Losartan metabolite EXP3179 is a unique blood pressure-lowering AT1R antagonist with direct, rapid endothelium-dependent vasoactive properties.

BACKGROUND AND PURPOSE: Losartan is an anti-hypertensive angiotensin II (ANGII) type 1 receptor (AT1R) blocker (ARB) with many unexpected therapeutic properties, even in non-blood pressure (BP)-related diseases. Administered as a prodrug, losartan undergoes serial metabolism into EXP3179, a metabolite alleged to lack AT1R-blocking properties, and EXP3174, the dominant AT1R antagonist. Having observed that losartan can decrease vascular tone in mice with low AT1R expression and inhibit Marfan aortic widening at very high doses, we investigated whether EXP3179 may have unique, AT1R-independent effects on vascular tone and endothelial function. EXPERIMENTAL APPROACH: We compared the AT1R blocking capabilities of EXP3179 and EXP3174 using AT1R-expressing cell lines. Their BP lowering and vasoactive properties were studied in normal, hypertensive and transgenic rodents, and ex vivo wire myography. KEY RESULTS: We observed that both EXP3179 and EXP3174 can fully block (100%) AT1R signaling in vitro and significantly decrease BP in normotensive and spontaneously hypertensive rats. Only EXP3179 prevented PE-induced contraction by up to 65% (p < 0.01) in L-NAME and endothelium removal-sensitive fashion. Use of transgenic mice revealed that these effects involve the eNOS/caveolin-1 axis and the endothelium-dependent hyperpolarization factor (EDHF). CONCLUSION AND IMPLICATIONS: We provide direct structure-activity evidence that EXP3179 is a BP-lowering AT1R blocker with unique endothelial function-enhancing properties not shared with losartan or EXP3174. The major pharmacological effects of losartan in patients are therefore likely more complex than simple blockade of AT1R by EXP3174, which helps rationalize its therapeutic and prophylactic properties, especially at very high doses. Reports relying on EXP3179 as an AT1R-independent losartan analogue may require careful re-evaluation.

Molecular charge associated with antiarrhythmic actions in a series of amino-2-cyclohexyl ester derivatives.

A series of amino-2-cyclohexyl ester derivatives were studied for their ion channel blocking and antiarrhythmic actions in the rat and a structure-activity analysis was conducted. The compounds are similar in chemical structure except for ionizable amine groups (pK values 6.1-8.9) and the positional arrangements of aromatic naphthyl moieties. Ventricular arrhythmias were produced in rats by coronary-artery occlusion or electrical stimulation. The electrophysiological effects of these compounds on rat heart sodium channels (Nav1.5) expressed in Xenopus laevis oocytes and transient outward potassium currents (Kv4.3) from isolated rat ventricular myocytes were examined. The compounds reduced the incidence of ischemia-related arrhythmias and increased current threshold for induction of ventricular fibrillo-flutter (VFt) dose-dependently. As pK increased compounds showed a diminished effectiveness against ischemia-induced arrhythmias, and were less selective for ischemia- versus electrically-induced arrhythmias. Where tested, compounds produced a concentration-dependent tonic block of Nav1.5 channels. An increased potency for inhibition of Nav1.5 occurred when the external pH (pHo) was reduced to 6.5. Some compounds inhibited Kv4.3 in a pH-independent manner. Overall, the differences in antiarrhythmic and ion channel blocking properties in this series of compounds can be explained by differences in chemical structure. Antiarrhythmic activity for the amino-2-cyclohexyl ester derivatives is likely a function of mixed ion channel blockade in ischemic myocardium. These studies show that drug inhibition of Nav1.5 occurred at lower concentrations than Kv4.3 and was more sensitive to changes in the ionizable amine groups rather than on positional arrangements of the naphthyl constituents. These results offer insight into antiarrhythmic mechanisms of drug-ion channel interactions.

David J. Triggle: Medicinal chemistry, to pharmacology, calcium channels, and beyond.

