The antiemetic activity, gastric motor activity, and dopamine receptor effects of metoclopramide, dazopride, and sulpiride were assessed to establish if enhancement of gastric motility or antagonism of central dopamine receptors is the predominant action for drug-induced suppression of cisplatin-induced emesis. Emesis produced in dogs by cisplatin is antagonized by metoclopramide and dazopride. The antiemetic actions of metoclopramide and dazopride are associated with their ability to enhance gastric motor activity. Dazopride, unlike metoclopramide, has minimal dopamine receptor antagonist properties. Sulpiride is a potent dopamine receptor antagonist; however, it had no effect on the stomach and was ineffective in suppressing cisplatin-induced emesis.
All of the optical isomers of the muscarinic antagonists 3-(1-azabicyclo[2.2.2]octyl) alpha-hydroxy-alpha,alpha-diphenylacetate (3-quinuclidinyl benzilate, QNB, 1) 3-(1-azabicyclo[2.2.2]octyl) xanthene-9-carboxylate (3-quinuclidinyl xanthene-9-carboxylate, QNX, 2), and 3-(1-azabicyclo[2.2.2]ocytl) alpha-hydroxy-alpha-phenylpropionate (3-quinuclidinyl atrolactate, QNA, 3) were prepared and studied in binding and functional assays. In all instances the esters of (R)-1-azabicyclo[2.2.2]octan-3-ol (3-quinuclidinol) had greater affinity for the M1 and M2 subpopulations of muscarinic acetylcholine receptors (M-AChRs) than did their S counterparts. The enantiomers of QNB (1), QNX (2), and QNA (3) in which the alcoholic portion of the muscarinic antagonists had the S absolute stereochemistry were more selective for the M1-AChRs. This selectivity was modulated by the nature and, in the case of QNA, the chirality of the acid portion. The most potent isomer in the series was (R)-QNB. In the QNA series the diastereoisomer with the absolute R configuration of the alcohol (a) and the R configuration of the acid (b) was the most potent in both binding and functional assays whereas (Sa,Rb)-QNA was the most selective for the M1 subtype of M-AChRs. In fact, the latter diastereomer was as potent and selective as pirenzepine for M1-AChRs.
Radioligand receptor binding has been used extensively to identify and characterize a host of receptors and enzymes targeting virtually every therapeutic area. Many drug discovery programs have been based on the utilization of radioligand receptor binding technology to identify lead compounds which interact with receptors likely to be important in neuronal, immunological, gastrointestinal, and cardiovascular function/dysfunction. There are several obvious advantages to using in vitro receptor binding as a first level screen when compared to in vivo pharmacometric screens. Scientifically, the structure activity data generated in binding assays is a direct reflection of the ligand/receptor interaction minus the complications which result from secondary events, bioavailability, and pharmacodynamic issues. Technically, the binding studies require only a small amount of test compound (< or = 1 mg), while whole animal studies routinely need gram quantities. Similarly, only a small amount of tissue is required, compared with the cost of purchase and maintenance of live animals for in vivo screening. Supply and labor costs are drastically reduced due to the limited volume and test tube based technology of receptor binding. For these reasons receptor binding assays have been utilized with considerable success to discover site specific lead compounds in virtually every therapeutic area.
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