinetics.

Population pharmacokinetics of nefopam in elderly, with or without renal impairment, and its link to treatment response.

AIMS: Nefopam is a nonmorphinic central analgesic, for which no recommendation exists concerning adaptation of regimen in aged patients with or without renal impairment. The objective was to describe the pharmacology of nefopam in aged patients to obtain guidelines for practical use. METHODS: Elderly patients (n = 48), 65-99 years old, with severe or moderate renal impairment or with normal renal function, were recruited. Nefopam (20 mg) was administered as a 30 min infusion postoperatively. Simultaneously, a 1 min intravenous infusion of iohexol was performed, in order to calculate the glomerular filtration rate. Blood samples were drawn to determine nefopam, desmethyl-nefopam and iohexol plasma concentrations. Nefopam and desmethyl-nefopam concentrations were analysed using a nonlinear mixed-effects modelling approach with Monolix version 4.1.3. The association between pharmacokinetic parameters and treatment response was assessed using logistic regression. RESULTS: A two-compartment open model was selected to describe the pharmacokinetics of nefopam. The typical population estimates (between-subject variability) for clearance, volume of distribution, intercompartmental clearance and peripheral volume were, respectively, 17.3 l h(-1) (53.2%), 114 l (121%), 80.7 l h(-1) (79%) and 208 l (63.6%). Morphine requirement was related to exposure of nefopam. Tachycardia and postoperative nausea and vomiting were best associated with maximal concentration and the rate of increase in nefopam plasma concentration. CONCLUSIONS: We identified the nefopam pharmacokinetic predictors for morphine requirement and side-effects, such as tachycardia and postoperative nausea and vomiting. In order to maintain morphine sparing and decrease side-effects following a single dose of nefopam (20 mg), simulations suggest an infusion time of >45 min in elderly patients with or without renal impairment.

To enhance the efficiency of nefopam transdermal iontophoresis by using a novel method based on ion-exchange fiber.

BACKGROUND: In the system of the iontophoresis, the external electric field made the ions in the system moving directly, then, the current was generated. Because the current was contributed by all ions in the system, and the small ions with large amount often had higher conductibility than the drug ions, the fraction of the total current contributed by the drug ions was often low. It was the main reason for the generally low efficiency of the transdermal iontophoretic drug delivery. OBJECTIVES: The objective of this study was to find a novel method to increase the fraction of the total current contributed by the drug ions so as to enhance the drug's iontophoretic delivery. METHOD: Iontophoretic transport of nefopam hydrochloride solution and iontophoretic transport of nefopam assisted by ion-exchange materials, including ion-exchange resin, ion-exchange membrane and ion-exchange fiber, across the rat skin were investigated. RESULTS: Both in vitro and in vivo iontophoretic transport experiments showed that the efficiency of the nefopam-fiber iontophoretic system for nefopam permeating across rat skin was the highest among four iontophoretic systems (nefopam solution, nefopam-resin, nefopam-membrane and nefopam-fiber). CONCLUSION: The results of this study suggested that there was an enhancement of nefopam across rat skin by ion-exchange fibers in ion-exchange fibers assisted iontophoresis. The present study has demonstrated the potential of a new approach of using ion-exchange fibers to improve the efficiency of the transdermal iontophoresis for cationizable drugs.

Study of pharmacokinetics and comparative bioavailability of nefopam 30 mg tablets in twelve fasting healthy Pakistani male young subjects: single-dose, randomized, two-period, two-treatment and two-way cross-over design.

OBJECTIVE: To study the pharmacokinetics and comparative bioavailability of nefopam tablets (Acupan®). SUBJECTS AND METHODS: Experimentation of this study was based on a single-dose, two-sequence, cross-over randomized design using 12 fasting healthy Pakistani male young subjects. This validated LC/MS method was applied to a pharmacokinetic and bioavailability study in 12 fasting healthy Pakistani male subjects from the blood samples taken up to 24 h after an oral dose of one tablet of 30 mg nefopam in a double-blind, randomized, cross-over design. RESULTS: The mean maximum plasma concentration (C(max)) for the reference formulation was 60.71 ± 2.36 ng/ml (± SEM) and for test formulation 60.46 ± 1.30 ng/ml (± SEM). The mean time to reach maximum plasma concentration (T(max)) values of reference and test formulations was 1.63 ± 0.13 h (± SEM) and 1.83 ± 0.07 h (± SEM), respectively. The mean ± SEM values of AUC(0-)∞ for the reference and test formulations were 293.01 ± 16.09 ng·h/ml and 307.53 ± 8.99 ng·h/ml, respectively. CONCLUSION: The results showed that both formulations possessed almost the same relative bioavailability and pharmacokinetic parameters.

Nefopam pharmacokinetics in patients with end-stage renal disease.

