Abstract Administration of d,l ‐fenfluramine (FEN), or the more active isomer d ‐fenfluramine (dFEN), causes long‐term depletion of forebrain serotonin (5‐HT) in animals. The mechanism underlying FEN‐induced 5‐HT depletion is not known, but appears to involve 5‐HT transporters (SERTs) in the brain. Some investigators have postulated that 5‐HT release evoked by FEN is responsible for the deleterious effects of the drug. In the present work, we sought to examine the relationship between drug‐induced 5‐HT release and long‐term 5‐HT depletion. The acute 5‐HT‐releasing effects of dFEN and the non‐amphetamine 5‐HT agonist 1‐( m ‐chlorophenyl)piperazine (mCPP) were evaluated using in vivo microdialysis in rat nucleus accumbens. The ability of dFEN and mCPP to interact with SERTs was assessed using in vitro assays for [ 3 H]‐transmitter uptake and release in rat forebrain synaptosomes. Drugs were subsequently tested for potential long‐lasting effects on brain tissue 5‐HT after repeated dosing (2.7 or 8.1 mg/kg, ip × 4). dFEN and mCPP were essentially equipotent in their ability to stimulate acute 5‐HT release in vivo and in vitro . Both drugs produced very selective effects on 5‐HT with minimal effects on dopamine. Interestingly, when dFEN or mCPP was administered repeatedly, only dFEN caused long‐term 5‐HT depletion in the forebrain at 2 weeks later. These data suggest that acute 5‐HT release per se does not mediate the long‐term 5‐HT depletion associated with dFEN. We hypothesize that dFEN and other amphetamine‐type releasers gain entrance into 5‐HT neurons via interaction with SERTs. Once internalized in nerve terminals, drugs accumulate to high concentrations, causing damage to cells. The relevance of this hypothesis for explaining clinical side effects of FEN and dFEN, such as cardiac valvulopathy and primary pulmonary hypertension, warrants further study.
W-18 (4-chloro-N-[1-[2-(4-nitrophenyl)ethyl]-2-piperidinylidene]-benzenesulfonamide) and W-15 (4-chloro-N-[1-(2-phenylethyl)-2-piperidinylidene]-benzenesulfonamide) represent two emerging drugs of abuse chemically related to the potent opioid agonist fentanyl (N-(1-(2-phenylethyl)-4-piperidinyl)-N-phenylpropanamide). Here, we describe the comprehensive pharmacological profiles of W-18 and W-15, as examination of their structural features predicted that they might lack opioid activity. We found W-18 and W-15 to be without detectible activity at μ, δ, κ, and nociception opioid receptors in a variety of assays. We also tested W-18 and W-15 for activity as allosteric modulators at opioid receptors and found them devoid of significant positive or negative allosteric modulatory activity. Comprehensive profiling at essentially all the druggable GPCRs in the human genome using the PRESTO-Tango platform revealed no significant activity. Weak activity at the sigma receptors and the peripheral benzodiazepine receptor was found for W-18 (Ki = 271 nM). W-18 showed no activity in either the radiant heat tail-flick or the writhing assays and also did not induce classical opioid behaviors. W-18 is extensively metabolized, but its metabolites also lack opioid activity. Thus, although W-18 and W-15 have been suggested to be potent opioid agonists, our results reveal no significant activity at these or other known targets for psychoactive drugs.
High doses of fenfluramine (FEN) are known to deplete central serotonin (5-HT) in animals, but functional impairments associated with such 5-HT depletion have been difficult to identify. In the present work, we examined neuroendocrine responsiveness in rats exposed to repeated high-dose FEN treatment. Male rats fitted with indwelling catheters received FEN (20 mg/kg, subcutaneously, twice a day) or saline for 4 days. At 1 and 2 weeks after treatment, rats were challenged with intravenous FEN (1.5 & 3 mg/kg) or saline. Repeated blood samples were drawn, and plasma was assayed for prolactin and corticosterone by radioimmunoassay. Acute FEN challenge caused dose-dependent elevations of plasma prolactin and corticosterone in all rats. However, the FEN-induced hormone responses were significantly blunted (p < 0.01) in rats previously exposed to FEN. The repeated FEN dosing regimen dramatically reduced (> 50%) postmortem 5-HT levels in the mediobasal hypothalamus, basolateral amygdala, and hippocampus, while the lateral hypothalamus was unaffected. These data suggest that high-dose FEN causes alterations in central 5-HT systems involved with pituitary hormone secretion. The relevance of the present data to the clinical use of FEN is unclear. Because the neuroendocrine challenge paradigm is able to identify functional 5-HT deficits in rats, we propose that similar experiments should be performed in humans. Neuroendocrine challenge tests represent a reliable method to test the existence of FEN-induced neurotoxicity in human patients undergoing long-term FEN treatment.
Combined administration of the amphetamine analogs phentermine and fenfluramine (PHEN/FEN) has been used in the treatment of obesity. While these medications are thought to modulate monoamine transmission, the precise neurochemical effects of the PHEN/FEN mixture have not been extensively studied. To assess the mechanism of PHEN/FEN action, in vivo microdialysis studies were performed in the nucleus accumbens of conscious freely moving rats. A series of amphetamine derivatives including phentermine, chlorphentermine, fenfluramine, and PHEN/FEN (1:1 ratio), were infused locally into the accumbens via reverse-dialysis (1, 10, 100 microM) or injected systemically (1 mg/kg, ip). Dialysate samples were assayed for dopamine (DA) and serotonin (5-HT) by high-performance liquid chromatography with electrochemical detection. When infused locally, phentermine preferentially increased extracellular DA, whereas fenfluramine selectively increased extracellular 5-HT. Local administration of chlorphentermine or the PHEN/FEN mixture caused parallel elevations of both transmitters. Analogous results were obtained when the drugs were injected systemically. Phentermine stimulated robust locomotor activity in mice, whereas chlorphentermine and fenfluramine did not. PHEN/FEN caused modest locomotor stimulation after a low dose, but had no effect at the highest dose. Accumulating evidence suggests that chronic drug and alcohol abuse is associated with deficits in both DA and 5-HT neuronal function. Thus, dual activation of DA and 5-HT neurotransmission with monoamine releasing agents may be an effective treatment strategy for substance use disorders, as well as for obesity. Synapse 36:102-113, 2000. Published 2000 Wiley-Liss, Inc.
