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Depression adrenoceptors

Future Outlook for Antidepressants. Third-generation antidepressants are expected to combine superior efficacy and improved safety, but are unlikely to reduce the onset of therapeutic action in depressed patients (179). Many dmgs in clinical development as antidepressive agents focus on estabhshed properties such as inhibition of serotonin, dopamine, and/or noradrenaline reuptake, agonistic or antagonistic action at various serotonin receptor subtypes, presynaptic tt2-adrenoceptor antagonism, or specific monoamine—oxidase type A inhibition. Examples include buspirone (3) (only... [Pg.233]

As of the mid-1990s, use of MAOIs for the treatment of depression is severely restricted because of potential side effects, the most serious of which is hypertensive crisis, which results primarily from the presence of dietary tyramine. Tyramine, a naturally occurring amine present in cheese, beer, wine, and other foods, is an indirecdy acting sympathomimetic, that is, it potently causes the release of norepinephrine from sympathetic neurons. The norepinephrine that is released interacts with adrenoceptors and, by interacting with a-adrenoceptors, causes a marked increase in blood pressure the resultant hypertension may be so severe as to cause death. [Pg.466]

Some P-adrenoceptor blockers have intrinsic sympathomimetic activity (ISA) or partial agonist activity (PAA). They activate P-adrenoceptors before blocking them. Theoretically, patients taking P-adrenoceptor blockers with ISA should not have cold extremities because the dmg produces minimal decreases in peripheral blood flow (smaller increases in resistance). In addition, these agents should produce minimal depression of heart rate and cardiac output, either at rest or during exercise (36). [Pg.114]

Toxic effects of propranolol are related to its blocking P-adrenoceptor blocking actions. They include cardiac failure, hypotension, hypoglycemia, and bronchospasm. Propranolol is lipophilic and crosses the blood—brain barrier. Complaints of fatigue, lethargy, mental depression, nightmares, hallucinations, and insomnia have been reported. GI side effects include nausea, vomiting, diarrhea, and constipation (1,2). [Pg.119]

Acebutolol. Acebutolol hydrochloride is a hydrophilic, cardioselective P-adrenoceptor blocker that has about 1/25 the potency of propranolol in this regard. The dmg has moderate ISA and weak membrane stabilizing activities. It is approved for the treatment of hypertension and ventricular arrhythmias, especially PVCs. Acebutolol should produce minimal depression of heart rate because of its ISA (32). [Pg.119]

Sotalol is rapidly and almost completely (>90%) absorbed. Bioavahabhity of absorbed dmg is 89—100%. Peak plasma levels are achieved in 2—4 h. Sotalol is 50% bound to plasma proteins. Plasma half-life of the compound is about 5.2 h. No metabolites of sotalol have been identified indicating littie metabolism. The dmg is excreted mainly by the kidneys (80—90%) and about 10% is eliminated in the feces. The plasma half-life is prolonged in patients having renal failure. Kinetics of the compound are not affected by changes in liver function (1,2). Sotalol has ah the adverse effects of -adrenoceptor blockers including myocardial depression, bradycardia, transient hypotension, and proarrhythmic effects (1,2). [Pg.121]

The cardiac effects of the calcium antagonists, ie, slowed rate (negative chronotropy) and decreased contractile force (negative inotropy), are prominent in isolated cardiac preparations. However, in the intact circulation, these effects may be masked by reflex compensatory adjustments to the hypotension that these agents produce. The negative inotropic activity of the calcium antagonists may be a problem in patients having heart failure, where contractility is already depressed, or in patients on concomitant -adrenoceptor blockers where reflex compensatory mechanisms are reduced. [Pg.126]

More then a dozen representatives of the above ring systems were introduced into the human therapy. Actisomide (2) and trequinsin (3) are used as antiarrhytmic and antihypertensive agents, respectively. Sunepitron (4), a a 2-adrenoceptor antagonist, is under clinical trials for the treatment of anxiety and depression. Representatives of the third generation of antibacterial quinolone-3-carboxylic acids the blockbluster ofloxacin (5), its levorotatory enantiomer, levofloxacin (6), and rufloxacin (7) have gained wide acceptance for the treatment of bacterial infections of the respiratory and urinary tracts, skin, and soft tissues, as well as sexually transmitted diseases, and pazufloxacin (8) is under development. Praziquantel (9) is widely applied for the treatment of schistosomes- and cestode-caused infection in both veterinary and human therapies (Scheme 4). [Pg.225]

Class II drugs are classical (3-adrenoceptor antagonists such as propranolol, atenolol, metoprolol or the short-acting substance esmolol. These drugs reduce sinus rate, exert negative inotropic effects and slow atrioventricular conduction. Automaticity, membrane responsiveness and effective refractory period of Purkinje fibres are also reduced. The typical extracardiac side effects are due to (3-adrenoceptor blockade in other organs and include bronchospasm, hypoglycemia, increase in peripheral vascular resistance, depressions, nausea and impotence. [Pg.100]

There is some evidence that receptors for other neurotransmitters on 5-HT nerve terminals also modify release of 5-HT. These include nicotinic receptors (increase release from striatal synaptosomes), a2A-adrenoceptors (depress cortical release) and H3-receptors (cortical depression). Because changes in 5-HT release on activation of these receptors is evident in synaptosomal preparations, it is likely that these are true heteroceptors . [Pg.194]

