Investigating interactions between phentermine, dexfenfluramine, and 5-HT2C agonists, on food intake in the rat.

RATIONALE: Synergistic or supra-additive interactions between the anorectics (dex)fenfluramine and phentermine have been reported previously in the rat and in the clinic. Studies with 5-HT2C antagonists and 5-HT2C knockouts have demonstrated dexfenfluramine hypophagia in the rodent to be mediated by actions at the 5-HT2C receptor. Given the recent FDA approval of the selective 5-HT2C agonist lorcaserin (BELVIQ®) for weight management, we investigated the interaction between phentermine and 5-HT2C agonists on food intake. OBJECTIVES: This study aims to confirm dexfenfluramine-phentermine (dex-phen) synergy in a rat food intake assay, to extend these findings to other 5-HT2C agonists, and to determine whether pharmacokinetic interactions could explain synergistic findings with particular drug combinations. METHODS: Isobolographic analyses were performed in which phentermine was paired with either dexfenfluramine, the 5-HT2C agonist AR630, or the 5-HT2C agonist lorcaserin, and inhibition of food intake measured in the rat. Subsequent studies assessed these same phentermine-drug pair combinations spanning both the full effect range and a range of fixed ratio drug combinations. Satellite groups received single doses of each drug either alone or in combination with phentermine, and free brain concentrations were measured. RESULTS: Dex-phen synergy was confirmed in the rat and extended to the 5-HT2C agonist AR630. In contrast, although some synergistic interactions between lorcaserin and phentermine were observed, these combinations were largely additive. Synergistic interactions between phentermine and dexfenfluramine or AR630 were accompanied by combination-induced increases in brain levels of phentermine. CONCLUSIONS: Dex-phen synergy in the rat is caused by a pharmacokinetic interaction, resulting in increased central concentrations of phentermine.

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.

Impact of antenatal exposure of mice to fenfluramine on cardiac development and long-term growth of the offspring.

The objective of this investigation was to determine, in a placebo-controlled manner, whether antenatal exposure to formulations of fenfluramine and dexfenfluramine impacted cardiac development and long-term growth of exposed mice offspring. One hundred forty-four CD-1 mice were randomized to six treatment groups (n=23 or 25) to obtain, per group, 5 gravids for killing on gestational day (GD) 15 and < or =10 deliveries for assessing growth of the offspring. Either fenfluramine preparation was administered in feed bars in two doses: 1 and 3.2 times the equivalent human daily dosage according to body surface area. The drugs were given from 2 weeks before mating until GD 15. The mice ingested each drug at target values, averaging 10.5+/-0.3 and 31.8+/-1.9 mg/kg/d for fenfluramine and 5.0+/-0.2 and 16.2+/-0.4 mg/kg/d for dexfenfluramine. The drug concentration was about 36% in the fetal brain compared with the adult brain. The maternal and the offspring hearts, including mitral and aortic valves, of fenfluramine-exposed mice were indistinguishable from the placebo-exposed mice. The duration of gestation and the litter size were the same between the treatment groups. The mean body weights, body lengths, and head circumferences and early functional testing did not differ significantly between the fenfluramine or dexfenfluramine-exposed offspring and the placebo-exposed offspring. There were no significant treatment differences in growth measured as body weights to PND 120. Neither fenfluramine formulation, given before conception and during gestation, impacted cardiac development and long-term growth of the mice offspring.

Measurement of human brain dexfenfluramine concentration by 19F magnetic resonance spectroscopy.

OBJECTIVE: The goals of this study were to quantitate the brain concentration of the anorectic drug dexfenfluramine (DF) in human subjects receiving clinical doses of DF and to determine whether human brain DF concentrations approach those reported to cause irreversible neurochemical changes in animals. Each subject's brain DF concentration was measured several times over an extended period of DF treatment to determine whether drug accumulation in the brain would plateau or continue to increase throughout the treatment period. DESIGN: Fluorine magnetic resonance spectroscopy (19F-MRS) was used to directly detect and quantitate brain levels of the fluorinated drug dexfenfluramine and its active metabolite dex-norfenfluramine (dNF). Patients received 15 mg dexfenfluramine BID for 90 days. 19F-MRS measurements were performed at baseline and at three times during the treatment period. PARTICIPANTS: Twelve women (age 38-54 years) who were obese, with body mass indices of 28. 4-37.4, but otherwise healthy. RESULTS: The combined concentration of DF and nDF reached steady-state in the human brain after approximately 10 days of treatment. The steady-state brain concentration averaged approximately 4 microM and did not tend to increase significantly during the 90 day treatment period. CONCLUSIONS: These results demonstrate that fluorinated drugs can be quantified using 19F MRS at concentrations below 10 microM in the human brain. The time-course data suggest that brain DF concentrations parallel DF plasma pharmacokinetics in humans. Measured brain dexfenfluramine/nor-dexfenfluramine concentrations were well below levels previously found to cause irreversible brain alterations in animals.