Stereoselective Analysis of the Antiseizure Activity of Fenfluramine and Norfenfluramine in Mice: Is l-Norfenfluramine a Better Follow-Up Compound to Racemic-Fenfluramine?

The aim of this study was to investigate the comparative antiseizure activity of the l-enantiomers of d,l-fenfluramine and d,l-norfenfluramine and to evaluate the relationship between their concentration in plasma and brain and anticonvulsant activity. d,l-Fenfluramine, d,l-norfenfluramine and their individual enantiomers were evaluated in the mouse maximal electroshock seizure (MES) test. d,l-Fenfluramine, d,l-norfenfluramine and their individual l-enantiomers were also assessed in the DBA/2 mouse audiogenic seizure model. All compounds were administered intraperitoneally. Brain and plasma concentrations of the test compounds in DBA/2 mice were quantified and correlated with anticonvulsant activity. In the MES test, fenfluramine, norfenfluramine and their enantiomers showed comparable anticonvulsant activity, with ED50 values between 5.1 and 14.8 mg/kg. In the audiogenic seizure model, l-norfenfluramine was 9 times more potent than d,l-fenfluramine and 15 times more potent than l-fenfluramine based on ED50 (1.2 vs. 10.2 and 17.7 mg/kg, respectively). Brain concentrations of all compounds were about 20-fold higher than in plasma. Based on brain EC50 values, l-norfenfluramine was 7 times more potent than d,l-fenfluramine and 13 times more potent than l-fenfluramine (1940 vs. 13,200 and 25,400 ng/g, respectively). EC50 values for metabolically formed d,l-norfenfluramine and l-norfenfluramine were similar to brain EC50 values of the same compounds administered as such, suggesting that, in the audiogenic seizure model, the metabolites were responsible for the antiseizure activity of the parent compounds. Because of the evidence linking d-norfenfluramine to d,l-fenfluramine to cardiovascular and metabolic adverse effects, their l-enantiomers could potentially be safer follow-up compounds to d,l-fenfluramine. We found that, in the models tested, the activity of l-fenfluramine and l-norfenfluramine was comparable to that of the corresponding racemates. Based on the results in DBA/2 mice and other considerations, l-norfenfluramine appears to be a particularly attractive candidate for further evaluation as a novel, enantiomerically pure antiseizure medication.

Comparative activity of the enantiomers of fenfluramine and norfenfluramine in rodent seizure models, and relationship with their concentrations in plasma and brain.

OBJECTIVES: To investigate the comparative antiseizure activity of the individual enantiomers of fenfluramine and its major active primary metabolite norfenfluramine in rodent seizure models, and its relationship with the pharmacokinetics of these compounds in plasma and brain. METHODS: The antiseizure potency of d,l-fenfluramine (racemic fenfluramine) was compared with the respective potencies of its individual enantiomers and the individual enantiomers of norfenfluramine using the maximal electroshock (MES) test in rats and mice, and the 6-Hz 44 mA test in mice. Minimal motor impairment was assessed simultaneously. The time course of seizure protection in rats was compared with the concentration profiles of d-fenfluramine, l-fenfluramine, and their primary active metabolites in plasma and brain. RESULTS: All compounds tested were active against MES-induced seizures in rats and mice after acute (single-dose) administration, but no activity against 6-Hz seizures was found even at doses up to 30 mg/kg. Estimates of median effective doses (ED50 ) in the rat-MES test were obtained for all compounds except for d-norfenfluramine, which caused dose-limiting neurotoxicity. Racemic fenfluramine had approximately the same antiseizure potency as its individual enantiomers. Both d- and l-fenfluramine were absorbed and distributed rapidly to the brain, suggesting that seizure protection at early time points (≤2 h) was related mainly to the parent compound. Concentrations of all enantiomers in brain tissue were >15-fold higher than those in plasma. SIGNIFICANCE: Although there are differences in antiseizure activity and pharmacokinetics among the enantiomers of fenfluramine and norfenfluramine, all compounds tested are effective in protecting against MES-induced seizures in rodents. In light of the evidence linking the d-enantiomers to cardiovascular and metabolic adverse effects, these data suggest that l-fenfluramine and l-norfenfluramine are potentially attractive candidates for a chiral switch approach leading to development of a novel, enantiomerically-pure antiseizure medication.

