Enzyme inhibition antidepressants

Depression and hypertension are both common conditions such that some co-morbidity is inevitable, and panic disorder is epidemiologically associated with hypertension. Co-prescription of an enzyme-inhibiting antidepressant with a P-adrenoceptor blocker (metoprolol, CYP 2D6) or with a calcium antagonist (diltiazem, amlodipine, CYP 3A4) may exaggerate antihypertensive effects. 

Another important characteristic of M AOIs is the production of reversible versus irreversible enzyme inhibition. An irreversible inhibitor permanently disables the enzyme. This means that MAO must be resynthesized, in the absence of the drug, before the activity of the enzyme can be reestablished. Resynthesis of the enzyme may take up to 2 weeks. For this reason, an interval of 10-14 days is required after discontinuing irreversible inhibitors and before instituting treatment with other antidepressants or permitting the use of contraindicated drugs or the consumption of contraindicated foods. On the other hand, a reversible inhibitor can move away from the active site of the enzyme, making the enzyme available to metabo-hze other substances. The reversibility and selectivity of the currently available MAOIs are summarized in Table 2-4. 

Another important CYP450 enzyme for antidepressants is 2D6. Tricyclic antidepressants are substrates for 2D6, which hydroxylates and thereby inactivates them (Fig. 6—14). Several antidepressants from the SSRI class are inhibitors of CYP2D6 (Fig. 6—15). There is a wide range of potency for 2D6 inhibition by the five SSRIs, with paroxetine and fluoxetine the most potent and fluvoxamine, sertraline, and citalopram the least potent. 

Inhibitors of monoamine oxidase A (thy-meretics). Moclobemide is the only representative of this group. It produces a reversible inhibition of MAOa, which is responsible for inactivation of the amines norepinephrine, dopamine, and serotonin (A). Enzyme inhibition results in an increased concentration of these neurotransmitters in the synaptic cleft. Moclobemide is less effective as an antidepressant than as a psychomotor stimulant. It is indicated only in depressions with extreme psychomotor slowing and is contraindicated in patients at risk of suicide. 

Amphetamine [XXII) is a central stimulant and many would not classify it with the antidepressant drugs proper. It has, however, been extensively used in the treatment of depression, it produces euphoria and some at least of its actions may be due to inhibition of monoamine oxidase. However, it also inhibits dopamine- S-oxidase, impairs the noradrenaline binding capacity of the brain and has direct sympathomimetic activity. Its classification with the antidepressants seems, therefore, to be justified, but it is not included with the monoamine oxidase inhibitors, since only a small part of its action can be attributed to enzyme inhibition. Amphetamine is a potentially addictive drug and it should be used cautiously and over short periods of time. Other compounds which are used, if at all, only for the treatment of mild depression, include methylphenidate [XXIII), pipradol [Table 5.2) and deanol (XXIV). The last named compound is interesting since it may owe its effectiveness to a stimulant action on acetylcholine synthesis > . ... 

An explanation of the mode of action of the monoamine oxidase inhibitors in terms of their intervention in central transmission processes is difficult for several reasons. Monoamine oxidase is widely distributed in the body and some of the consequences of its inhibition may arise peripherally in the brain the enzyme participates in the inactivation of at least three substances (noradrenaline, dopamine and 5-hydroxytryptamine). Not all monoamine oxidase inhibitors have antidepressant activity but those that have may owe at least part of their activity to an action other than enzyme inhibition. 

The interactions with cimetidine are well established, well documented and of clinical importance. The incidence is uncertain hut most patients could be affected. Those taking amitriptyline, desipramine, doxepin, imi-pramine or nortriptyline who are given cimetidine should be warned that adverse effects such as mouth dryness, urine retention, blurred vision, constipation, tachycardia, postural hypotension may be more likely to occur. Other tricyclic antidepressants would be expected to be similarly affected. If symptoms are troublesome reduce the dosage of the antidepressant (33 to 50% has been suggested) or replace the cimetidine with ranitidine, which does not appear to interact. Other H2-ieceptor antagonists that do not cause enzyme inhibition (e.g. famotidine and nizatidine) would also not be expected to interact. 

Modulation of second-messenger pathways is also an attractive target upon which to base novel antidepressants. Rolipram [61413-54-5] an antidepressant in the preregistration phase, enhances the effects of noradrenaline though selective inhibition of central phosphodiesterase, an enzyme which degrades cycHc adenosiae monophosphate (cAMP). Modulation of the phosphatidyl iaositol second-messenger system coupled to, for example, 5-HT,, 5-HT,3, or 5-HT2( receptors might also lead to novel antidepressants, as well as to alternatives to lithium for treatment of mania. Novel compounds such as inhibitors of A-adenosyl-methionine or central catechol-0-methyltransferase also warrant attention. 

By maintaining low concentrations of cytoplasmic noradrenaline, MAO will also regulate the vesicular (releasable) pool of transmitter. When this enzyme is inhibited, the amount of noradrenaline held in the vesicles is greatly increased and there is an increase in transmitter release. It is this action which is thought to underlie the therapeutic effects of an important group of antidepressant drugs, the MAO inhibitors (MAOIs) which are discussed in Chapter 20. 