David Triggle's scientific career began as a chemist, went through medicinal chemistry into pharmacology, and finally on to somewhat more philosophical interests in later years. It was a career marked by many contributions to all of those aspects of science. Chief amongst his many contributions, in addition to those in medicinal chemistry, was his work on the drugs known as calcium ion channel blockers or (calcium antagonists). In the calcium ion channel field he was a particularly instrumental figure in sorting out the mechanisms, actions and roles of the class of calcium channel blockers, known chemical and pharmacologically as the dihydropyridines (DHPs) in particular, as well as other calcium blockers of diverse structures. During the course of a long career, and extensive journeys into medicinal chemistry and pharmacology, he published voluminously in terms of papers, reviews, conference proceedings and books. Notably, many of his papers often had limited authorship where, as senior author it reflected his deep involvement in all aspects of the reported work. His work always helped clarify the field while his incisive reviews, together with his role in coordinating and running scientific meetings, were a great help in clarifying and organizing various fields of study. He has had a long and illustrious career, and is wellknown in the world of biomedical science; his contributions are appreciated, and well recognized everywhere. The following article attempts to chart a path through his work and contributions to medicinal chemistry, pharmacology, science, academia and students.

An examination of the cardiac actions of PD117,302, a κ-opioid receptor agonist.

These studies examined the opioid and non-opioid in vivo and in vitro actions of PD117,302 (((±)-trans-N-methyl-N-[2-(l-pyrrolidinyl)-cyclohexyl]benzo[b]thiophene-4-acetamide), a kappa (κ)-opioid receptor agonist. PD117,302 selectively labeled the κ-opioid receptor in guinea pig cerebellar membranes and in mice the ED50 for analgesia was 2.3µmol/kg. A non opioid cardiovascular assessment of PD117,302 showed that it dose-dependently increased left-ventricular peak systolic pressure in rat isolated perfused hearts but reduced heart rate and blood pressure in anaesthetized rats. Over the concentration range 0.3-30µM in vitro, and dose-range 0.25-4µmol/kg in vivo, PD117,302 dose-dependently prolonged the P-R interval, QRS width and Q-T interval of the rat heart ECG. Naloxone (either 1µM or 8µmol/kg) did not antagonize the observed ECG effects of PD117,302. Cardiac electrical stimulation studies in anesthetized rats showed that threshold currents for capture and fibrillation were increased and effective refractory period (ERP) prolonged. In rats subject to coronary artery occlusion PD117,302 reduced arrhythmia incidence. Intracellular cardiac action potential studies qualified the ECG changes produced by PD117,302 such that there was a dose-dependent reduction in the maximum rate of depolarization of phase 0 (dV/dtmax) and prolongation of the action potential duration (APD). In isolated cardiac myocytes PD117,302 dose-dependently (1-100µM) reduced peak Na(+) current and produced a hyperpolarizing shift in the inactivation curve. Transient outward and sustained outward K(+) currents were blocked by PD117,302. Thus, the ECG changes and antiarrhythmic effects observed in vivo result from direct blockade of multiple cardiac ion channels.

The Lambeth Conventions (II): guidelines for the study of animal and human ventricular and supraventricular arrhythmias.

The 'Lambeth Conventions' is a guidance document, written in 1987 (Walker et al., 1988), intended to be of practical value in the investigation of experimental arrhythmias induced by ischaemia, infarction, and reperfusion. This is an update, expanded to include guidance on the study of supraventricular arrhythmias, drug-induced arrhythmias, heritable arrhythmias, and advances in our knowledge in core areas since 1987. We have updated the guidance on the design and execution of experiments and the definition, classification, quantification, and analysis of all types of arrhythmias. Investigators are encouraged to adopt the conventions and test their validity in the hope that this will improve uniformity and interlaboratory comparisons, aid clinical research, facilitate antiarrhythmic drug discovery and safety assessment, and improve antiarrhythmic drug deployment for different cardiac conditions. We note that there is a gap between some definitions proposed here and their conventional clinical counterparts, and encourage the research necessary to bridge that translational gap. A web link offers the chance to vote and comment on the new conventions (https://bscr.wufoo.com/forms/z7x0x5/).

Efficacy and safety of RPL554, a dual PDE3 and PDE4 inhibitor, in healthy volunteers and in patients with asthma or chronic obstructive pulmonary disease: findings from four clinical trials.