Efficacy of Fenfluramine and Norfenfluramine Enantiomers and Various Antiepileptic Drugs in a Zebrafish Model of Dravet Syndrome.

Dravet syndrome (DS) is a rare genetic encephalopathy that is characterized by severe seizures and highly resistant to commonly used antiepileptic drugs (AEDs). In 2020, FDA has approved fenfluramine (FFA) for treatment of seizures associated with DS. However, the clinically used FFA is a racemic mixture (i.e. (±)-FFA), that is substantially metabolized to norfenfluramine (norFFA), and it is presently not known whether the efficacy of FFA is due to a single enantiomer of FFA, or to both, and whether the norFFA enantiomers also contribute significantly. In this study, the antiepileptic activity of enantiomers of FFA (i.e. (+)-FFA and (-)-FFA) and norFFA (i.e. (+)-norFFA and (-)-norFFA) was explored using the zebrafish scn1Lab-/- mutant model of DS. To validate the experimental conditions used, we assessed the activity of various AEDs typically used in the fight against DS, including combination therapy. Overall, our results are highly consistent with the treatment algorithm proposed by the updated current practice in the clinical management of DS. Our results show that (+)-FFA, (-)-FFA and (+)-norFFA displayed significant antiepileptic effects in the preclinical model, and thus can be considered as compounds actively contributing to the clinical efficacy of FFA. In case of (-)-norFFA, the results were less conclusive. We also investigated the uptake kinetics of the enantiomers of FFA and norFFA in larval zebrafish heads. The data show that the total uptake of each compound increased in a time-dependent fashion. A somewhat similar uptake was observed for the (+)-norFFA and (-)-norFFA, implying that the levo/dextrotation of the structure did not dramatically affect the uptake. Significantly, when comparing (+)-FFA with the less lipophilic (+)-norFFA, the data clearly show that the nor-metabolite of FFA is taken up less than the parent compound.

Adverse effects of benfluorex on heart valves and pulmonary circulation.

Benfluorex is responsible for the development of restrictive valvular regurgitation due to one of its metabolites, norfenfluramine. The 5-HT2B receptor, expressed on heart valves, acts as culprit receptor for drug-induced valvular heart disease (VHD). Stimulation of this receptor leads to the upregulation of target genes involved in the proliferation and stimulation of valvular interstitial cells through different intracellular pathways. Valve lesions essentially involve the mitral and/or aortic valves. The randomised prospective REGULATE trial shows a threefold increase in the incidence of valvular regurgitation in patients exposed to benfluorex. A cross-sectional trial shows that about 7% of patients without a history of VHD previously exposed to benfluorex present echocardiographic features of drug-induced VHD. The excess risks of hospitalisation for cardiac valvular insufficiency and of valvular replacement surgery were respectively estimated to 0.5 per 1000 and 0.2 per 1000 exposed patients per year. Recent data strongly suggest an aetiological link between benfluorex exposure and pulmonary arterial hypertension (PAH). The PAH development may be explained by serotonin, which creates a pulmonary vasoconstriction through potassium-channel blockade. Further studies should be conducted to determine the subsequent course of benfluorex-induced VHD and PAH, and to identify genetic, biological and clinical factors that determine individual susceptibility to developing such adverse effects.

Structural basis for molecular recognition at serotonin receptors.

