Pharmacokinetics of d- and l-norfenfluramine following their administration as individual enantiomers in rats.

The effect of fenfluramine and norfenfluramine enantiomers in rodent seizure models and their correlation with the pharmacokinetics of d- and l-fenfluramine in rats have been reported recently. To complement these findings, we investigated the pharmacokinetics of d- and l- norfenfluramine in rat plasma and brain. Sprague-Dawley rats were injected intraperitoneally with 20 mg/kg and 1 mg/kg l- norfenfluramine. A 1 mg/kg dose of d-norfenfluramine was used because higher doses caused severe toxicity. The concentration of each enantiomer in plasma and brain was determined at different time points by liquid chromatography/mass spectrometry. Pharmacokinetic parameters were compared between norfenfluramine enantiomers, and with those reported previously for fenfluramine enantiomers after a 20 mg/kg, i.p., dose. All enantiomers were absorbed rapidly and eliminated, with half-lives ranging from 0.9 h (l-fenfluramine) to 6.1 h (l- norfenfluramine, 20 mg/kg) in plasma, and from 3.6 h (d-fenfluramine) to 8.0 h (l-fenfluramine) in brain. Brain-to-plasma concentration ratios ranged from 15.4 (d-fenfluramine) to 27.6 (d-norfenfluramine), indicating extensive brain penetration. The fraction of d- and l-fenfluramine metabolized to norfenfluramine was estimated to be close to unity. This work is part of ongoing investigations to determine the potential value of developing enantiomerically pure l-fenfluramine or l-norfenfluramine as follow-up compounds to the marketed racemic fenfluramine.

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.

[Benfluorex and valvular heart disease]. / Benfluorex (Mediator®) et atteintes valvulaires.

Benfluorex is responsible of restrictive organic valvular regurgitations via one of its metabolites, the norfenfluramine. It has been withdrawn from the european market in June 2010. In France, about five millions of people have been exposed to benfluorex since its market launch in 1976. At the time of its market withdrawn, over 300,000 patients in France were taking the drug. Aortic and mitral valves are the most frequent involved. The prevalence of this type of valve damage is not yet known with accuracy. Severe regurgitations appear to be rare (less than one case per thousand exposed patients-year).

Evidence for possible involvement of 5-HT(2B) receptors in the cardiac valvulopathy associated with fenfluramine and other serotonergic medications.

BACKGROUND: Serotonergic medications with various mechanisms of action are used to treat psychiatric disorders and are being investigated as treatments for drug dependence. The occurrence of fenfluramine-associated valvular heart disease (VHD) has raised concerns that other serotonergic medications might also increase the risk of developing VHD. We hypothesized that fenfluramine or its metabolite norfenfluramine and other medications known to produce VHD have preferentially high affinities for a particular serotonin receptor subtype capable of stimulating mitogenesis. METHODS AND RESULTS: Medications known or suspected to cause VHD (positive controls) and medications not associated with VHD (negative controls) were screened for activity at 11 cloned serotonin receptor subtypes by use of ligand-binding methods and functional assays. The positive control drugs were (+/-)-fenfluramine; (+)-fenfluramine; (-)-fenfluramine; its metabolites (+/-)-norfenfluramine, (+)-norfenfluramine, and (-)-norfenfluramine; ergotamine; and methysergide and its metabolite methylergonovine. The negative control drugs were phentermine, fluoxetine, its metabolite norfluoxetine, and trazodone and its active metabolite m-chlorophenylpiperazine. (+/-)-, (+)-, and (-)-Norfenfluramine, ergotamine, and methylergonovine all had preferentially high affinities for the cloned human serotonin 5-HT(2B) receptor and were partial to full agonists at the 5-HT(2B) receptor. CONCLUSIONS: Our data imply that activation of 5-HT(2B) receptors is necessary to produce VHD and that serotonergic medications that do not activate 5-HT(2B) receptors are unlikely to produce VHD. We suggest that all clinically available medications with serotonergic activity and their active metabolites be screened for agonist activity at 5-HT(2B) receptors and that clinicians should consider suspending their use of medications with significant activity at 5-HT(2B) receptors.

The effect of D-fenfluramine on brain 5-hydroxytryptamine and 5-hydroxyindoleacetic acid in male and female rats.

