Monoamine oxidase-like

Methylphenidate like cocaine largely acts by blocking reuptake of monoamines into the presynaptic terminal. Methylphenidate administration produces an increase in the steady-state (tonic) levels of monoamines within the synaptic cleft. Thus, DAT inhibitors, such as methylphenidate, increase extracellular levels of monoamines. In contrast, they decrease the concentrations of the monoamine metabolites that depend upon monoamine oxidase (MAO), that is, HVA, but not catecholamine-o-methyltransferase (COMT), because reuptake by the transporter is required for the formation of these metabolites. By stimulating presynaptic autoreceptors, methylphenidate induced increase in dopamine transmission can also reduce monoamine synthesis, inhibit monoamine neuron firing and reduce subsequent phasic dopamine release. 

Monoamine oxidase exists in two forms, MAOa and MAOb. The former is more active against NA and 5-HT than it is against DA, which is a substrate for both, even though, like S-phenylethylamine, it is more affected by MAOb. H seems likely that MAOb is the dominant enzyme in human brain and inhibitors of it, such as selegiline, have some value in the treatment of Parkinson s disease by prolonging the action of the remaining endogenous DA as well as that formed from administered levodopa. 

Against this backdrop, researchers reported evidence that iproniazid, the antitubercular drug that was to become the first antidepressant, might increase norepinephrine and serotonin levels in the brain. How did it have this effect Recall that some of the neurotransmitter molecules released by a neuron are destroyed by enzymes in the synaptic cleft between the sending presynaptic neuron and the receiving postsynaptic neuron. When the neurotransmitter is a monoamine - like norepinephrine and serotonin - this process is called monoamine oxidase (MAO). As early as 1952 researchers at the Northwestern University Medical School in Chicago reported that iproniazid inhibited the oxidation of monoamines. This meant that iproniazid was a... 

The figure below illustrates proposed sites of action of drugs. Tor each drug listedt select the site of action that the drug is most likely to inhibit (a, a receptor iT J3 receptor COMTt cat e cho l-O-methyl transferase MAOt monoamine oxidase NET norepinephrine NMNt normetanephrine). 

Wiley JL, LaVecchia KL, Martin BR, Damaj MI (2002) Nicotine-like discriminative stimulus effects of bupropion in rats. Exp Clin Psychopharmacol 10 129-135 Williams M, Robinson JL (1984) Binding of the nicotinic cholinergic antagonist, dihydro-beta-erythroidine, to rat brain tissue. J Neurosci 4 2906-2911 Witkin JM, Dykstra LA, Carter RB (1982) Acute tolerance to the discriminative stimulus properties of morphine. Pharmacol Biochem Behav 17 223-228 Wooters TE, Bardo MT (2007) The monoamine oxidase inhibitor phenelzine enhances the discriminative stimulus effect of nicotine in rats. Behav Pharmacol 18 601-608 Wright JM Jr, Vann RE, Gamage TE, Damaj MI, WUey JL (2006) Comparative effects of dextromethorphan and dextrorphan on nicotine discrimination in rats. Pharmacol Biochem Behav 85 507-513... 

Monoamine Oxidase Inhibitors (MAOIs). The MAOls work in a unique fashion by blocking the activity of an enzyme that degrades each of three key brain transmitters norepinephrine, dopamine, and serotonin. These widespread effects on several brain transmitter systems make the MAOls a potentially very effective class of medications for a variety of disorders. A few small studies have evaluated the usefulness of the MAOls in the treatment of BPD and found them moderately helpful for the impulsivity associated with this illness. Unfortunately, the requirements for strict dietary restrictions due to a risk of hypertensive crisis severely limit the usefulness of MAOls in the treatment of BPD. These restrictions are a particular concern when treating patients who have problems with impulsivity and are therefore likely to have difficulty maintaining the dietary regimen. For this reason, although they may theoretically be helpful, MAOls should only be used to treat BPD after other more easily tolerated medications have been tried and have failed. In the near future, so-called reversible MAOls that appear to avoid the need for diet restrictions may become available. If so, this will allow us to reconsider their use in the treatment of BPD. For more information regarding the use of MAOls, please refer to Chapter 3. 

The 1960 s and 1970 s saw several other hypotheses proposed and dis-proven. The monoamine oxidase (MAO) deficiency hypothesis was based on the observation of diminished activity of platelet MAO-B in schizophrenia, although this was likely to be an artifact of drug treatment and the small deficits could not, in any case, account for changes in monoamine transmitters. Other hypotheses relating to, among other transmitter molecules, noradrenaline and enkephalin/endorphin have also been proposed. Each of these have had propo-... 