Serotonin or 5-hydroxytryptamine (5-HT) regulates a wide spectrum of human physiology through the 5-HT receptor family. We report the crystal structures of the human 5-HT1B G protein-coupled receptor bound to the agonist antimigraine medications ergotamine and dihydroergotamine. The structures reveal similar binding modes for these ligands, which occupy the orthosteric pocket and an extended binding pocket close to the extracellular loops. The orthosteric pocket is formed by residues conserved in the 5-HT receptor family, clarifying the family-wide agonist activity of 5-HT. Compared with the structure of the 5-HT2B receptor, the 5-HT1B receptor displays a 3 angstrom outward shift at the extracellular end of helix V, resulting in a more open extended pocket that explains subtype selectivity. Together with docking and mutagenesis studies, these structures provide a comprehensive structural basis for understanding receptor-ligand interactions and designing subtype-selective serotonergic drugs.

Appetite suppressants, cardiac valve disease and combination pharmacotherapy.

The prevalence of obesity in the United States is a major health problem associated with significant morbidity, mortality, and economic burden. Although obesity and drug addiction are typically considered distinct clinical entities, both diseases involve dysregulation of biogenic amine neuron systems in the brain. Thus, research efforts to develop medications for treating drug addiction can contribute insights into the pharmacotherapy for obesity. Here, we review the neurochemical mechanisms of selected stimulant medications used in the treatment of obesity and issues related to fenfluramine-associated cardiac valvulopathy. In particular, we discuss the evidence that cardiac valve disease involves activation of mitogenic serotonin 2B (5-HT2B) receptors by norfenfluramine, the major metabolite of fenfluramine. Advances in medication discovery suggest that novel molecular entities that target 2 different neurochemical mechanisms, that is, "combination pharmacotherapy," will yield efficacious antiobesity medications with reduced adverse side effects.

Molecular determinants for the interaction of the valvulopathic anorexigen norfenfluramine with the 5-HT2B receptor.

S-(+)-Norfenfluramine (SNF)-an active metabolite of the now-banned anorexigen fenfluramine-has been implicated in the drug's appetite-suppressing actions and its life-threatening cardiovascular side effects. SNF reduces appetite through serotonin 5-HT(2C) receptor activation; it causes cardiopulmonary side effects through 5-HT(2B) receptor activation. Thus, we attempted to identify molecular determinants of SNF binding to 5-HT(2B) receptors distinct from those underlying SNF-5-HT(2C/2A) receptor interactions. Mutagenesis implicated Val2.53 in SNF binding to 5-HT(2B) receptors. Ligand docking simulations suggested both Val2.53 gamma-methyl groups form stabilizing van der Waals' (vdW) interactions with the alpha-methyl group of SNF. A V2.53L mutation induced a 17-fold decrease in affinity; molecular dynamics (MD) simulations suggested that this decrease resulted from the loss of one 2.53-alpha-methyl group vdW interaction. Supporting this, 1) the binding of norfenfluramine (NF) analogs lacking an S-(+) alpha-methyl group (RNF and alpha-desmethyl-NF) was less sensitive to the V2.53L mutation, and 2) a V2.53A mutation decreased SNF affinity 190-fold, but decreased RNF and alpha-desmethyl-NF affinities only 16- and 45-fold, respectively. We next addressed whether the alpha-methyl group of SNF contributes to 5-HT(2C/2A) receptor affinity. Removal of the alpha-methyl group (RNF and alpha-desmethyl-NF), which reduced 5-HT(2B) receptor binding 3-fold, did not affect 5-HT(2C/2A) receptor binding. An alpha-ethyl substituent (alpha-ethyl-NF), which decreased 5-HT(2B) receptor affinity 46-fold, reduced 5-HT(2C) and 5-HT(2A) receptor binding by 14- and 5-fold, respectively. Finally, we determined that residue 2.53 affects SNF potency and efficacy at 5-HT(2B) receptors but not at 5-HT(2C) and 5-HT(2A) receptors. In conclusion, vdW interactions between residue 2.53 and the alpha-methyl group of SNF contribute to the ligand's 5-HT(2) receptor subtype-selective pharmacology.

