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.

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.

Specific and sensitive analysis of nefopam and its main metabolite desmethyl-nefopam in human plasma by liquid chromatography-ion trap tandem mass spectrometry.

A specific and sensitive liquid chromatography-tandem mass spectrometric (LC-MS-MS) method using an ion trap spectrometer was developed for quantitation of nefopam and desmethyl-nefopam in human plasma. Nefopam, desmethyl-nefopam and the internal standard (ethyl loflazepate) were extracted in a single step with diethyl ether from 1 mL of alkalinized plasma. The mobile phase consisted of acetonitrile with 0.1% formic acid (50:50, v:v). It was delivered at a flow-rate of 0.3 mL/min. The effluent was monitored by MS-MS in positive-ion mode. Ionisation was performed using an electrospray ion source operating at 200 degrees C. Nefopam and desmethyl-nefopam were identified and quantified in full scan MS-MS mode using a homemade MS-MS library. Calibration curves were linear over the concentration range of 0.78-100 ng/mL with determination coefficients >0.996. This method was fast (total run time<6 min), accurate (bias<12.5%), and reproducible (intra- and inter-assay precision<17.5%) with a quantitation limit of 0.78 ng/mL. The high specificity and sensitivity achieved by this method allowed the determination of nefopam and desmethyl-nefopam plasma levels in patients following either intermittent or continuous intravenous administration of nefopam.

Nefopam blocks voltage-sensitive sodium channels and modulates glutamatergic transmission in rodents.

In order to specify the nature of interactions between the analgesic compound nefopam and the glutamatergic system, we examined the effects of nefopam on binding of specific ligands on the three main subtypes ionotropic glutamate receptors: N-methyl-D-aspartate (NMDA), alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA), or quisqualic acid (QA) and kainic acid (KA) in rat brain membrane preparations. Functionally, we investigated the effects of nefopam against the seizures induced by agonists of these excitatory glutamate receptors in mice. Since the synaptic release of glutamate mainly depends upon the activation of membrane voltage-sensitive sodium channels (VSSCs), the nature of interactions between nefopam and these ionic channels was studied by evaluating the effects of nefopam on binding of 3H-batrachotoxinin, a specific ligand of the VSSCs in rat brain membrane preparations. The functional counterpart of the binding of nefopam on VSSCs was evaluated by its effects on the 22Na uptake-stimulated by veratridine on human neuroblastoma cells and in the maximal electroshock test in mice. Nefopam showed no affinity for the subtypes of ionotropic glutamate receptors up to 100 microM. On the other hand, nefopam was effective against NMDA, QA and KA induced clonic seizures in mice. Nefopam displaced 3H-batrachotoxinin and inhibited the uptake of 22Na in the micromolar range and it protected mice against electroshock induced seizures. Nefopam may block the VSSCs activity: consequently, at the presynaptic level, this effect led to a reduction of glutamate release and at the postsynaptic level, it led to a decrease of the neuronal excitability following activation of the glutamate receptors.

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.

Solution- and solid-state structures of N-desmethylnefopam hydrochloride, a metabolite of the analgesic drug.

The solid-state structure of (+/-)-N-desmethylnefopam hydrochloride (1), a metabolite of the analgesic drug, was determined by single-crystal X-ray diffraction analysis. Compound 1 gave crystalline prisms belonging to the orthorhombic Pcab space group, and at ambient temperature (293 K), a = 9.939(2), b = 14.479(1), c = 20.148(3) A, V = 2899.5(8) A3, Z = 8, R(F) = 0.045, and Rw(F) = 0.025. The benzoxazocine ring of crystalline 1 is twisted into the boat-flattened (chair) [BfC] conformation, the phenyl ring resides in a relatively sterically unhindered exo-type ring position, whereas the O atom and NCH2Ar occupy sterically hindered positions between "boat" and "chair" regions. Dissolution of BfC crystalline 1 in CD2Cl2 solvent affords a dynamic conformational equilibrium (involving the putative twist-chair-flattened (chair) conformer) as shown by line broadening and weighted time-averaged vicinal coupling constants [-OCH2CH2N- segment] in the 1H NMR spectrum. The solution-state weighted time-averaged 50(1) degrees O-CH2-CH2-N dihedral angle, calculated by the R-ratio method, shows that the BfC conformation is the major contributor to time-averaged structure.

Stereoisomer differentiation for the analgesic drug nefopam hydrochloride using modeling studies of serotonin uptake area.

Equatorial and axial N-methyl diastereomers of the analgesic drug nefopam hydrochloride were differentiated using a hypothetical model of the serotonin (5-hydroxytryptamine) uptake area. Both diastereomers were placed within the hypothetical model area to form van der Waals interactions involving the phenyl group of nefopam, but only in the case of the equatorial N-methyl epimer was the +N--H bond able to be oriented towards the proposed hydrogen-bonding site. A comparison of equatorial N-methyl nefopam hydrochloride enantiomers in the proposed two-site binding mode points to less severe nonbonding steric interactions for the (+)-(1S,5S)-enantiomer compared with the (-)-(1R,5R)-isomer.

Cytochrome P450 metabolic intermediate complex of nefopam.

NADPH-catalysed biotransformation of nefopam in liver microsomes obtained from phenobarbitone-pretreated rats leads to the formation of an inactive cytochrome P450 metabolic intermediate (MI) complex. This complex can be detected spectrophotometrically by an absorbance maximum at 459 nm. The extent of the in-vitro MI complexation of 33 microM nefopam, a cyclic analogue of orphenadrine, was almost equal to the extent of the in-vitro MI complexation of 33 microM tofenacine, the mono-N-demethylated metabolite of orphenadrine. The time course of the MI complexation of nefopam and studies with two of its major metabolites suggest an initial biotransformation, which has to occur before MI complexation can take place. Maximal MI complexation of nefopam occurred at approximately 25 microM, whereas the MI complexation could not be detected at 100 microM nefopam.

Nefopam: a review of its pharmacological properties and therapeutic efficacy.

Nefopam is a non-narcotic analgesic not structurally related to other analgesic drugs. It is effective by the oral and parenteral routes, and when appropriate dose ratios were compared in short term studies it was shown to produce analgesia comparable to that with the oral analgesics aspirin, dextropropoxyphene and pentazocine, as well as that with 'moderate' doses of parenteral morphine, pethidine and pentazocine. However, when 'higher' dose ratios were compared, morphine and pethidine were usually more effective than nefopam, possibly due to a 'ceiling effect' for analgesia which may occur with higher doses of nefopam, as with other simple analgesics. Although a few patients with chronic pain have received nefopam for several weeks, further studies are needed to clarify its continued effectiveness and safety when used over long periods. In most patients nefopam has been relatively well tolerated, the most frequent side effects being sweating, nausea and in some studies sedation.