BACKGROUND: Treatment of intense postoperative pain in patients with end-stage renal disease (ESRD) is a recurrent problem for anesthesiologists because of the risk of accumulation of numerous molecules and their metabolites. Nefopam is a potent analgesic metabolized by the liver and weakly eliminated intact in urine that may offer advantages for use in patients with ESRD because it lacks respiratory-depressive effects. However, the effects of renal failure on nefopam disposition have never been investigated. METHODS: We studied 12 ESRD patients (creatinine clearance < 20 mL/min, mean age 57 ± 13 years) having surgery under general anesthesia to create or repair an arteriovenous fistula. Postoperatively, after complete recovery from anesthesia, each patient received a single 20-mg dose of nefopam IV over 30 minutes. Nefopam and desmethyl-nefopam concentrations in plasma samples obtained over 48 hours were determined by liquid chromatography-tandem mass spectrometry. The pharmacokinetic parameter values obtained were compared with those of 12 healthy 50- to 60-year-old volunteers who also received a single 20-mg nefopam infusion over 30 minutes using a population pharmacokinetic approach. RESULTS: Healthy volunteers and ESRD patients had comparable demographic characteristics. In comparison with those volunteers, ESRD patients had a lower volume of central compartment (115 and 53 L vs. 264 L for patients not yet hemodialyzed and on chronic hemodialysis, respectively; P < 0.001) and lower mean nefopam clearance (37.0 and 27.3 L/h vs. 52.9 L/h, P < 0.001), resulting in higher mean nefopam peak concentration (121 and 223 ng/mL vs. 61 ng/mL, P < 0.001). CONCLUSIONS: Nefopam distribution and elimination are altered in patients with ESRD, resulting in heightened exposure. To avoid too-high concentration peaks, it is suggested that the daily nefopam dose be reduced by 50%.

Development and evaluation of nefopam transdermal matrix patch system in human volunteers.

Nefopam hydrochloride, a nonsteroidal anti-inflammatory drug, is administered in tablet form three times daily or as intramuscular injection at 6-h intervals to treat disorders such as acute or constant pain. It is also used for a prolonged treatment of severe pain, when morphine therapy has to be withdrawn for morphine-related dependence. To achieve a constant drug-plasma level of nefopam for a prolonged period, a transdermal drug delivery system was fabricated in our present study by employing suitable experimental hydrophilic and lipophilic polymeric combinations of polyvinyl pyrrolidone (PVP) and ethyl cellulose (EC). Physical studies including weight variation, moisture content, moisture uptake, flatness, external morphology of the formulations, and in vitro drug release were performed. Drug-excipient interaction studies were carried out using Fourier transform infrared spectroscopy. In vitro skin permeation study with cadaver skin was conducted using modified Keshary-Chein diffusion cells. Interactions between nefopam and PVP seem to contribute to the slow and controlled release pattern of nefopam. The scanning electron microscopy evaluation of prepared matrix patches revealed that drug was dispersed uniformly in polymeric matrix. In vitro drug release study showed that an increase in concentration of hydrophilic polymer, PVP, enhanced drug release substantially. In vitro skin permeation study showed variable permeation profiles of nefopam from the experimental patches. Among the formulations, PVP:EC (1:3) was found to provide slowest release and maximum sustained skin permeation of drug in vitro. Application of those patches, PVP:EC (1:3), on human volunteers was found to provide systemic availability of the drug till 48 h.

Cyclodextrin inclusion complexes of the central analgesic drug nefopam.

Inclusion complexes of nefopam base (NEF) with various beta-cyclodextrins (betaCDs) were investigated. All tested betaCDs increased the apparent solubility of NEF according to a Higuchi AL type plot (except betaCD: AN type plot), which indicates the formation of 1:1 stoichiometry inclusion complexes. 1H-NMR and 13C-NMR experiments showed that complexation by CDs allowed an easy separation of the R and S enantiomers. Based on spectral data obtained from the two-dimensional rotating frame nuclear Overhauser effect spectroscopy (2D-ROESY), a reasonable geometry for the complexes could be proposed implicating the insertion of the benzoxazocine ring into the wide end of the torus cavity.

Comparative pharmacokinetics and pharmacodynamics of intravenous and oral nefopam in healthy volunteers.