Saccadic peak velocity and EEG as end-points for a serotonergic challenge test.

UNLABELLED: We previously reported that a single dose of the serotonin receptor agonist meta-chlorophenylpiperazine increased the peak velocity of saccadic eye movements and decreased low-frequency electroencephalographic activity. METHODS: We administered a single dose of the serotonin releaser dexfenfluramine in a double blind, placebo controlled randomised cross-over design and measured saccadic eye movements and EEG every hour up to 6 h. Subjects were 62 males (18-30 years) with a history of no, moderate or heavy use of ecstasy tablets. RESULTS: Dexfenfluramine increased saccadic peak velocity and decreased alpha, delta and theta electroencephalographic activity, the latter predominantly in heavy users of ecstasy. CONCLUSIONS: This study supports the idea that saccadic peak velocity and EEG can be useful endpoints of a serotonergic challenge. This could be an important anatomical extension of these end-points, which until now were limited to the effect on hypothalamic serotonergic projections.

Fenfluramine and norfenfluramine levels in brain microdialysate, brain tissue and plasma of rats administered doses of d-fenfluramine known to deplete 5-hydroxytryptamine levels in brain.

The relationship between dose, frontal cortex (brain) microdialysate and brain tissue levels of fenfluramine (FEN) and norfenfluramine (NF), as well as the effect that these levels have on body temperature, was determined after systemic d-FEN. FEN and NF levels were monitored continuously in the microdialysate of adult male Sprague-Dawley rats dosed with 3 x 5 mg/kg s.c. (spaced 2 hr apart), 1 x 2 mg/kg s.c. or 1 x 10 mg/kg i.p. d-FEN (at ambient temperatures of either 23 degrees C or 27 degrees C). Drug concentrations in plasma and brain regions were also determined 1 hr after one or three doses of 5 mg/kg of d-FEN and 1 and 8 hr after 10 mg/kg d-FEN, and the levels of 5-hydroxytryptamine and 5-hydroxyindole acetic acid in the frontal cortex of FEN and controls were determined 4 days after dosing. Peak microdialysate FEN levels, occurring between 40 and 60 min after the first dose, were 0.24 +/- 0.07 microM after 2 mg/kg, 0.33 +/- 0.04 microM after 5 mg/kg and 1.65 microM after 10 mg/kg. After multiple doses of 5 mg/kg FEN the time-to-peak level was greater than 80 min with peaks of 0.68 +/- 0.04 microM after the second dose and 1.20 +/- 0.07 microM after the third dose. There was a positive correlation between combined (FEN + NF) peak levels in microdialysate and the increase in body temperature after 10 mg/kg d-FEN at 27 degrees C; however, the group mean and peak levels of FEN and NF in microdialysate were statistically the same at either 23 degrees C or 27 degrees C. The indole-depleting effect of d-FEN at 4 days after dosing was exacerbated at 27 degrees C when hyperthermia occurred. Thus, hyperthermia does not affect the pharmacokinetics of d-FEN but pharmacokinetics can influence the degree of hyperthermia in a 27 degrees C environment. Plasma levels, brain extracellular and brain levels of approximately 1 microM, 2.5 microM and 50 microM FEN (respectively), or greater, result from 5-hydroxytryptamine-depleting doses of 5 mg/kg s.c. FEN.

Determination of D-fenfluramine, D-norfenfluramine and fluoxetine in plasma, brain tissue and brain microdialysate using high-performance liquid chromatography after precolumn derivatization with dansyl chloride.

