P.H. Duffield

Identification of some human urinary metabolites of the intoxicating beverage kava

Methane chemical ionization (CI) gas chromatography-mass spectrometry (GC-MS) has been used to identify some of the human urinary metabolites of the kava lactones following ingestion of kava prepared by the traditional method of aqueous extraction of Piper methysticum. All seven major, and several minor, kava lactones were identified in human urine. Observed metabolic transformations include the reduction of the 3,4-double bond and/or demethylation of the 4-methoxyl group of the alpha-pyrone ring system. Demethylation of the 12-methoxy substituent in yangonin (or alternatively hydroxylation at C-12 of desmethoxyyangonin) was also recognised. This product was isolated by high-performance liquid chromatographic analysis of crude urine extracts and characterised by methane CI GC-MS. In contrast to the situation prevailing in the rat no dihydroxylated metabolites of the kava lactones, or products from ring opening of the 2-pyrone ring system, were identified in human urine. GC-MS analysis of urine can be readily utilised to determine whether donors have recently consumed kava.

The concentration in brain of octopamine and tyramine after portal-systemic bypass in rats: Neuroamine concentrations determined simultaneously by methane chemical ionization gas chromatography mass spectrometry

The concentration in brain of both octopamine (OCT) and tyramine (TYR) was significantly increased in rats 8 weeks after portal-systemic bypass. This suggests that the increase in OCT is secondary to increased decarboxylation of tyrosine to TYR. However, the role these neuroamines, particularly OCT, play in the development of hepatic encephalopathy remains controversial.

Evidence that alpha-methyl-p-tyramine is implicated in behavioural augmentation to amphetamine

Behavioural studies showed that administration of alpha-methyl-p-tyramine (AMT; 10 mg/kg i.p.) to rats 24 hr before treatment with d-amphetamine (AMPHET; 4 mg/kg i.p.) resulted in augmentation of AMPHET-induced stereotype activity. Parallel experiments involving electro-chemical estimation of dopamine metabolites in the striatum showed that the decrease in the concentration of homovanillic acid (HVA) produced by AMPHET (4 mg/kg) was enhanced in AMT (10 mg/kg) pretreated animals. These findings suggest that AMT derived from previous doses of AMPHET may play a role in the phenomena of behavioural augmentation observed after chronic administration of AMPHET.

How metabolites may augment some psychostimulant actions of amphetamine

Abstract The release of dopamine in the CNS by repeated doses of amphetamine is thought to underlie amphetamine-induced psychosis in humans and behavioural augmentation in experimental animals, although the mechanisms involved are incompletely understood. Donald Dougan, Denis Wade and Patricia Duffield discuss recent data on the long-term accumulation of metabolites of amphetamine in the brain. One of these compounds, α-methyltyramine, the para-hydroxylated metabolite of amphetamine, enhances the stereotype response to the acute administration of the drug and also causes augmentation of the amphetamine-induced decrease in dopamine metabolism in the striatum. These observations are consistent with the hypothesis that behavioural augmentation, seen after repeated doses of amphetamine, is due to the accumulation of α-methyltyramine in dopaminergic nerve terminals. Subsequent doses of amphetamine then release α-methyltyramine which blocks dopamine uptake with an apparent increase in the amphetamine-releasable pool of dopamine without change in receptor sensitivity. The close structural and metabolic similarities between amphetamine and its metabolites, and naturally occurring monoamines, again raises the question of the possible role of these amines in some forms of schizophrenia.

Effect of chlordimeform and clonidine on the turnover of P-octopamine in rat hypothalamus and striatum.

The effect of the invertebrate octopamine agonists chlordimeform and clonidine on the concentration and turnover of p-octopamine and m- and p-tyramine was determined in rat hypothalamus and striatum. Clonidine (0.25 mg/Kg, s.c.) did not alter the concentration of p-octopamine in the hypothalamus or p-tyramine in the striatum. Administration of chlordimeform (50 mg/Kg, i.p.) resulted in an increase in p- and m-tyramine concentrations in the striatum but not that of p-octopamine in the hypothalamus. This increase in the tyramine isomers is consistent with the ability of chlordimeform and its metabolite, demethylchlordimeform, to inhibit monoamine oxidase (MAO). The concurrent administration of chlordimeform (50 mg/Kg, i.p.) and pargyline (75 mg/Kg, i.p.) produced a significant decrease in the accumulation of octopamine in the hypothalamus but not in the striatum. In contrast, the concurrent administration of clonidine (0.25 mg/Kg, s.c.) and pargyline (75 mg/Kg, i.p.) caused a significant decrease in the accumulation of octopamine in the striatum but not hypothalamus. These results show that the turnover of octopamine in the hypothalamus and striatum is decreased by chlordimeform and clonidine, respectively. Further, clonidine is known to modulate the turnover of amines in mammalian noradrenergic nerve terminals by an action at presynaptic adrenergic receptors. These data suggest that two mechanisms, one involving presynaptic adrenergic receptors in the striatum, and the other involving as yet unidentified receptors in the hypothalamus, modulate the turnover of octopamine in the mammalian brain.

Occurrence and synthesis of octopamine in the heart and ganglia of the mollusc Tapes watlingi

Abstract 1. 1. Gas chromatography chemical ionization mass spectrometry was used to measure the octopamine, tyramine, β-hydroxyphenethylamine and dopamine content of nervous, cardiovascular and gastrointestinal tissues in the clam Tapes watlingi . 2. 2. The nervous tissues contained higher concentrations of octopamine than either cardiovascular or gastrointestinal tissue. 3. 3. Nervous and ventricular tissue synthesized deuterated octopamine, from exogenous deuterated tyramine. These data support the suggestion that octopaminergic nerves may be present in the molluscan heart.

Absence of α-methyldopamine in rat striatum after chronic administration of d-amphetamine

Direct measurement by gas chromatography methane chemical ionization mass spectrometry of alpha-methyldopamine and alpha-methylnorepinephrine in rat striatum has shown the failure of these compounds to be accumulated in vivo after chronic administration of d-amphetamine despite the accumulation of alpha-methyltyramine, an immediate in vitro precursor. Further, both alpha-methyldopamine and alpha-methyltyramine accumulate in rat striatum after administration of alpha-methyltyrosine. These data suggest that, after administration of alpha-methyltyrosine, alpha-methyldopamine is formed via decarboxylation of alpha-methyldopa and not from hydroxylation of alpha-methyltyramine. Finally, our results indicate that alpha-methyldopamine does not play a role in the development of tolerance to d-amphetamine.

Modulation of dopamine receptors in the Tapes clam by dextroamphetamine and phenylethanolamine

The mechanism underlying the modulation, by dextroamphetamine and compounds related to phenylethanolamine, of responses to dopamine and serotonin has been studied in the isolated ventricle and aortic bulb of the clam Tapes watlingi. Dextroamphetamine and phenylethanolamine but not cocaine and benztropine have the ability to unmask inhibitory responses to both dopamine and serotonin in the ventricle. Chlordimeform but not clozapine attenuates the inhibitory response to both dextroamphetamine and phenylethanolamine in concentrations which have little or no effect on the inhibitory response to dopamine in the ventricle. Phenylethanolamine, dextroamphetamine, phenylpropylolamine and p-chloro-phenylethanolamine but not octopamine or noradrenaline attenuate the contractile responses to both dopamine and serotonin in preparations of the quiescent aortic bulb. These data show that there are specific receptors for phenylethanolamine in the Tapes heart capable of modulating responses to dopamine and serotonin, and suggests that this biogenic phenethylamine can act as an environmental and physiological factor which may determine how the mollusc heart responds to dopamine.