To determine the pharmacokinetic, subjective effects of a single 20 mg dose of nefopam administered either intravenously or orally in healthy volunteers, twenty-four healthy Caucasian men received 20 mg nefopam orally+placebo intravenous infusion and placebo orally+intravenous infusion of 20 mg nefopam with one week interval, in a double-blind, double-dummy cross-over study. Nefopam and desmethyl-nefopam plasma concentrations were measured by HPLC with UV detection up to 48 hr after drug administration. Self-rating questionnaires (Mood and vigilance Visual Analogue Scales, Addiction Research Centre Inventory) and drug safety were investigated. The F value (bioavailability) of the parent drug was 0.36+/-0.13. The AUCoral/AUCiv ratio of nefopam+desmethyl-nefopam was 0.62+/-0.23. The half-life of nefopam was similar whether administered orally (5.1+/-1.3 hr) or intravenously (5.1+/-0.6 hr). The half-life of desmethyl-nefopam was two to three times longer than that of the parent molecule (orally: 10.6+/-3.0 versus 5.1+/-1.3 hr, P<10(-4) and intravenously: 15.0+/-2.4 versus 5.1+/-0.6 hr, P<10(-4)). As assessed by the Addiction Research Centre Inventory, no evidence of abuse liability in healthy, drug-naive volunteers was observed. On visual analogue scales, volunteers rated themselves as more drowsy, less alert, less energetic and less anxious after oral compared to intravenous administration. The AUC0-->24 hr of anxiety and energy parameters were not different after oral and intravenous administration: 90+/-142 versus 35+/-84 (P=0.27) and 66+/-74 versus 46+/-54 mm x hr (P=0.36), respectively. The AUC0-->24 hr of drowsiness and alertness parameters were significantly greater after oral than after intravenous administration: 68+/-65 versus 27+/-30 (P=0.005) and 54+/-63 versus 28+/-48 mm x hr (P=0.03), respectively. A clockwise hysteresis loop was observed for drowsiness in 16 out of 24 volunteers after oral administration. The results suggest that in healthy volunteers desmethyl-nefopam may contribute to the pharmacodynamic effects of single dose nefopam solution administered orally. This study shows a rather low bioavailability of nefopam given in intravenous solution when administered orally. Nevertheless, when the main metabolite desmethyl-nefopam is taken into account, the ratio of the areas under the curves is almost doubled.

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.

Fatal overdosage with nefopam (Acupan).

This paper presents a fatality due to massive, intravenous self-administration of nefopam (Acupan), a non-opiate central analgesic, in a 37-year-old female. Nefopam was measured in various postmortem samples by means of high-pressure liquid chromatography coupled to mass spectrometry via an ionspray interface. Heart blood concentration was 4.38 microg/mL and exceeded by approximately 30 times the highest therapeutic levels with the usual reservations concerning possible postmortem redistribution. This is only the third case of death following nefopam overdose reported in the literature.

Nefopam enantiomers: preclinical pharmacology/toxicology and pharmacokinetic characteristics in healthy subjects after intravenous administration.

Nefopam (NEF) is a potent analgesic compound administered as a racemic mixture. Previous in vitro and in vivo studies with nefopam enantiomers have shown that (+)nefopam [(+)NEF] is substantially more potent than (-)nefopam [(-)NEF]. Differences between enantiomers have also been suggested in metabolic studies in vitro. The impact of these differences in vivo is not known because there is little or no information on the relative plasma concentrations of the enantiomers or on their kinetics. In this study, individual enantiomers of nefopam were synthesized and examined for acute toxicity in male and female rats and mice. Pharmacologic properties of enantiomers were examined using in vitro binding assays and antinociceptive tests in rats and mice. Additionally, a pharmacokinetic study was conducted in human volunteers. Subjects were administered 20 mg nefopam as Acupan(R) either as a 5- or 20-min intravenous infusion. In a control phase, subjects were administered only vehicle. Blood samples were collected through the following 24 h. Plasma samples were analyzed for individual enantiomers using a chiral assay developed for this purpose. The pharmacologic differences of previous studies were confirmed in receptor binding assays and in the hot plate and the formalin tests in mice. Neither enantiomer demonstrated substantial activity in the tail flick test in rats. No significant differences were revealed between LD(50) values of nefopam enantiomers after oral or intravenous administration in male and female rats or mice. There were no significant differences in AUC(0-infinity), C(max), or half-life between enantiomers following intravenous administration. Based on these findings, there is currently no compelling rationale to justify administering or monitoring individual enantiomers.

Nefopam hydrochloride degradation kinetics in solution.

A stability-indicating reversed-phase high performance liquid chromatographic method was developed for the detection of nefopam hydrochloride and its degradation products under accelerated degradation conditions. The degradation kinetics of nefopam hydrochloride in aqueous solutions over a pH range of 1.18 to 9.94 at 90 +/- 0.2 degrees C was studied. The degradation of nefopam hydrochloride was found to follow apparent first-order kinetics. The pH-rate profile shows that maximum stability of nefopam hydrochloride was obtained at pH 5.2-5.4. No general acid or base catalysis from acetate, phosphate, or borate buffer species was observed. The catalytic rate constants on the protonated nefopam imposed by hydrogen ion and water was determined to be 7.16 X 10(-6) M-1 sec-1, and 4.54 X 10(-9) sec-1, respectively. The pKa of nefopam hydrochloride in aqueous solution was determined to be 8.98 +/- 0.33 (n = 3) at 25 +/- 0.2 degrees C by the spectrophotometric method. The catalytic rate constant of hydroxyl ion on the degradation of nefopam in either protonated or nonprotonated form was determined to be 6.63 X 10(-6) M-1 sec-1 and 4.06 X 10(-6) M-1 sec-1, respectively. A smaller effect of hydroxyl ion on the degradation of nonprotonated than on the degradation of protonated nefopam was observed.(ABSTRACT TRUNCATED AT 250 WORDS)