BACKGROUND: Many patients with asthma or chronic obstructive pulmonary disease (COPD) routinely receive a combination of an inhaled bronchodilator and anti-inflammatory glucocorticosteroid, but those with severe disease often respond poorly to these classes of drug. We assessed the efficacy and safety of a novel inhaled dual phosphodiesterase 3 (PDE3) and PDE4 inhibitor, RPL554 for its ability to act as a bronchodilator and anti-inflammatory drug. METHODS: Between February, 2009, and January, 2013, we undertook four proof-of-concept clinical trials in the Netherlands, Italy, and the UK. Nebulised RPL554 was examined in study 1 for safety in 18 healthy men who were randomly assigned (1:1:1) to receive an inhaled dose of RPL554 (0·003 mg/kg or 0·009 mg/kg) or placebo by a computer-generated randomisation table. Subsequently, six non-smoking men with mild allergic asthma received single doses of RPL554 (three received 0·009 mg/kg and three received 0·018 mg/kg) in an open-label, adaptive study, and then ten men with mild allergic asthma were randomly assigned to receive placebo or RPL554 (0·018 mg/kg) by a computer-generated randomisation table for an assessment of safety, bronchodilation, and bronchoprotection. Study 2 examined the reproducibility of the bronchodilator response to a daily dose of nebulised RPL554 (0·018 mg/kg) for 6 consecutive days in a single-blind (patients masked), placebo-controlled study in 12 men with clinically stable asthma. The safety and bronchodilator effect of RPL554 (0·018 mg/kg) was assessed in study 3, an open-label, placebo-controlled crossover trial, in 12 men with mild-to-moderate COPD. In study 4, a placebo-controlled crossover trial, the effect of RPL554 (0·018 mg/kg) on lipopolysaccharide-induced inflammatory cell infiltration in induced sputum was investigated in 21 healthy men. In studies 3 and 4, randomisation was done by computer-generated permutation with a block size of two for study 3 and four for study 4. Unless otherwise stated, participants and clinicians were masked to treatment assignment. Analyses were by intention to treat. All trials were registered with EudraCT, numbers 2008-005048-17, 2011-001698-22, 2010-023573-18, and 2012-000742-34. FINDINGS: Safety was a primary endpoint of studies 1 and 3 and a secondary endpoint of studies 2 and 4. Overall, RPL554 was well tolerated, and adverse events were generally mild and of equal frequency between placebo and active treatment groups. Efficacy was a primary endpoint of study 2 and a secondary endpoint of studies 1 and 3. Study 1 measured change in forced expiratory volume in 1 s (FEV1) and provocative concentration of methacholine causing a 20% fall in FEV1 (PC20MCh) in participants with asthma. RPL554 produced rapid bronchodilation in patients with asthma with an FEV1 increase at 1 h of 520 mL (95% CI 320-720; p<0·0001), which was a 14% increase from placebo, and increased the PC20MCh by 1·5 doubling doses (95% CI 0·63-2·28; p=0·004) compared with placebo. The primary endpoint of study 2 was maximum FEV1 reached during 6 h after dosing with RPL554 in patients with asthma. RPL554 produced a similar maximum mean increase in FEV1 from placebo on day 1 (555 mL, 95% CI 442-668), day 3 (505 mL, 392-618), and day 6 (485 mL, 371-598; overall p<0·0001). A secondary endpoint of study 3 (patients with COPD) was the increase from baseline in FEV1. RPL554 produced bronchodilation with a mean maximum FEV1 increase of 17·2% (SE 5·2). In healthy individuals (study 4), the primary endpoint was percentage change in neutrophil counts in induced sputum 6 h after lipopolysaccharide challenge. RPL554 (0·018 mg/kg) did not significantly reduce the percentage of neutrophils in sputum (80·3% in the RPL554 group vs 84·2% in the placebo group; difference -3·9%, 95% CI -9·4 to 1·6, p=0·15), since RPL554 significantly reduced neutrophils (p=0·002) and total cells (p=0·002) to a similar degree. INTERPRETATION: In four exploratory studies, inhaled RPL554 is an effective and well tolerated bronchodilator, bronchoprotector, and anti-inflammatory drug and further studies will establish the full potential of this new drug for the treatment of patients with COPD or asthma. FUNDING: Verona Pharma.

The major impacts of James Black's drug discoveries on medicine and pharmacology.

James Black has many claims to pharmacological fame as the creator of two new classes of drugs (beta-blockers and H2 antihistamines) and as a tireless innovator in drug discovery strategies and analytical procedures. The latter attributes in particular assisted Black in the invention of the prototypes for the two major classes of drugs for which he is best known, propranolol and cimetidine. The clinical impact of these drugs on both morbidity and mortality has been profound. In addition, the application of his analytical approach to drug discovery and pharmacology led others in the field to create many other new classes of drugs. Shortly before he died in 2010, Black wrote a retrospective review of his research career that provides insight into his innovative thinking and career success. This overview affords readers a very personal picture of the man, his ideas and his contributions.

