The Effects of Tranylcypromine Isomers on Norepinephrine-H3 Metabolism in Rat Brain

Overview

Journal Psychopharmacology (Berl)

Specialty Pharmacology

Date 1980 Jan 1

PMID 6779313

Citations 6

Authors

T G Reigle

P J Orsulak

J Avni

P A Platz

J J Schildkraut

Affiliations

Soon will be listed here.

Abstract

The effects of d- and l-tranylcypromine on the disposition and metabolism of intracisternally administered l-norepinephrine-H3 were studied in rat brain. Both isomers inhibited the deamination of norepinephrine-H3. However, d-tranylcypromine was considerably more potent than the l-isomer in this respect. In addition, the l-isomer of tranylcypromine was found to enhance the disappearance of endogenous and tritiated norepinephrine from brain. Although this action appeared to result from an increase in catecholamine release, the possibility of uptake inhibition could not be eliminated. The l-isomer of tranylcypromine enhanced the disappearance of norepinephrine-H3 from brain when administered both 20 and 90 min following intracisternal injection of the label. Comparable doses of d-tranylcypromine did not exhibit this effect. Larger increases in brain levels of normetanephrine-H3 were produced by d,l-tranylcypromine than by either the d- or l-isomer alone, indicating that the racemic mixture may produce the greatest increase in the interaction of norepinephrine with its postsynaptic receptors.

Citing Articles

The pharmacokinetics of tranylcypromine enantiomers in healthy subjects after oral administration of racemic drug and the single enantiomers.

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Role of monoamines in behavior of reserpinized rats given tranylcypromine stereoisomers.

Smith D J Neural Transm. 1981; 50(2-4):193-200.

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Antidepressant efficacy of tranylcypromine isomers: a controlled study.

Moises H, Beckmann H J Neural Transm. 1981; 50(2-4):185-92.

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Tranylcypromine isomers: single-dose effects in normal human subjects.

Gorenstein C, Gentil V Psychopharmacology (Berl). 1981; 75(4):400-3.

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Effects of tranylcypromine enantiomers on monoamine uptake and release and imipramine binding.

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