A logical conclusion from this work was that depression is caused by hyperresponsive )S-adrenoceptors. At first, this might seem to undermine Schildkraut s suggestion that depression is caused by a deficit in noradrenergic transmission. However, proliferation of receptors is the normal response to a deficit in transmitter release and so the opposite change, dowmegulation of jS-adrenoceptors by antidepressants, would follow an increase in the concentration of synaptic noradrenaline. This would be consistent with both their proposed mechanism of action and the monoamine theory for depression. [Pg.444]

Brismar, K Mogensen, L. Wetterberg, L. (1987). Depressed melatonin secretion in patients with nightmares due to beta-adrenoceptor blocking drugs. Acta Med. Scand. 221, 155-8. [Pg.302]

Virtually all types of drug that have been shown to be effective in major depression exert profound effects on the functioning of the serotoninergic or noradrenergic systems, or both. Although some treatments have been shown to decrease the sensitivity of certain postsynaptic 5-HT and NE receptors, it is generally believed that it is an enhancement of neurotransmission in these systems that is responsible for the improvement of the core symptoms of depression. For instance, long-term administration of tricyclic antidepressants (TCAs) or monoamine oxidase inhibitors (MAOIs) decreases the density of (3-adrenoceptors and cortical 5-HT2 receptors (Blier and Abbott 2003). [Pg.435]

At the postsynaptic level, lithium has been shown to reduce the function of beta adrenoceptors, presumably by affecting the coupling between the receptor and the secondary messenger system. This effect only becomes apparent following chronic treatment, which may help to explain the delay of several days, or even weeks, before an optimal beneficial effect is observed. All antidepressants are known to reduce the functional activity of postsynaptic beta receptors, which may explain why lithium has both an antimanic and an antidepressant effect in patients with manic-depression. [Pg.202]

Clonidine is an agonist at a - and o 2-adreno-ceptor subtypes. It reduce the sympathetic tonus and is thereby a useful antihypertensive drug. Clonidine can induce sedation, depression and peripheral side effects like a dry mouth. Unspecific a-adrenoceptor blocking agents like tricyclic antidepressants can reduce the antihypertensice effect of clonidine. [Pg.309]

HT2 antagonists like trazodone, nefazodone, clozapine and risperidone are used in the treatment of schizophrenia and depression. They block adrenoceptors and Hi-histamine-receptors as well. Hypotension, drowsiness and weight gain can occur. [Pg.315]

Mirtazapine has a novel mechanism of action that in theory should promote anxiolytic effects, although evidence from studies of anxiety disorders is awaited. It increases synaptic release of serotonin and noradrenaline via blockade of presynaptic inhibitory a2-adrenoceptors, as well as blocking post-synaptic 5-HT2 and 5-HT3 serotonin receptors and Hi histamine receptors. Mirtazapine has good efficacy for anxiety symptoms associated with depression (Fawcett and Barkin 1998), and in controlled studies was superior to... [Pg.484]

The toxicity associated with propranolol is for the most part related to its primary pharmacological action, inhibition of the cardiac (3-adrenoceptors. This topic is discussed in detail in Chapter 11. In addition, propranolol exerts direct cardiac depressant effects that become manifest when the drug is administered rapidly by the IV route. Glucagon immediately reverses all cardiac depressant effects of propranolol, and its use is associated with a minimum of side effects. The inotropic agents amrinone (Inocor) and milrinone (Primacor) provide alternative means of augmenting cardiac contractile function in the presence of -adrenoceptor blockade (see Chapter 15). Propranolol may also stimulate bron-chospasm in patients with asthma. [Pg.184]

Verapamil must be used with extreme caution or not at all in patients who are receiving p-adrenoceptor blocking agents. Normally, the negative chronotropic effect of verapamil will in part be overcome by an increase in reflex sympathetic tone. The latter is be prevented by simultaneous administration of a p-adrenoceptor blocking agent, which exaggerates the depressant effects of... [Pg.191]

The TCA drugs have lost their place as first-line therapy for depression because of their bothersome side effects (Table 33.2) at therapeutic doses and lethal effects in toxic doses. In addition to their presynaptic effects on the neuronal uptake of norepinephrine and serotonin, they block several postsynaptic receptors. They are potent cholinergic muscarinic receptor antagonists, resulting in symptoms such as dry mouth, constipation, tachycardia, blurred vision and urinary retention. Blockade of histamine receptors (Hi) often results in sedation and weight gain. Antagonism of aj-adrenoceptors in the vasculature can cause orthostatic hypotension. [Pg.391]

Goodwin FK, Murphy DL, Dunner DL, et al Dthium response in unipolar versus bipolar depression. Am J Psychiatry 129 76-79, 1972 Goodwin GM, DeSouza RJ, Wood AJ, et al TJie enhancement by lithium of the 5-HTlA mediated serotonin syndrome produced by 8-OH-DPAT in the rat evidence for a post-synaptic mechanism. Psychopharmacology 90 488-493, 1986a Goodwin GM, DeSouza RJ, Wood AJ, et al Lithium decreases 5-HTlA and 5-HT2 receptor and alpha-2 adrenoceptor mediated function in mice. Psychopharmacology 90 482-487, 1986b... [Pg.647]


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See also in sourсe #XX -- [ Pg.444 ]




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