Analysis of the dose-response relationship of histamine and N tau-methylhistamine

The isolated stomach preparation of the mouse: a physiological unit for pharmacological analysis

Although oxyntic cell secretion can be studied at many organisation levels between isolated cell suspensions and non-invasive techniques in animals, the isolated, lumen-perfused, stomach preparation of the mouse represents a hierarchical level which eliminates extrinsic regulatory influences but retains all the cellular architecture known to be necessary for physiological responses and so can be defined as the physiological unit of acid secretion. The feeding pattern before and the distending pressure during an experiment have been identified as the main determinants of basal secretion: the combination of an intragastric pressure of 12 cmH2O and the fasted state generated a stable basal secretion over 2 h providing a satisfactory basis for bioassays. Basal acid secretion was lowered by treatment with omeprazole and sodium thiocyanate but not with tetrodotoxin, N-methylatropine or tiotidine, suggesting that basal secretion does not involve nervous stimulation or the local release of histamine under these experimental conditions. The improved assay permitted the full characterization of cumulative agonist concentration-effect curves in single stomach preparations to histamine, 5-methylfurmethide, pentagastrin and isobutyl-methylxanthine. Interestingly, pentagastrin produced sustained stimulation of gastric acid secretion under conditions when there was no pharmacological evidence that histamine secretion was taking place. This finding is discussed in relation to the role of histamine in the control of gastric acid secretion.

Further evidence that histamine in hippocampus affects the exploratory behavior in the rat

The effect of histamine (HA) and 3-methyl-histamine (3-MHA) in the hippocampus on hole-board behavior was studied. Male rats were microinjected stereotaxically into the hippocampus with 1 microliter of saline solution containing 9, 45 or 90 nMol of HA or 3-MHA. Five min later, all rats were tested for 5 min in a hole-board and locomotor, rearing, grooming and head-dipping activities were measured by direct observation. HA inhibited rearing and grooming at all the doses used but it affected locomotor activity only at 45 and 90 nMol doses. There was no effect on head-dipping behavior. 3-MHA instead increased locomotor and head-dipping activities at all the doses used and it did not change rearing and grooming. The present results give a further support for a physiological participation of HA in the hippocampus.

Operational models of pharmacological agonism

The traditional receptor-stimulus model of agonism began with a description of drug action based on the law of mass action and has developed by a series of modifications, each accounting for new experimental evidence. By contrast, in this paper an approach to modelling agonism is taken that begins with the observation that experimental agonist-concentration effect, E/[A], curves are commonly hyperbolic and develops using the deduction that the relation between occupancy and effect must be hyperbolic if the law of mass action applies at the agonist-receptor level. The result is a general model that explicitly describes agonism by three parameters: an agonist-receptor dissociation constant, KA; the total receptor concentration, [R0]; and a parameter, KE, defining the transduction of agonist-receptor complex, AR, into pharmacological effect. The ratio, [R0]/KE, described here as the 'transducer ratio', tau, is a logical definition for the efficacy of an agonist in a system. The model may be extended to account for non-hyperbolic E/[A] curves with no loss of meaning. Analysis shows that an explicit formulation of the traditional receptor-stimulus model is one particular form of the general model but that it is not the simplest. An alternative model is proposed, representing the cognitive and transducer functions of a receptor, that describes agonist action with one fewer parameter than the traditional model. In addition, this model provides a chemical definition of intrinsic efficacy making this parameter experimentally accessible in principle. The alternative models are compared and contrasted with regard to their practical and conceptual utilities in experimental pharmacology.

Specific binding of [3H]mepyramine to histamine H1-receptors in vascular smooth muscle membranes

The antagonist-sensitive binding of [3H]mepyramine to beef aortic membranes was as expected for binding to histamine H1-receptors. [3H]mepyramine binds rapidly and in saturable fashion to the specific receptor sites, specific binding reaching equilibrium in 3 min at 37 degrees C. SCATCHARD's analysis of the binding data gave a dissociation constant of 3.0 nM for the radioligand-receptor complex and maximal number of binding sites: 31 fmol/mg protein. In the competition studies histamine H1-antagonists are more potent inhibitors of radioligand binding than H2-antagonist. They inhibit [3H]mepyramine binding in the following order: mepyramine greater than triprolidine greater than promethazine much greater than cimetidine. Binding data are in correlation with the previous pharmacological studies.