Differential responses to various classes of drugs in a model of allergic rhinitis in guinea pigs.

Different drugs from various pharmacological classes were compared for their ability to protect against the nasal effects of acute allergen challenge in a guinea pig model. In the model, sneezing and nose rubbing were recorded after an initial allergen challenge in guinea pigs previously sensitized to egg albumin. Four days later the same guinea pigs were re-challenged a second time when anesthetised. In these anaesthetized animals, nasal airway pressure, pulmonary inflation pressure and cellular infiltration into nasal lavage fluid were measured. The drug tested were autacoid antagonists (mepyramine--3mg/kg, cetirizine--3mg/kg and montelukast--10mg/kg), L-NAME (10 or 20mg/kg), heparin (20mg/kg) and dexamethasone (20mg/kg) given either intraperitoneally or intravenously; all were given shortly before challenge. Sneezing induced by allergen challenge was statistically significantly reduced by mepyramine, cetirizine and dexamethasone whereas only cetirizine reduced nose rubbing. Changes in nasal airway pressure due to allergen exposure were reduced by cetirizine, montelukast, L-NAME, and heparin, but not by mepyramine, nor dexamethasone. In the presence of L-NAME, nasal airway pressure actually changed in the opposite direction. Cellular infiltration, as assessed by cytometry in nasal lavage fluid 60min after acute allergen challenge, was reduced by montelukast and heparin but not by antihistamines, L-NAME nor dexamethasone. This pattern of effects of the drugs, given by doses and routes previously described in the literature as being effective was not completely consistent with expected responses. The lack of effect of dexamethasone probably reflects the fact that it was given acutely whereas in the clinic chronic administration is used. The two antihistamines were not identical in their actions, presumably reflecting the fact that cetirizine has therapeutic actions not entirely confined to blockade of H1 receptors. Montelukast has not been reported to have major effects on sneezing and itching in the clinic but reduces nasal obstruction (lower nasal airway pressure or nasal patency). Montelukast's effects on cellular infiltration indicate the possible involvement of leukotrienes. Heparin has actions on inflammatory cell infiltration. This could explain its profile of reducing both cellular infiltration, and increased nasal airway pressure.

Synthesis and biological studies of novel 2-aminoalkylethers as potential antiarrhythmic agents for the conversion of atrial fibrillation.

A series of 2-aminoalkylethers prepared as potential antiarrhythmic agents is described. The present compounds are mixed sodium and potassium ion channel blockers and exhibit antiarrhythmic activity in a rat model of ischemia-induced arrhythmias. Structure-activity studies led to the identification of three compounds 5, 18, and 26, which were selected based on their particular in vivo electrophysiological properties, for studies in two canine atrial fibrillation (AF) models. The three compounds converted AF in both models, but only compound 26 was shown to be orally bioavailable. Resolution of the racemate 26 into its corresponding enantiomers 40 and 41 and subsequent biological testing of these enantiomers led to the selection of (1S,2S)-1-(1-naphthalenethoxy)-2-(3-ketopyrrolidinyl)cyclohexane monohydrochloride (41) as a potential atrial selective antiarrhythmic candidate for further development.

Allergic rhinitis and its pharmacology.

The pathophysiology of allergic rhinitis and its drug treatment is reviewed. Special emphasis is placed upon potential new treatments. Allergic rhinitis is characterized by allergen(s), symptoms (sneezing, itching, rhinorrhea, nasal congestion and nasal hypersensitivity), and signs such as invasion of nasal mucosa by inflammatory cells. Such pathological changes are due to inflammatory responses mediated by way of allergen-immunoglobulin E (IgE)-cell complex formation. The complexity of the disease and the multiple pathways involved offer many targets for drug treatment, but to date no single drug is totally effective. This review summarizes the current knowledge of allergic rhinitis, its prevalence, pathophysiology and experimental and clinical treatments. In the search for new drugs, different experimental animal models of allergic rhinitis are required. As a result the models have also been reviewed. Furthermore, particular aspects of the pathophysiology of allergic rhinitis are discussed in greater detail including the immune cells involved in the mediation of the disease, chemical mediators, their actions, and the receptors on which they act. Therapy, particularly that with current drugs, targets many of the known mediators and some of the cellular processes with varying success. Other drugs, for example, vasoconstrictors given to reduce rhinorrhea, provide symptomatic relief by counteracting symptoms. Since the incidence of allergic rhinitis is prevalent and growing in many parts of the world and current treatments are not ideal, it is important to continue to study the pharmacology of this disease as part of a search for better drugs.