A HPLC method is described for the simultaneous determination of D-fenfluramine (FEN), D-norfenfluramine (NF) and fluoxetine (FLX) using fluorometric detection after precolumn derivatization with dansyl-chloride. The method has limits of quantitation of 200 fmol for FEN and NF, 500 fmol for FLX in brain microdialysate, and 1 pmol for NF and FEN, and 2 pmol for FLX in plasma. Brain tissue standards were linear between 5 and 200 pmol/mg for all three compounds. The inter-assay variability (relative standard deviation) was 6.6%, 6.9% and 9.3% for FEN, 4.6%, 3.7% and 7.9% for NF and 10.4%, 4.9% and 12.2% for FLX, for brain microdialysate (2 pmol/microl), plasma (2 pmol/ microl) and brain tissue (50 pmol/mg), respectively. Intra-assay variability was always lower, typically several times lower than inter-assay variability. Extraction recovery was 108% and 48% for FEN, 105% and 78% for NF and 94% and 45% for FLX, in plasma (2 pmol/microl) and brain tissue (5 pmol/mg), respectively. Due to the stability of the dansyl-chloride derivatives this method is well suited for an autoinjector after manual derivatization with dansyl chloride at room temperature for 4 h.

The effect of fenfluramine dosage regimen and reduced food intake on levels of 5-HT in rat brain.

Male Wistar rats received fenfluramine in subacute (5 mg/kg b.i.d. i.p. for 4 days) or escalating (0.5, 1, 1.5, 2, 3, 4 and 5 mg/kg b.i.d. i.p., each dose given for 4 days) doses. Saline-treated controls received food ad libitum, or were pair-fed with the fenfluramine-treated animals. Rats were killed 1, 15 and 30 days after drug withdrawal. On day 1, plasma and brain fenfluramine levels were higher, and hypothalamus norfenfluramine levels were lower following escalating compared to subacute dosing, although total active drug levels were unaltered. Both treatment regimes, and pair-feeding reduced food intake and body weight. Subacute fenfluramine reduced brain 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) levels for up to 30 days. Brain 5-HT and 5-HIAA levels were unaltered following escalating-doses of fenfluramine. Additionally, pair-feeding transiently decreased hippocampal 5-HT levels. These data suggest that escalating-doses of fenfluramine prevent the 5-HT-depleting effect of a sub-cute challenge without altering the anorexic action of the drug.

Effect of escalating doses of d-fenfluramine on the content of indoles in brain.

The neurochemical effects of a large dose challenge (5 mg/kg, i.p.) of d-fenfluramine (d-F) in rats, given saline or gradually escalating doses of d-F (0.1-2.5 mg/kg, i.p.), were examined with regard to regional sensitivity and the time-course of recovery. The indole-depleting effect after the large dose of d-F to saline-pretreated animals appeared to differ, depending on the areas of brain considered (cortex greater than hippocampus greater than striatum), despite the fact that the drug and its main metabolite, d-norfenfluramine (d-NF) distributed almost uniformly in the regions of brain examined. The depletion in all these regions of the brain was reversible within 6 weeks, serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) being back to control levels in the hippocampus and striatum but not 5-HT in the cortex. However, when rats were exposed to gradually escalating doses of d-F the recovery of indoles in the brain, after injection of the large dose challenge, appeared to be faster. Indoles were markedly less reduced 1 week later in the cortex, hippocampus and striatum, with content of indole in the striatum showing complete recovery and the long-term depletion of 5-HT and 5-HIAA, by the subsequent large dose challenge was almost completely reversed in all regions. Analysis of the concentrations of d-F and its main metabolite d-fenfluramine (d-NF) in brain excluded any pharmacokinetic tolerance. These results suggest that during therapeutic treatment with d-F, the use of escalating doses may attenuate the potential for the long-lasting decrease of 5-HT in brain.

Single- and multiple-dose kinetics of d-fenfluramine in rats given anorectic and toxic doses.

