Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.1.8 (cholinesterase)
 12,691 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cholinomimetic activity of Cimetidine and Ranitidine has been demonstrated by several authors. In the aim to better understand the phenomenon, we analyse the miniature end-plate current decay time. The prolongation of the decay phase of the synaptic current induced by the "selective" H2-antagonist Ranitidine, and to a lesser extent and at higher concentrations by Cimetidine, resembles that of the cholinesterase inhibitors. These agents usually prolong the quantal conductance change having little or no effect on the channel lifetime. The results of our previous experiments, which data were obtained by analyzing the "voltage" events, either spontaneous or evoked, of a classic frog preparation, showed a marked alteration of the temporal parameters. These effects, obtained at higher drug concentrations than those used in the present work, are now better defined by deriving extracellularly the "current" events. The results are also compared with those obtained by assaying the cholinesterase inhibitor Eserine, under the same experimental conditions.
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PMID:A further study on the kinetics of the subcellular current events at the mouse end-plate in the presence of cimetidine and ranitidine. 243 8

The effects of histamine H2-receptor antagonists on acetylcholinesterase and pseudocholinesterase activity were studied. All H2-antagonists tested inhibited both enzyme activities dose-dependently. The potency of inhibitory activity of H2-antagonists on acetylcholinesterase estimated from median inhibitory dose were in the following order of decreasing activity: ranitidine greater than TZU-0460 greater than cimetidine greater than YM-11170, whereas that on pseudocholinesterase were TZU-0460 greater than ranitidine greater than cimetidine greater than YM-11170. As the effects derived from the inhibition of acetylcholinesterase by H2-antagonists may affect intestinal motility, we studied ileal muscle contractions. Ranitidine had the most potent stimulating effect on contraction, the pattern of which was similar to physostigmine and was blocked by atropine and morphine. YM-11170 had a weak action on muscle contraction and cholinesterase activities.
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PMID:Cholinergic effects of histamine-H2 receptor antagonists partly through inhibition of acetylcholinesterase. 287 96

Many studies have demonstrated that histamine 2 receptor antagonists (H2RA) have in vitro anticholinesterase effects, but discrepancies about type and potency of this inhibitory effect exist among published results. Moreover, cholinesterase inhibition has not been shown in patients receiving H2RA. These discrepancies led us to study the in vitro antibutyryl- and in vitro antiacetylcholinesterase activities of ranitidine, cimetidine, nizatidine comparatively to pyridostigmines. Plasma cholinesterase activity (PCEA), erythrocyte cholinesterase activity (ECEA) and plasma ranitidine levels were measured in six patients before and during continuous IV infusion (150 or 200 mg/d) of ranitidine. Our in vitro results confirm the weak anticholinesterase activity of H2RA. Ranitidine is the most potent inhibitor of butyrylcholinesterase (Ki = 61 microM). Ranitidine and nizatidine are the most potent inhibitors of acetylcholinesterase (Ki' = 2.1 microM, Ki' = 5.1 microM, respectively) but one thousand times less effective than pyridostigmine (Ki = 0.003 microM). The results in patients show no statistically significant difference between PCEA and ECEA measured before and during ranitidine infusion (plasma ranitidine levels between 0.31 and 1.25 microM).
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PMID:Inhibition of cholinesterases by histamine 2 receptor antagonist drugs. 809 33

Weak and reversible inhibitors of cholinesterase, when coadministred in excess with a more potent inhibitor such as organophosphates, can act in a protective manner. Ranitidine (RAN) is a clinically widely used histamine type 2 (H2) receptor blocker. Ranitidine is also the most potent inhibitor of acetylcholinesterase among H2 blockers (inhibitory constant K in the low micromolar range) but roughly three orders of magnitude less potent than paraoxon. This study evaluates RAN-conferred protection in acute high-dose organophosphate (paraoxon, POX) exposure in rats in direct comparison with the therapeutic gold-standard pralidoxime (PRX). Group 1 received 1 microM POX, group 2 received 50 microM RAN, group 3 received 50 microM PRX, group 4 received 1 microM POX + 50 microM RAN and group 5 received 1 microM POX + 50 microM PRX. All substances were applied intraperitoneally. The animals were monitored for 48 h and mortality was recorded at 30 min and 1, 2, 3, 4, 24 and 48 h. Blood was taken for red blood cell acetylcholinesterase (RBC-AChE) measurements at baseline, 30 min and 24 and 48 h. Mortality occurred mainly in the fi rst 30 min after POX administration, with minimal changes occurring thereafter. Mortality (in %) at 30 min in groups 1, 4 and 5 was 52 +/- 18, 37 +/- 20 and 17 +/- 18, respectively, and mortality at 48 h was 59 +/- 12, 39 +/- 20 and 28 +/- 20, respectively. The RBC-AChE activities (in % of baseline values) at 30 min in groups 1, 4 and 5 were 18 +/- 16, 47 +/- 23 and 48 +/- 20, respectively. At 24 h the values were 46 +/- 16, 65 +/- 24 and 86 +/- 17, respectively, and at 48 h the values were 71 +/- 19, 78 +/- 21 and 110 +/- 27, respectively. Coadministration of PRX significantly decreases mortality in the described model at all points in time. Coadministration of RAN statistically significantly decreases mortality at 24 and 48 h. The extent of protection conferred by RAN is less (but not statistically significantly so) than that conferred by the gold-standard PRX. Coadministration of PRX statistically significantly increases RBC-AChE activities in the described model at all points in time. Ranitidine confers a statistically significant protection for the enzyme at 30 min only. We conclude that RAN is potentially of clinical use in reducing mortality in acute high-dose organophosphate exposure. Further studies involving different organophosphates and dosages, as well as different animal species, will be needed both to con fi rm these initial findings and to address the issue of the optimal timing for RAN preadministration.
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PMID:Protective agents in acute high-dose organophosphate exposure: comparison of ranitidine with pralidoxime in rats. 1566 39