A comprehensive model of allergic rhinitis in guinea pigs.

INTRODUCTION: The economic and social impact of allergic rhinitis is substantial. The effectiveness of currently available medications is limited and therefore investigations for more effective drugs is essential. This study was intended to establish a model of allergic rhinitis in guinea pigs that can be utilized for further investigation of new drugs. METHODS: Male Dunkin Hartley guinea pigs were sensitized intranasally to, and challenged with, ovalbumin. Sneezing (SN) and nose rubbing (NR) response to allergen challenge were observed on day 21 post-initiation of sensitization in conscious guinea pigs. Nasal blockade (NB), leukocyte infiltration, and lung inflation pressure (LIP) were assessed in the same guinea pigs 23-28 days post-initiation of sensitization. A ventilator/flow method was used to measure NB and LIP. Leukocyte infiltration into nasal lavage fluid 60 min after challenge in the same animals was recorded as total and differential cell counts. RESULTS: Sensitized guinea pigs produced acute allergic responses after allergen challenge. This was characterized by increases in SN, NR, NB, and eosinophil infiltration. In addition, intranasal allergen challenge did not change lung inflation pressure. DISCUSSION: Allergen-induced rhinitis in guinea pigs resembles that in humans. The model reported in this study can be used to reflect the effectiveness of drugs currently used to treat allergic rhinitis and to investigate new potential drugs for the treatment of allergic rhinitis.

Mechanism of tissue-selective drug action in the cardiovascular system.

Analysis of the human genome project tells us that there may be as few as 3000 genes that are likely to be good drug targets. Although the number of targets is still very large, these data have been interpreted by some to mean that the pharmaceutical industry may someday run out of novel drug targets. Despite the doom and gloom of such analysis, there is considerable reason for optimism. Drugs may exhibit selectivity of action beyond that predicted by target expression alone. Drugs that act at a single molecular target may have very different pharmacology and, as a result, different therapeutic uses. Three well-characterized model systems are highlighted to illustrate this point. The first model system is exemplified by nifedipine and verapamil, both of which act on L-type calcium channels. Both drugs are used to treat hypertension, but only verapamil can be used to produce atrioventricular block in patients with atrial fibrillation. The second model system describes the therapeutic exploitation of unusual conditions that occur in the ischemic myocardium to produce drugs that are more effective for suppressing ischemia-induced arrhythmias. The third model system discusses the mechanisms through which phosphodiesterase-5 (PDE5) inhibitors act selectively to facilitate penile erection while having little effect in the non-penile vasculature that also expresses PDE5.

Block of NA+ and K+ currents in rat ventricular myocytes by quinacainol and quinidine.

1. The electrophysiological actions of quinacainol were investigated on sodium (I(Na)), transient outward (i(to)) and sustained-outward plateau (iKsus) potassium currents in rat isolated cardiac myocytes using the whole-cell patch-clamp technique and compared with quinidine. 2. Quinacainol blocked sodium currents in a concentration-dependent manner and with a potency similar to that of quinidine (mean (+/-SEM) EC50 50+/-12 vs 95+/-25 micromol/L for quinidine and quinacainol, respectively). However, quinacainol had a considerably prolonged onset and recovery from block compared with quinidine. 3. Neither quinacainol nor quinidine significantly changed the steady state voltage dependence of activation of sodium currents. Quinidine produced a hyperpolarizing shift in the voltage dependence for sodium current inactivation, but no such shift was observed with quinacainol at doses that produced a substantial current block. 4. Although quinacainol did not effectively block voltage-dependent potassium currents, even at concentrations as high as 1.5 mmol/L, quinidine, at a half-maximal sodium channel-blocking concentration, reduced peak i(to) current amplitude, increased the rate of inactivation of i(to) and blocked iKsus. 5. These results indicate that quinacainol, a quinidine analogue, blocks sodium currents in cardiac myocytes with little effect on i(to) or iKsus potassium currents, which suggests that quinacainol may be exerting class 1c anti-arrhythmic actions.

Effects of E4031 and quinidine on atrial and ventricular refractoriness in rabbits in vivo.