1. High parenteral doses of a twice-daily schedule of d,l-fenfluramine (d,l-F) may cause long-lasting decrease of functional indices of brain serotoninergic neurones in rats. The single- and multiple-dose (b.i.d. x 4 days) kinetics of low (1.25 mg/kg) and high (12.5 mg/kg) subcutaneous (s.c.) doses of d-F, which accounts of the anorectic effects of the racemate, and its deethylated metabolite d-norfenfluramine (d-NF), were therefore examined and compared with those of pharmacologically effective oral doses (0.3-1.25 mg/kg) in rats. 2. There were dose-dependent alterations of kinetic parameters after s.c. and oral dosing, indicating that hepatic clearance of d-F in the rat can be saturated either by increasing the size of the single dose or during repeated dosing. Nonlinearity was also observed for d-NF. Consequently at high doses exposure of rat to the drug, as measured by the sum of area under the plasma concentration-time curve (AUC) of d-F and d-NF considerably exceeded that expected from simple dosage considerations, particularly with repeated administration of d-F. 3. Total exposure at the high doses considerably exceeded that at pharmacological doses, however, indicating an ample margin in favour of anorectic activity. The possibility that the long-term depletion of brain 5-HT by d-F and/or its metabolite d-NF may have relevance at the usual therapeutic dose, is discussed.

Comparative studies on the anorectic activity of d-fenfluramine in mice, rats, and guinea pigs.

The present study compares the anorectic activity of d-fenfluramine and its metabolite d-norfenfluramine in three animal species. d-Fenfluramine and d-norfenfluramine show anorectic activity at increasing doses (ED50) in rats, guinea pigs, and mice, d-norfenfluramine being more active than d-fenfluramine in all three species. Equiactive anorectic activities are reached with different brain levels of d-fenfluramine and d-norfenfluramine, guinea pigs being the most sensitive species, followed by rats then mice. The metabolite most probably plays a major role in the anorectic effect of d-fenfluramine in guinea pigs, contributes to the anorectic activity in rats, but adds little to the action of the parent drug in mice. The different sensitivity to d-fenfluramine and d-norfenfluramine in these three species does not appear to be explained by a number of biochemical parameters, including serotonin uptake or release, receptor subtypes, or 3H-d-fenfluramine binding and uptake.

Interactions of iprindole with fenfluramine metabolism in rat brain and liver.

An assay procedure utilizing electron-capture gas chromatography was developed for simultaneous analysis of fenfluramine and norfenfluramine. This method was applied to brain and liver samples from rats which had been injected with fenfluramine with or without pretreatment with iprindole. The tissues from rats treated with fenfluramine showed extensive formation of norfenfluramine, consistent with findings reported previously in the literature. Pretreatment with iprindole led to an increase in brain and liver levels of fenfluramine, and, unexpectedly, to a marked decrease in levels of norfenfluramine in these tissues. These findings suggest that iprindole blocks N-deethylation and that it may be a useful tool with which to study the effects of fenfluramine in the absence of norfenfluramine. The results also emphasize the importance of considering drug-drug interactions in future research on fenfluramine.

Effects of intracerebroventricular administration of d-fenfluramine and d-norfenfluramine, as a single injection or 2-hr infusion, on serotonin in brain: relationship to concentrations of drugs in brain.

The effects of d-fenfluramine (DF) and d-norfenfluramine (DNF), administered intracerebroventricularly (i.c.v.) on levels of serotonin (5-HT) in the brain, was assessed in relation to levels of drugs in brain. d-Fenfluramine, as a single injection (500 micrograms/20 microliters), caused no significant changes in 5-HT in whole brain from 15 to 480 min after injection. When infused intraventricularly for 2 hr, DF and DNF at 500 but not at 125 250 micrograms/hr, markedly reduced concentrations of 5-HT in brain 4 hr after the end of the infusion. At this time levels of DNF in brain were similar (between 4 and 5 micrograms/g) with both compounds, whereas levels of DNF after single intraventricular injections of DF were below 2 micrograms/g at all times after injection. Infusion of 500 micrograms/hr of DNF for 2-hr reduced concentrations of 5-HT in various regions of the brain, with the exception of the brainstem, whereas 250 micrograms/hr of DNF significantly lowered levels of 5-HT only in the cortex. The effect of infusion of 500 micrograms/hr of DNF was specific for 5-HT (no effect on dopamine and norepinephrine) and lasted for at least 168 hr. The results suggest that the effect on 5-HT in brain of intraventricular infusion of DF, but not a single injection, was due to the fact that, only in the former condition were adequate levels of DNF, the active metabolite of DF, reached in the brain. These results are relevant to the interpretation of studies in which biochemical changes in the brain after intraventricular administration, are reported without any measurement of the drug or its active metabolites, in plasma and brain.

