Resolved pyrrolidine, piperidine, and perhydroazepine analogues of the muscarinic agent N-methyl-N-(1-methyl-4-pyrrolidino-2-butynyl)acetamide.

A series of conformationally restricted analogues of the partial muscarinic agonist N-methyl-N-(1-methyl-4-pyrrolidino-2-butynyl)acetamide (BM 5; 1) was synthesized. Three of the racemic derivatives were resolved into the enantiomers. The compounds were investigated for muscarinic and antimuscarinic activity in the isolated guinea pig ileum. They were found to be fairly potent muscarinic antagonists or weak partial agonists. The new compounds were either equally or less potent than 1 in inhibiting (-)-[3H]-N-methylscopolamine binding in homogenates of the rat cerebral cortex. Thus, structural modifications to 1 in which the amide moiety and the methyl group in the butynyl chain have been joined to form a six- or seven-membered ring preserve affinity but abolish efficacy. The R enantiomers were found to have 14-79 times higher affinity to ileal muscarinic receptors than the respective antipodes. The enantiomeric affinity ratios were nearly identical in both preparations studied. As suggested by molecular mechanics calculations, the difference in affinity between the five-membered and the six- and seven-membered ring analogues may be rationalized in conformational terms.

Calcium antagonism and structure-affinity relationships of terfenadine, a histamine H1 antagonist, and some related compounds.

Calcium channel affinity of terfenadine and its optical isomers was determined by the displacement of [3H]nitrendipine on rat cerebral cortex membranes. Terfenadine showed a pKd of 6.36 +/- 0.03 whereas its R(+)-isomer (VUF4567) had a pKd value of 6.39 +/- 0.03 and the S(-)-isomer (VUF4568) had a pKd of 6.40 +/- 0.04. The same affinity between the enantiomers suggests that the binding domain on the membrane is not sterically restricted towards the part of the molecule in which the chiral centre is present. The characteristics of terfenadine in regulating [3H]nitrendipine binding were similar to those of some other diphenyl-alkylamine type calcium antagonists. It allosterically altered the binding affinity for nitrendipine and acted at the same site linked to the calcium channel as gallopamil. A structure-affinity relationship among a group of terfenadine analogues is discussed.

Radiolabelled calmodulin ligands: their low affinity and high lipophilicity may lead to artefacts in binding studies.

In order to characterize the interaction site of a series of putative calmodulin antagonists of the diphenylalkylamine type with calmodulin (CaM), a representative member of this chemical class was radiolabelled. The binding of the selected compound, [3H]-VUF 4576, to calmodulin was studied according to a recently described technique using CaM agarose. However, some peculiar results were obtained: the tight binding of [3H]-VUF 4576 increased in presence of cold VUF 4576, resulting in a high non-specific binding. The unexpected results could readily be explained by a high binding capacity of the labelled compound and the cold ligands to the walls of the test tubes used. Such results were also found when [3H]-chlorpromazine ([3H]-CPZ) was applied. In literature comparable findings have been published. To explain such results the influence of positive cooperativity or irreversible binding has been suggested. We suppose that not only in our study, but also in other published investigations, binding to glass of the radioligand and/or the cold compounds may have had a strong influence. We suggest, therefore, that care should be taken in interpreting non-classical displacement data obtained with ligands which combine a rather low affinity and a high degree of lipophilicity, not only for binding to calmodulin, but for other systems as well.

A novel class of cholinergic agents structurally related to 2-morpholinol.

A series of esters and ethers of N-alkylmorpholin-2-ols, and their methiodides, which can be considered cyclic analogues of acetylcholine, were synthesized. The amines were obtained by acylation or etherification of morpholinols with the appropriate acyl chlorides and alcohols. All compounds were tested for their ability to interact with the muscarinic receptor M2 (guinea-pig atria) or M3 (rat ileum and urinary bladder) subtype. Some compounds, although endowed with relatively low potency, proved interesting for their organ selectivity. Some considerations on the structure-activity relationship are made and the results obtained with reference agonists and antagonists are also shown.