This study assessed the effects of E4031 and quinidine on refractoriness (ERP) in a new in vivo model in rabbits. Following sinoatrial (SAN) and atrioventricular node (AVN) ablation ERP was determined in atria and ventricles with the shortest S1-S2 interval eliciting a second electrogram defined as the ERP. The effects of E4031 and quinidine (dose ranges 1-8 micromol/kg) were compared. E4031 dose-dependently increased ERP. The maximum change from pre-drug values with E4031 was 27+/-8 msec (a 36+/-12% increase) at 2 Hz in atria and 51+/-9 msec (27+/-5%) at 2 Hz in ventricles. Negative frequency-dependence was observed only in ventricles. Quinidine dose-dependently increased ERP. The maximum increase for quinidine was 23+/-3 msec (28+/-4%) at 2 Hz in atria and 25+/-10 msec (22+/-10%) at 6 Hz in ventricles, but without frequency-dependence in either tissue. In comparison to E4031, quinidine produced smaller changes in ERP and showed minimal frequency dependence. Thus, the added presence of sodium blocking actions with quinidine did not produce greater effects on ERP than I(Kr) blockade alone with E4031. However, quinidine also blocks other potassium currents, such as Ito, and the degree of I(Kr) blockade with E4031 was probably greater than that with the same dose of quinidine. This model may have clinical utility for testing multi-ion channel blocking drugs.

Effects of flecainide on atrial and ventricular refractoriness in rabbits in vitro and in vivo.

This study compared the in vitro versus in vivo effects of flecainide on effective refractory period (ERP) in atrial and ventricular tissue in rabbits. Flecainide (a class 1c agent) was chosen, on the basis of its known pharmacological profile and antiarrhythmic actions, to provide a reference compound for investigating models that suitably predict the clinical effects of antiarrhythmics. The rabbit models used were those previously described by Lowe et al. (2002) and Leung et al. (2003). ERP was measured as the shortest S1-S2 interval that elicited a second contraction (in vitro) or electrogram (in vivo). Flecainide (1-10 microM) in vitro produced a concentration-dependent increase in ERP. The greatest drug-induced change from pre-drug values in vitro occurred with the highest concentration in atria and ventricles at 4 Hz. The change was 30+/-4 msec (33+/-7%) in atria versus 53+/-8 msec (46+/-10%) in ventricles. In vivo, flecainide (1 - 4 micromol/kg) dose-dependently increased atrial ERP at 2 and 6 Hz. The biggest change was 28+/-17 msec (29+/-16%). However, there was no effect at 4 Hz. In the ventricles, a dose-related increase in ERP was only seen at 4 Hz (26+/-6 msec). Flecainide showed no frequency dependence of action on ERP in any preparation. Flecainide produced adverse effects both in vitro and in vivo. A concentration and frequency-dependent negative inotropic effect was seen in vitro, and dose-related hypotension in vivo. The highest dose (8 micromol/kg i.v.) of flecainide was lethal. Flecainide produced the expected electrophysiological and toxicity profile, both in vitro and in vivo. Despite such findings, the drug is used to terminate and prevent atrial arrhythmias clinically. In conclusion our rabbit models for determining ERP may not be useful in predicting the clinical usefulness of a drug like flecainide.

Tedisamil and lidocaine enhance each other's antiarrhythmic activity against ischaemia-induced arrhythmias in rats.

1. Combinations of the action potential-widening drug tedisamil (Class III antiarrhythmic activity), and the inactivated state sodium channel blocker lidocaine (Class Ib antiarrhythmic activity) were assessed for antiarrhythmic actions in a rat model of ischaemia-induced arrhythmias and for electrophysiological actions in normal rat myocardial tissue. 2. Both tedisamil and lidocaine dose-dependently suppressed ischaemia-induced arrhythmias. The ED(50) values were 3.0+/-1.3 and 4.9+/-0.6 micro mol kg(-1) min(-1), respectively. 3. Combinations of the two drugs acted synergistically such that the ED(50) for tedisamil was reduced to 0.8+/-0.2 micro mol kg(-1) min(-1) in the presence of 2 micro mol kg(-1) min(-1) lidocaine. Similarly, the ED(50) for lidocaine was reduced to 0.7+/-0.2 micro mol kg(-1) min(-1) in the presence of 2 micro mol kg(-1) min(-1) tedisamil (both P<0.05). 4. In a separate series of experiments in which normal ventricular tissue was electrically stimulated, 2 micro mol kg(-1) min(-1) lidocaine produced a leftward shift in the dose-response curve for tedisamil's effect on effective refractory period (P<0.05). This dose of lidocaine had no effect on its own. These data indicate that the synergistic actions of combinations of tedisamil and lidocaine were mediated, at least in part, by extension of effective refractory period in normal myocardial tissue. 5. In contrast to the strategy of developing drugs that are selective for a single electrophysiological mechanism, the results of the present study suggest that effective antiarrhythmic drugs might be developed by optimising the combination of two complimentary electrophysiological mechanisms (i.e., action potential-prolonging activity and inactivated state sodium channel blockade).