Brain regional 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) concentrations were determined in freely feeding male and female rats 7 days after giving a single dose of D-fenfluramine (3.8 mg/kg, p.o.) or vehicle. Males showed negligible effects except for a significant decrease of 5-HT in the rest of the cortex, whereas females showed significant decreases of 5-HT and 5-HIAA in the frontal cortex, the rest of the cortex, hippocampus and hypothalamus; 5-HT was also decreased in female midbrain. Females had substantially higher plasma and brain concentrations of fenfluramine and moderately but significantly lower concentrations of norfenfluramine than the males. Plasma fenfluramine + norfenfluramine concentrations of the females were significantly higher than those of the males. Corresponding brain values showed smaller but significant differences. Female brain and plasma areas under the curve for fenfluramine + norfenfluramine (0-24 h after administration of D-fenfluramine) were 20 and 35% higher than male values. However, results suggest that the sex difference in the effect of D-fenfluramine on brain 5-HT metabolism is not due to differences in the metabolism of the drug.

Oral kinetics of dexfenfluramine and dexnorfenfluramine in non-human primates.

1. Large doses of dexfenfluramine in animals cause a decrease of serotoninergic markers but none of the species so far investigated shows sufficient kinetic and metabolic similarity with man to be a valid model for safety studies. The plasma kinetics of dexfenfluramine and its active metabolite dexnorfenfluramine were therefore studied in baboon, rhesus and cynomolgus monkeys given dexfenfluramine hydrochloride orally (2 mg/kg) in order to investigate whether any of these primates have a biodisposition particularly similar to man. 2. The drug was rapidly N-deethylated to dexnorfenfluramine achieving comparatively low mean maximum plasma levels (Cmax) of 12-14 ng/ml in all primates, and rapidly disappeared thereafter with half-lives (t1/2) ranging from 2 to 3 h in the baboon and rhesus monkey to 6 h in the cynomolgus monkey. Its normetabolite reached higher mean Cmax (52-97 ng/ml) and the t1/2's were longer, varying from about 11 h in the rhesus monkey to 22 h in the cynomolgus monkey. The metabolite-to-parent drug ratio (14-37), in terms of plasma area under curve (AUC), greatly exceeded that in man (< 1), being higher than in all species investigated so far. 3. Comparative repeat dose simulation in monkey and man indicated that the dosage in primates would need to be increased 10-fold to achieve comparable dexfenfluramine steady-state plasma Cmax, producing nor-metabolite levels several times those in man, whilst for comparable metabolite Cmax, those of the parent drug would be correspondingly too low. 4. In view of the different mechanism of action of dexfenfluramine and dexnorfenfluramine within the serotoninergic system none of these primates is therefore a suitable model for safety assessment in terms of exposure of the active moieties in comparison with man.

Anorectic effect and brain concentrations of D-fenfluramine in the marmoset: relationship to the in vivo and in vitro effects on serotonergic mechanisms.

The present study investigated the anorectic activity of d-fenfluramine (d-F) and the relationship with brain levels of unchanged drug and its metabolite d-norfenfluramine (d-NF) in marmosets, relating them to neurochemical effects on the serotoninergic system. d-F and d-NF were equally active in reducing food intake (ED50 about 3 mg/kg, p.o.). However, the brain concentrations of the metabolite required to reduce food intake after synthetic d-NF were more than twice those after d-F, indicating that d-NF contributes to but does not completely explain the anorectic effect of d-F. At this dose d-F did not appreciably modify the serotonin (5-HT) and 5-hydroxyindoleacetic (5-HIAA) contents of the brain regions examined, except for a slight enhancement of 5-HIAA in hippocampus. In vitro in brain cortical synaptosomes d-F inhibited [3H]5-HT uptake more potently than d-NF, as in other species. d-F and d-NF showed similar potency in stimulating [3H]5-HT release, in a Ca++ dependent manner. The tritium released by d-F and d-NF appeared to be mainly unmetabolized [3H]5-HT. Like in other species the marmoset too has saturable and specific [3H]d-F binding sites, for which d-NF has lower affinity. d-F and d-NF have low affinities for 5-HT receptor subtypes, except that d-NF has appreciable affinity for 5-HT1C and 5-HT1D receptors. Unlike in rodents but similarly to primates in the striatum the pharmacology of 5-HT receptors seems to correspond to the 5-HT1D subtype.(ABSTRACT TRUNCATED AT 250 WORDS)

Hormone responses to fenfluramine and placebo challenge in endogenous depression.