Chiral manipulation of drug selectivity: studies on a series of terfenadine-derived dual antagonists on H1-receptors and calcium channels.

A series of terfenadine derivatives were evaluated for enantioselectivity on histamine H1-receptors and calcium channels. Whereas H1-receptors are only sterically discriminative against the benzhydryl part of the molecules, calcium channels showed enantioselectivity to either the phenylbutyl part or the benzhydryl part provided that an appropriate lipophilicity is preserved at the chiral site. It is speculated that the hydrophilicity of the butanol moiety is responsible for the lack of stereoselectivity of terfenadine enantiomers since it drives the side chain out of the stereoselective site of calcium channels, which are lipophilic. In four different test systems, (guinea-pig ileum, guinea-pig lung membranes, rat aorta and rat cortex membranes), this series of compounds generally showed about 10 times higher activity on H1-receptors than on calcium channels. By introducing a chiral center in the different parts of the molecule we were able to increase the selectivity of an enantiomer VUF4648 to calcium channels.

In vitro and in vivo characterization of a calcium modulator of the diphenylalkylamine type with selective coronary dilatory properties.

UNLABELLED: VUF 8929 (N-¿2-[bis(p-fluorophenyl)methoxy]ethyl¿-(2-phenyl)ethylamine maleate, CAS 140890-71-7) is a diphenylalkylamine derivative structurally related to prenylamine. The calcium antagonistic properties of this compound have been studied in in vitro and in vivo systems. VUF 8929 has affinity for the voltage-operated calcium channel. Its pKD for the displacement of [3H]nitrendipine bound to cerebral rat cortex is 6.27 (+/- 0.17). The compound influences the [3H]nitrendipine binding through an allosteric interaction with a site adjacent to the dihydropyridine binding site. Competitive experiments with the additional presence of the phenylalkylamine gallopamil showed that this allosteric site is a property common to diphenyl- and phenylalkylamines. It was further observed that VUF 8929 has a high affinity for calmodulin as it shows high potency in inhibiting the calmodulin mediated activation of PDE. The inhibition of K+ (IC50 0.5 mumol/l)- and noradrenaline (IC50 1.3 mumol/l)-induced contractions of rabbit aorta rings was in the same concentration range as found for the calmodulin inhibitory activity. In vitro platelet aggregation was also inhibited in the same concentration range when washed platelets were used. Thus calmodulin antagonism may contribute to the observed effects on aorta ring contractions and platelets aggregation. Platelet aggregation, however, in media in which albumin was added or in platelet rich plasma was not affected. It is assumed that due to the high lipophilicity, common to many diphenylalkylamines, VUF 8929 has a strong binding to plasma proteins. This may also explain why orally administered VUF 8929 did not affect the alpha 2-induced pressor response in pithed rats and the ex vivo collagen induced aggregation response. The haemodynamic profile in anaesthetized dogs showed that intravenous injected VUF 8929 reduced the workload of the heart while coronary blood flow increases at a dose of 0.3 mg/kg. Reversible occlusion of the coronary artery, which leads to S-T segment elevation and local venous acidosis, were reduced by VUF 8929 indicating that the compound has anti-ischaemic properties. IN CONCLUSION: VUF 8929 is a calcium antagonist which has anti-ischaemic properties, reduces the workload of the heart and increases coronary flow. Due to these properties VUF 8929 is a potential cardioprotective agent.

Novel derivatives of 3-(dipropylamino)chroman. Interactions with 5-HT1A and D2A receptors.

Novel 8-aryl and 8-aroyl substituted derivatives of 3-(dipropylamino)chroman are described. The compounds have been prepared by a palladium catalyzed reaction of iodoarenes and a stannylated derivative of [eta6-3-(dipropylamino)chroman]Cr(CO)3. Several of the compounds have high affinity for 5-HT1A receptors whereas the affinity for D2A receptors is lower, the 8-arylated derivatives being slightly more potent than the 8-aroylated analogues.