Levodopa, the metabolic precursor of dopamine, is the most effective agent in the treatment of Parkinson s disease but not for drug-induced Parkinsonism. Oral levodopa is absorbed by an active transport system for aromatic amino acids. Levodopa has a short elimination half-life of 1-3 hours. Transport over the blood-brain barrier is also mediated by an active process. In the brain levodopa is converted to dopamine by decarboxylation and both its therapeutic and adverse effects are mediated by dopamine. Either re-uptake of dopamine takes place or it is metabolized, mainly by monoamine oxidases. The isoenzyme monoamine oxidase B (MAO-B) is responsible for the majority of oxidative metabolism of dopamine in the striatum. As considerable peripheral conversion of levodopa to dopamine takes place large doses of the drug are needed if given alone. Such doses are associated with a high rate of side effects, especially nausea and vomiting but also cardiovascular adverse reactions. Peripheral dopa decarboxylase inhibitors like carbidopa or benserazide do not cross the blood-brain barrier and therefore only interfere with levodopa decarboxylation in the periphery. The combined treatment with levodopa with a peripheral decarboxylase inhibitor considerably decreases oral levodopa doses. However it should be realized that neuropsychiatric complications are not prevented by decarboxylase inhibitors as even with lower doses relatively more levodopa becomes available in the brain. 

There is good evidence that the facilitation of peripheral sympathetic nervous system transmission prcxluced by the amphetamines also occurs in the CNS.The possibihty that amphetamines act indirectly (i.e., by releasing monoamines) at monoaminergic synapses in the brain and spinal cord seems likely. However, amphetamine has effects beyond displacement of catecholamines these include inhibition of neuronal amine uptake, direct stimulation of dopamine and serotonin receptors, antagonism of catecholamine action at certain subtypes of adrenoceptors, and inhibition of monoamine oxidase. Interestingly, none of these actions explains the therapeutic benefit of the amphetamines in hyperkinetic children. 

Like the benzodiazepines, buspirone appears to be safe even when given in very high doses. The most common side effects are dizziness, light-headedness, and headache. Abuse, dependence, and withdrawal have not been reported, and buspirone administration does not produce any cross-tolerance to the benzodiazepines. Buspirone has been reported to increase blood pressure in patients taking monoamine oxidase inhibitors, and it may increase plasma levels of haloperidol if coadministered with that agent. 

Monoamine oxidase exists in the human body in two molecular forms, known as type A and type B. Each of these isozymes has selective substrate and inhibitor characteristics. Neurotransmitter amines, such as norepinephrine and serotonin, are preferentially metabolized by MAO-A in the brain. MAO-B is more likely to be involved in the catabolism of human brain dopamine, although dopamine is also a substrate for MAO-A. 

Monoamine oxidase inhibitors. The monoamine oxidase inhibitors (MAOIs) inhibit the intracellular catabolic enzyme monoamine oxidase. There are two types of monoamine oxidase MAO-A and MAO-B, both of which metabolize tyramine and dopamine. In addition, MAO-A preferentially metabolizes norepinephrine, epinephrine, and serotonin, and MAO-B preferentially metabolizes phenylethylamine (an endogenous amphetamine-like substance) and N-methylhistamine (Ernst, 1996). Some MAOIs are selective for A or B and some are nonselective (mixed). In addition, irreversible MAOIs (e.g., phenelzine, tranylcypromine) are more susceptible to the cheese effect than are the reversible agents (e.g., moclobemide). 

Newer MAOI drugs are selective for the MAO-A subtype of the enzyme, and are less likely to interact with foods or other drugs. Monoamine oxidase (MAO) inactivates monoamine substances, many of which are, or are related to, neurotransmitters. The central nervous system mainly contains MAO-A, whose substrates are adrenaline (epinephrine), noradrenaline (norepinephrine), metanephrine, and 5-hydroxyti7ptamine (5-HT), whereas extra-neuronal tissues, such as the liver, lung, and kidney, contain mainly MAO-B which metabolises p-phenylethylamine, phenylethanolamine, o-tyramine, and benzylamine. 

The depressive phase of manic-depressive disorder often requires concurrent use of an antidepressant drug (see Chapter 30). Tricyclic antidepressant agents have been linked to precipitation of mania, with more rapid cycling of mood swings, although most patients do not show this effect. Selective serotonin reuptake inhibitors are less likely to induce mania but may have limited efficacy. Bupropion has shown some promise but—like tricyclic antidepressants—may induce mania at higher doses. As shown in recent controlled trials, the anticonvulsant lamotrigine is effective for many patients with bipolar depression. For some patients, however, one of the older monoamine oxidase inhibitors may be the antidepressant of choice. Quetiapine and the combination of olanzapine and fluoxetine has been approved for use in bipolar depression. 

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