Plasma prolactin and cortisol levels after oral administration of d-l fenfluramine hydrochloride (60 mg) and placebo were examined in 24 endogenously depressed patients and 21 age- and sex-matched normal control subjects in a randomized, double-blind study. Prolactin levels were significantly increased by fenfluramine in both groups, but the response was significantly blunted in the depressed patients compared with the controls. This effect was partially dependent upon elevated baseline cortisol levels in the depressed group and was also influenced by a history of weight loss. Plasma cortisol levels were not increased by fenfluramine in either group. These findings confirm previous reports and suggest that patients with endogenous major depression are characterized by central serotonergic hyporesponsivity. The need to account for baseline effects on hormonal responses to putative serotonergic agents is supported by the findings; however, these effects appear to be less striking when endogenicity is a prominent clinical feature of the depressive syndrome. The apparently complex influence of weight loss on prolactin response to serotonergic challenge remains to be clarified as well as the role played by the bioavailability of the challenge drug and its metabolite.

Comparison of the effects of repeated oral versus subcutaneous fenfluramine administration on rat brain monoamine neurons: pharmacokinetic and dose-response data.

The importance of the route of drug administration (oral vs. subcutaneous) on the neurochemical effects and pharmacokinetics of repeated d,1-fenfluramine administration in rats (1-24 mg/kg b.i.d., i.e., 2-48 mg/kg/day for 4 days) was examined. Overall, comparable dose-dependent alterations in brain monoamine markers were observed following repeated oral (PO) and subcutaneous (SC) administration of fenfluramine. Doses of 1 and 2 mg/kg fenfluramine were without significant effects on the density of 3H-paroxetine-labeled serotonin (5-HT) uptake sites. Higher doses of fenfluramine (4, 12 and 24 mg/kg) produced dose-dependent decreases in 5-HT, 5-hydroxyindoleacetic acid and 5-HT uptake sites with maximal decreases (80-90%) occurring at the 12 mg/kg dose. Fenfluramine administration produced dose-dependent and biphasic effects on brain dopamine markers with increases in homovanillic acid (HVA) observed at 2 hours, whereas decreases in the levels of dopamine, HVA and dihydroxyphenylacetic acid were evident at 18 hours posttreatment. Norepinephrine levels were only decreased at the highest dose of fenfluramine. Significantly higher levels of brain fenfluramine were observed following SC than following PO administration of the drug. On the other hand, comparable levels of its active metabolite norfenfluramine were present in the brain following the two routes of fenfluramine administration. These data suggest the importance of norfenfluramine levels in the brain in determining the high-dose neurotoxic effects of fenfluramine on brain 5-HT neurons in rats.

Effects of repeated fenfluramine administration on indices of monoamine function in rat brain: pharmacokinetic, dose response, regional specificity and time course data.

The pharmacokinetics and neurochemical effects of repeated fenfluramine administration in rats (1-24 mg/kg s.c., b.i.d. for 4 days) were examined with respect to dose dependence, regional specificity and time course of recovery. Fenfluramine administration resulted in parallel increases in plasma and brain concentrations of the drug and its metabolite, norfenfluramine, which were dose-related but nonlinear. Doses of 1 and 2 mg/kg fenfluramine increased brain serotonin (5-HT) and 5-hydroxyindoleacetic acid with no significant effects on 5-HT uptake sites. Higher doses of fenfluramine (4-24 mg/kg) reduced all three brain 5-HT markers with maximal decreases (80%-90%) occurring at 12 mg/kg. High-dose (24 mg/kg) fenfluramine administration led to larger decreases in 5-HT markers in neocortex, striatum and hippocampus than in hypothalamus, brain stem and spinal cord. Following 80% to 90% reductions of the 5-HT markers in neocortex and hippocampus at 18 hr after drug treatment, 5-HT and 5-hydroxyindoleacetic acid returned to control levels by 4 and 16 weeks, respectively, but 5-HT uptake sites initially recovered more slowly, with a 25% reduction still evident at 8 months. At this time 5-HT and 5-hydroxyindoleacetic acid were again reduced. Fenfluramine administration produced dose-dependent and biphasic effects on brain dopamine markers. Increases in homovanillic acid levels were apparent at 2 hr, whereas decreases in the levels of dopamine, homovanillic acid and dihydroxyphenylacetic acid were evident at 18 hr post-treatment. Norepinephrine levels were only decreased by doses of fenfluramine greater than or equal to 4 mg/kg. Fenfluramine administration did not cause long-term alterations in dopamine or norepinephrine uptake sites.(ABSTRACT TRUNCATED AT 250 WORDS)

