Antihistamines antagonists

The discovery of the antiulcer activity of H2 antihistamine antagonists has revolutionized the treatment of that disease. A benzimidazole. Omeprazole (55), inhibits gastric secretion and subsequent ulcer formation by a quite different mechanism. Studies at the molecular level suggest that this compound inhibits K /H dependent ATPase and consequently shuts down the proton pumping action of this enzyme system. 

Hj Antihistamine Treatment in Allergic Diseases. H -receptor antagonists are used for the symptomatic treatment of several allergic... 

Lithium Amide. Lithium amide [7782-89-0], LiNH2, is produced from the reaction of anhydrous ammonia and lithium hydride. The compound can also be prepared by the removal of ammonia from solutions of lithium metal in the presence of catalysts (54). Lithium amide starts to decompose at 320°C and melts at 375°C. Decomposition of the amide above 400°C results first in lithium imide, Li2NH, and eventually in lithium nitride, Li N. Lithium amide is used in the production of antioxidants (qv) and antihistamines (see HiSTAMlNE AND HISTAMINE ANTAGONISTS). 

The principal OTC pharmaceutical products include cold remedies, vitamins and mineral preparations, antacids, analgesics, topical antibiotics, antiftingals and antiseptics, and laxatives. Others include suntan products, ophthalmic solutions, hemorrhoidal products, sleep aids, and dermatological products for treatment of acne, dandmff, insect parasites, bums, dry skin, warts, and foot care products (11). More recent prescription-to-OTC switches have included hydrocortisone, antihistamine and decongestant products, antiftingal agents, and, as of 1995, several histamine H2-receptor antagonists. 

Two newer potent selective H -antagonists, terfenadine (23) (132) and astemizole (24) (133), have been developed which have neither the sedative nor the anticholinergic Habilities of the earlier agents. Both of these compounds have proven efficacious in the treatment of hay fever and produce very few side effects, prompting a re-evaluation of the role of antihistamines in asthma treatment. 

The short-acting clomethia2ole [533-45-9] (1), sometimes used as therapy for sleep disorders ia older patients, shares with barbiturates a risk of overdose and dependence. Antihistamines, such as hydroxy2iae [68-88-2] (2), are also sometimes used as mild sedatives (see HiSTAMlNES AND HISTAMINE antagonists). Antidepressants and antipsychotics which have sedative effects are used to treat insomnia when the sleep disorder is a symptom of some underlyiag psychiatric disorder. 

Tricyclic Antidepressants. Imipramine [50-49-7] (32), which was the first tricycHc antidepressant to be developed, is one of many useful psychoactive compounds derived from systematic molecular modifications of the antihistamine prometha2ine [60-87-7] (see Histamine and histamine antagonists). The sulfur atom of prometha2ine was replaced with an ethylene bridge and the dimethylamino group attached to an / -propyl group, rather than to an isopropyl one, of the side chain. The actual synthesis of (32) is typical of the compounds in this class (37). 

Diphenhydramine [58-73-1] (55) was originally developed as an antihistamine and was first used clinically for this purpose in 1946 (see HiSTAMlNE AND HISTAMINE antagonists). In addition to this primary effect, however, central antitussive activity has also been demonstrated in animals (75,76) and in humans (77). Its antitussive activity is about half that of codeine. Drowsiness is the most frequent side effect. Diphenhydramine can be prepared as follows (78) ... 

FIGURE 9.20 Design of multiple ligancl activity, (a) Dual histamine HI receptor and leukotriene receptor antagonist incorporating known antihistaminic properties of cyproheptadine and LTD4. (b) Joint ACE/NEP inhibitor formed from incorporating similarities in substrate structures for both enzymes. From [57],... 

Among the antianaphylactic drugs, epinephrine (adrenaline) is the essential substance. In the acute treatment of the anaphylaxis in addition to the classical ABC (airway, breathing, circulation) rule for cardiopulmonary resuscitation [26, 27], one can apply the AAC rule (antigen off, adrenaline, cortisone) [18], Other drugs playing a role in the treatment of anaphylaxis include antihistamines (Hi-antagonists). 

Histamine H,-antagonists For intravenous infusion diphenhydramine, dimetindene and ciemastine are avaiiabie. There are no controiied studies for the new non-sedating antihistamines in the treatment of anaphyiaxis... 

Histamine Hj-antagonists such as cimetidine or ranitidine can be heipfu when combined with H,-antihistamines... 

The belief that histamine (HT) has a central effect stems from the knowledge that all the classical antihistamines (Hi receptor antagonists) used to treat allergic reaction, such as hay fever, caused marked sedation if, like mepyramine and promethazine, they can cross the blood-brain barrier, but fail to do so if, like terfenedine and cetirizine, they do not. 

Histamine receptors were first divided into two subclasses Hi and H2 by Ash and Schild (1966) on the basis that the then known antihistamines did not inhibit histamine-induced gastric acid secretion. The justification for this subdivision was established some years later when Black (see Black et al. 1972) developed drugs, like cimetidine, that affected only the histamine stimulation of gastric acid secretion and had such a dramatic impact on the treatment of peptic ulcers. A recently developed H2 antagonist zolantidine is the first, however, to show significant brain penetration. A further H3 receptor has now been established. It is predominantly an autoreceptor on histamine nerves but is also found on the terminals of aminergic, cholinergic and peptide neurons. All three receptors are G-protein-coupled but little is known of the intracellular pathway linked to the H3 receptor and unlike Hi and H2 receptors it still remains to be cloned. Activation of Hi receptors stimulates IP3 formation while the H2 receptor is linked to activation of adenylate cyclase. 

Although histamine has mixed excitatory and inhibitory effects on central neurons, those antihistamines (Hi-receptor antagonists) that enter the brain produce sedation this indicates that the predominant overall effect of histamine is excitatory. The preferred explanation for this rests on evidence that histaminergic neurons in the posterior hypothalamus are active in waking and silent in deep SWS and REM sleep. 

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