Evidence that central 5-HT2 receptors do not play an important role in the anorectic activity of D-fenfluramine in the rat.

To gain information on the role of central 5-HT2 receptors in the reduction of food intake caused by D-fenfluramine in rats, different intraperitoneal doses of metergoline, a non-selective 5-HT receptor antagonist and ritanserin, a selective 5-HT2 receptor antagonist, were compared for their ability (a) to antagonize the anorectic effect of D-fenfluramine; (b) to occupy central 5-HT2 receptors in vivo (measured by the binding of [3H]spiperone in the frontal cortex) and (c) to affect the concentrations of D-fenfluramine and its active metabolite, D-norfenfluramine in brain. Metergoline dose-dependently reduced the effect of D-fenfluramine (2.5 mg/kg i.p.) on food intake, with complete antagonism at 1 mg/kg, a dose which occupies about 50% of cortical 5-HT2 receptors. Ritanserin, at a dose (0.5 mg/kg) causing 50% occupation of 5-HT2 receptors, had no effect on anorexia induced by D-fenfluramine and only partially prevented it at doses which caused maximum occupation of 5-HT2 receptors (1-2 mg/kg). Unlike 1 mg/kg metergoline, 1 mg/kg ritanserin significantly reduced the concentrations of D-norfenfluramine in the frontal cortex and hypothalamus of rats 30 min after injection of D-fenfluramine. The results suggest that 5-HT receptors, other than 5-HT2, possibly 5-HT1B, are involved in the anorectic effect of D-fenfluramine in food-deprived rats.

Enantioselective gas chromatographic assay with electron-capture detection for dl-fenfluramine and dl-norfenfluramine in plasma.

An enantioselective gas chromatographic assay utilising electron-capture detection has been developed for the simultaneous quantitation of enantiomers of fenfluramine and nonfenfluramine in plasma. The assay involves the conversion of the enantiomers of both fenfluramine and norfenfluramine into their corresponding diastereomeric amide derivatives by an acylation reaction with n-heptafluorobutyryl-S-prolyl chloride under Schotten-Baumann conditions prior to gas chromatographic separation on an achiral polar OV-225 capillary column. Linear and reproducible standard curves were obtained over the concentration ranges 4.30-86.3 ng/ml per enantiomer and 1.25-42.25 ng/ml per enantiomer for the enantiomers of fenfluramine and norfenfluramine, respectively. The method was applied to a single-dose pharmacokinetic study in a healthy adult subject. Stereoselective differences were observed in the plasma concentration versus time profiles of the enantiomers of both fenfluramine and norfenfluramine. The area under the plasma concentration versus time curve values obtained for the l-isomers of fenfluramine or norfenfluramine were higher than the values of their corresponding d-antipodes.

Metabolism of fenfluramine to norfenfluramine in guinea-pigs.

After injection of fenfluramine into guinea-pigs, the N-dealkylated metabolite norfenfluramine was present in brain at higher concentrations and persisted longer than the parent drug, fenfluramine. Contrary to a claim in previous literature, the guinea-pig does metabolize fenfluramine to norfenfluramine, hence the ability of fenfluramine to cause acute and long-term depletion of brain 5-hydroxytryptamine in this species does not prove that fenfluramine, instead of nonfenfluramine, can produce these effects.