The measurement of d-fenfluramine and its metabolite, d-norfenfluramine in plasma and urine with an application of the method to pharmacokinetic studies.

1. A specific and sensitive gas chromatographic assay is described for the measurement of d-fenfluramine and its de-ethylated metabolite, d-norfenfluramine, in biological fluids, together with some data on its application to the oral pharmacokinetics of the drug. 2. The analytical method developed has advantages over the previously described methods since it uses nitrogen specific detection and, when applied routinely, enables smaller sample volumes to be used (typically 1 ml of plasma) with a shorter chromatography time and an improved sensitivity (minimum quantifiable level of 2.5 ng ml-1). 3. Peak plasma concentrations of 22 and 24 ng ml-1 of intact drug were reached at 4 h after an oral dose of 14C-d-fenfluramine hydrochloride (30 mg) given to two volunteers as part of a metabolism and disposition study. Subsequently, concentrations of intact drug declined monoexponentially with a half-life of approximately 13 h. Peak concentrations of 10 and 8 ng ml-1 of the metabolite, d-norfenfluramine, were reached after 4 and 6 h and were maintained as a plateau for a further 4-6 h. Assessment of the half-life of the metabolite could not be made because of lack of data on the terminal portion of the curves. 4. The urinary excretion of d-fenfluramine (6.0 and 10.6% of the dose) and d-norfenfluramine (5.8 and 8.8% of the dose) was low, indicating extensive metabolism of the parent drug.

Disposition of (-)-fenfluramine and its active metabolite, (-)-norfenfluramine in rat: a single dose-proportionality study.

1. The disposition of (-)-fenfluramine, (-)-F, was studied in rats after i.v. and oral administration (1.25 to 12.5 mg/kg). Whole blood-to-plasma ratio and the protein binding (determined by equilibrium dialysis) of the compound and its main active metabolite, (-)-norfenfluramine (-)-NF, were investigated. 2. The bound fraction of both compounds (about 40%) was constant in the concentration range of 1-10 nmol/ml. The whole blood to plasma concentration ratios of (-)-F and (-)-NF were larger than unity and were constant over this dose range. 3. The drug followed apparent first-order kinetics, at doses up to 6.25 mg/kg. The mean half-lives of the parent drug and its metabolite were about 1 and 12 h respectively. The volume of distribution of (-)-F was large and total body clearance approached liver blood flow. 4. Oral doses were rapidly absorbed from the rat gastrointestinal tract. Bioavailability of the drug was about 20%. Urinary excretion of unchanged drug (3-4% of dose) and its metabolite (about 20%) were similar after i.v. and oral administration. 5. After larger doses (12.5 mg/kg) the kinetics of (-)-F were nonlinear. The AUC increased, but not in proportion to the dose, and kinetic parameters were modified. 6. Brain concentrations reflected the dose-related changes observed in (-)-F and (-)-NF blood concentrations, and patterns of brain distribution and subcellular localization of the drug and its metabolite were modified at the highest dose tested.

Fenfluramine treatment of autism: relationship of treatment response to blood levels of fenfluramine and norfenfluramine.

Nine children meeting DSM-III criteria for infantile autism were treated with fenfluramine hydrochloride or inactive placebo in a double-blind crossover trial that followed the protocol for the fenfluramine multicenter study. Parents of the two children who had had the highest fenfluramine blood levels wished to have their children continue on fenfluramine, although the improvement they saw could not be demonstrated on the various rating instruments employed. The results of the study, while providing minimal support in themselves for the effectiveness of fenfluramine, do raise the possibility that fenfluramine blood levels might be related to treatment response.