Physicochemical determinants for drug induced blockade of HERG potassium channels: effect of charge and charge shielding.

The data on the activities of all previously described HERG blockers and of the most widely cited I(Kr) blockers were analyzed with respect to the effect of potential charged center(s) and its shielding by surrounding structural elements. The following model was considered: the less shielding of the charged form of the drug occurs, the easier its deprotonation will be and the less potency of the blockade of HERG/I(Kr) channels will be. Tertiary amines which form ammonium ions shielded by two structural fragments of the drug molecule were found to be potent HERG/I(Kr) blockers with IC50 < 1 microM (16 of 19 compounds, 84%). However, if the charged center was found at the molecular periphery as such groups as dimethylamino, N-methylpiperidino, N-methylpiperazino, N-methylpyrrolidino, pyrrolidino, imidazolo and partial periphery (diethylamino), then only moderate potency for HERG blockade with 1 microM < IC50 < 10 microM (8 of 11 compounds; 73%) was observed. Similarly, 27 of 32 weak HERG blockers ( IC50 > 10 microM) were found to be primary or secondary amines, or neutral or very weakly basic compounds. Ions of primary and secondary amines are susceptible to the fast deprotonation of the charged center and they, as well as non-charged compounds, have a low probability of induction of Torsades de Pointes (TdP). Conformational analysis and modeling of the interaction of the charged fragment of the drugs with acetone, a system that mimics a ketone fragment of HERG/I(Kr) channel, supports preference of the conformation with the shielded charged center for potent HERG/I(Kr) blockers. The absence of stereospecificity of HERG/I(Kr) blockade observed in most of the published studies reinforces the importance of charged center shielding as a key parameter. We suggest that the introduction of a hydroxy group at position 3 relative to a tertiary ammonium charged center, or the introduction of hydroxy, alkoxy or amino groups at position 2 relative to the nitrogen center of an aromatic system, should provide easy access of a water molecule to the proton, thereby facilitating deprotonation and thus leading to a moderate or weak HERG/I(Kr) blockade and a reduced risk of TdP.

Sodium channel blocking and antiarrhythmic actions of the novel arylpiperazine rsd992.

Bolus doses (4-128 micromolkg(-1)) and infusions (2-32 micromolkg(-1)min(-1)) of the novel arylpiperazine drug RSD992 produced bradycardia in rats and guinea pigs but had minimal effect on ECG variables. RSD992 (2-32 micromolkg(-1)min(-1)) increased threshold current (I(T)) for induction of extra-systoles and induction of sustained ventricular fibrillation (VF(T)) and also increased the effective refractory period (ERP) and decreased the maximum following frequency (MFF) in rat and guinea pig hearts. RSD992 (32-512 microM) significantly increased PR and QRS intervals in isolated rat hearts subjected to conditions that mimic ischaemia (pH 6.4, K(+) 11mM) but not in isolated hearts under normal perfusion conditions (pH 7.4, K(+) 3mM). RSD992 (0.1-3.0mM) reduced peak sodium current in rat cardiac (rNa(v)1.5) sodium channels more potently than neuronal (rNa(v)1.2a) sodium channels expressed in Xenopus oocytes. The voltage-dependence of sodium channel activation was unaffected whereas inactivation was shifted in a hyperpolarized direction thus suggesting RSD992 may preferentially interact with the inactive state of the sodium channel, a state usually associated with myocardial cell depolarization in ischaemic myocardium. RSD992 (2-24 micromolkg(-1)min(-1)) decreased the incidence of ventricular arrhythmias and mortality in rats subject to coronary artery ligation. RSD992 exhibits frequency- and ischaemia-selective actions on myocardial sodium currents and antiarrhythmic actions in ischaemic rat myocardium.