In contrast, iproniazid, introduced in 1951 for treatment of tuberculosis, induced euphoria and was described as a psychic energiser . In fact, these patients, when given iproniazid, could become quite disruptive and this action was regarded as an undesirable side-effect However, its beneficial effects in depression were soon recognised and it was regarded as the first effective antidepressant drug. Studies of peripheral sympathetic neurons, later extended to noradrenergic neurons in the brain, showed that iproniazid irreversibly inhibits the catalytic enzyme, monoamine oxidase (MAO). Because only cytoplasmic monoamines are accessible to MAO, inhibition of this enzyme first increases the concentration of the pool of soluble transmitter but this leads to a secondary increase in the stores of vesicle-bound transmitter i.e. the pool available for impulse-evoked release (Fillenz and Stanford 1981). 

The main problems with early, irreversible MAOIs were adverse interactions with other drugs (notably sympathomimetics, such as ephedrine, phenylpropanolamine and tricyclic antidepressants) and the infamous "cheese reaction". The cheese reaction is a consequence of accumulation of the dietary and trace amine, tyramine, in noradrenergic neurons when MAO is inhibited. Tyramine, which is found in cheese and certain other foods (particularly fermented food products and dried meats), is normally metabolised by MAO in the gut wall and liver and so little ever reaches the systemic circulation. MAOIs, by inactivating this enzymic shield, enable tyramine to reach the bloodstream and eventually to be taken up by the monoamine transporters on serotonergic and noradrenergic neurons. Fike amphetamine, tyramine reduces the pH gradient across the vesicle membrane which, in turn, causes the vesicular transporter to fail. Transmitter that leaks out of the vesicles into the neuronal cytosol cannot be metabolised because... 

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... 

Many neurotransmitters are inactivated by a combination of enzymic and non-enzymic methods. The monoamines - dopamine, noradrenaline and serotonin (5-HT) - are actively transported back from the synaptic cleft into the cytoplasm of the presynaptic neuron. This process utilises specialised proteins called transporters, or carriers. The monoamine binds to the transporter and is then carried across the plasma membrane it is thus transported back into the cellular cytoplasm. A number of psychotropic drugs selectively or non-selectively inhibit this reuptake process. They compete with the monoamines for the available binding sites on the transporter, so slowing the removal of the neurotransmitter from the synaptic cleft. The overall result is prolonged stimulation of the receptor. The tricyclic antidepressant imipramine inhibits the transport of both noradrenaline and 5-HT. While the selective noradrenaline reuptake inhibitor reboxetine and the selective serotonin reuptake inhibitor fluoxetine block the noradrenaline transporter (NAT) and serotonin transporter (SERT), respectively. Cocaine non-selectively blocks both the NAT and dopamine transporter (DAT) whereas the smoking cessation facilitator and antidepressant bupropion is a more selective DAT inhibitor. 

The first two antidepressants, iproniazid and imipramine, were developed in the same decade. They were shown to reverse the behavioural and neurochemical effects of reserpine in laboratory rodents, by inhibiting the inactivation of these monoamine transmitters (Leonard, 1985). Iproniazid inhibits MAO (monoamine oxidase), an enzyme located in the presynaptic neuronal terminal which breaks down NA, 5-HT and dopamine into physiologically inactive metabolites. Imipramine inhibits the reuptake of NA and 5-HT from the synaptic cleft by their transporters. Therefore, both of these drugs increase the availability of NA and 5-HT for binding to postsynaptic receptors and, therefore, result in enhanced synaptic transmission. Conversely, lithium, the oldest but still most frequently used mood stabiliser (see below), decreases synaptic NA (and possibly 5-HT) activity, by stimulating their reuptake and reducing the availability of precursor chemicals required in the biosynthesis of second messengers. 

In animal studies, high levels of cortisol have been shown to induce (increase) the activity of the enzyme tryptophan 2,3-dioxygenase in the liver, thereby decreasing the bioavailability of tryptophan to the brain. It is interesting to note that low acute doses of a number of different antidepressants inhibit the activity of this enzyme and, as a result, increase brain tryptophan concentrations, thus stimulating 5-HT synthesis (Badawy and Evans, 1982). In this way a link between the two key monoamine neurotransmitters and the hormone may be seen namely, reduced brain NA activity leads to decreased inhibition of the HPA axis, while increased levels of cortisol reduce 5-HT activity in the brain. Activation of the HPA axis has also been shown to result in tissue atrophy, in particular of the limbic system s hippocampus, and a reduction in the levels of neurotrophic factors responsible for the maintenance and optimal function of brain neurons (Manji et al., 2001). In conclusion, manipulation of the HPA axis (Nemeroff, 2002) and stimulation of neurotrophic factor activity (Manji et al., 2001) might open up new avenues for the treatment of affective disorders. 

Tranylcypromine sulfate is an antidepressant drug and an inhibitor of MAO. Its antidepressant effect is probably due to the accumulation of NE in the brain as a consequence of inhibition of the enzyme. The other MAO I currently used as an antidepressant is phenelzine sulfate. 

The ability of an SSRI, or any antidepressant, to inhibit or induce the activity of the cytochrome P450 (CYP450) enzymes can be a significant contributory factor in determining its capability to cause a pharmacokinetic drug-drug interaction. 

Blocking Enzymes. Remember that there are enzymes both in the synapse and in the cytoplasm of the nerve cells that metabolize and thereby inactivate neurotransmitter molecules. One way to promote neurotransmission is to increase the supply of available neurotransmitter. Blocking (or inhibiting) the enzymes that destroy neurotransmitter will do just that. Certain antidepressants known as monoamine oxidase inhibitors (MAOIs) and some medications used to treat Alzheimer s disease act in this manner. 

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