ORM-3819 promotes cardiac contractility through Ca(2+) sensitization in combination with selective PDE III inhibition, a novel approach to inotropy.

This study is the first pharmacological characterization of the novel chemical entity, ORM-3819 (L-6-{4-[N'-(4-Hydroxi-3-methoxy-2-nitro-benzylidene)-hydrazino]-phenyl}-5-methyl-4,5-dihydro-2H-pyridazin-3-one), focusing primarily on its cardiotonic effects. ORM-3819 binding to cardiac troponin C (cTnC) was confirmed by nuclear magnetic resonance spectroscopy, and a selective inhibition of the phosphodiesterase III (PDE III) isozyme (IC50=3.88±0.3 nM) was revealed during in vitro enzyme assays. The Ca(2+)-sensitizing effect of ORM-3819 was demonstrated in vitro in permeabilized myocyte-sized preparations from left ventricles (LV) of guinea pig hearts (ΔpCa50=0.12±0.01; EC50=2.88±0.14 µM). ORM-3819 increased the maximal rate of LV pressure development (+dP/dtmax) (EC50=8.9±1.7 nM) and LV systolic pressure (EC50=7.63±1.74 nM) in Langendorff-perfused guinea pig hearts. Intravenous administration of ORM-3819 increased LV+dP/dtmax (EC50=0.13±0.05 µM/kg) and improved the rate of LV pressure decrease (-dP/dtmax); (EC50=0.03±0.02 µM/kg) in healthy guinea pigs. In an in vivo dog model of myocardial stunning, ORM-3819 restored the depressed LV+dP/dtmax and improved % segmental shortening (%SS) in the ischemic area (to 18.8±3), which was reduced after the ischaemia-reperfusion insult (from 24.1±2.1 to 11.0±2.4). Our data demonstrate ORM-3819 as a potent positive inotropic agent exerting its cardiotonic effect by a cTnC-dependent Ca(2+)-sensitizing mechanism in combination with the selective inhibition of the PDE III isozyme. This dual mechanism of action results in the concentration-dependent augmentation of the contractile performance under control conditions and in the postischemic failing myocardium.

Antieosinophilic activity of simendans.

Simendans are novel agents used in the treatment of decompensated heart failure. They sensitize troponin C to calcium and open ATP-sensitive potassium channels and have been shown to reduce cardiac myocyte apoptosis. The aim of the present study was to evaluate whether simendans reduce pulmonary eosinophilia and regulate eosinophil apoptosis. Bronchoalveolar lavage (BAL) eosinophilia was evaluated in ovalbumin-sensitized mice. Effects of simendans on apoptosis in isolated human eosinophils were assessed by relative DNA fragmentation assay, annexin V-binding, and morphological analysis. Dextrosimendan [(+)-[[4-(1,4,5,6-tetrahydro-4-methyl-6-oxo-3-pyridazinyl)phenyl)hydrazono]propanedinitrile] reduced ovalbumin-induced BAL-eosinophilia in sensitized mice. Levosimendan [(-)-[[4-(1,4,5,6-tetrahydro-4-methyl-6-oxo-3-pyridazinyl)phenyl]hydrazono]propanedinitrile] and dextrosimendan reversed interleukin (IL)-5-afforded survival of human eosinophils by inducing apoptosis in vitro. Even high concentrations of IL-5 were not able to overcome the effect of dextrosimendan. Dextrosimendan further enhanced spontaneous apoptosis as well as that induced by CD95 ligation, without inducing primary necrosis. Dextrosimendan-induced DNA fragmentation was shown to be dependent on caspase and c-Jun NH2-terminal kinase activation, whereas extracellular signal-regulated kinase, p38 mitogen-activated kinase, and ATP-sensitive potassium channels seemed to play no role in its actions. Taken together, our results show that simendans possess antieosinophilic activity and may be useful for the treatment of eosinophilic inflammation.

Positive inotropic effect of levosimendan is correlated to its stereoselective Ca2+-sensitizing effect but not to stereoselective phosphodiesterase inhibition.

In order to clarify the mechanisms of the positive inotropic actions of levosimendan and its optical isomer, dextrosimendan, we compared their concentration-dependent effects in intact papillary muscles, permeabilized cardiomyocytes and in purified phosphodiesterase enzyme preparations of guinea-pig hearts. In papillary muscles twitch tension increased with EC50 values of 60 nM and 2.8 microM for levosimendan and dextrosimendan, respectively. Hence, the two enantiomers exhibited a 47 times potency difference in their positive inotropic effects in a preparation where theoretically Ca2+-sensitization and phosphodiesterase inhibition could both contribute to the positive inotropic effects. In guinea-pig cardiomyocytes, levosimendan and dextrosimendan increased isometric force production (at pCa 6.2) due to Ca2+-sensitization with EC50 values of 8.4 nM and 0.64 microM, respectively, with a similar relative potency difference of 76. A major difference appeared in their relative pharmacological potencies, however, when the inhibitory effects of the two enantiomers were assayed on phosphodiesterase III, purified from guinea pig left ventricle (i.e. the phosphodiesterase isoenzyme which is dominant in that tissue). Levosimendan was a 427 times more potent phosphodiesterase inhibitor than dextrosimendan, with IC50 values of 7.5 nM, and 3.2 microM, respectively. Taken together, our data support the hypothesis that levosimendan and dextrosimendan exert their positive inotropic effects via a stereoselective Ca2+-sensitizing mechanism and not via stereoselective inhibition of phosphodiesterase III in the myocardium.

Two inotropes with different mechanisms of action: contractile, PDE-inhibitory and direct myofibrillar effects of levosimendan and enoximone.

We characterized the Ca2+-sensitizing and phosphodiesterase (PDE)-inhibitory potentials of levosimendan and enoximone to assess their contributions to the positive inotropic effects of these drugs. In guinea pig hearts perfused in the working-heart mode, the maximal increase in cardiac output (55%, P<0.05) was attained at 50 nM levosimendan. The corresponding value for enoximone (36%) was significantly smaller (P<0.05) and was observed at a higher concentration (500 nM). In permeabilized myocyte-sized preparations levosimendan evoked a maximal increase of 55.8+/-8% (mean+/-SEM) in isometric force production via Ca2+ sensitization (pCa 6.2, EC50 8.4 nM). Enoximone up to a concentration of 10 microM failed to influence the isometric force. The PDE-inhibitory effects were probed on the PDE III and PDE IV isoforms. Levosimendan proved to be a 1300-fold more potent and a 90-fold more selective PDE III inhibitor (IC50 for PDE III 1.4 nM, and IC50 for PDE IV 11 microM, selectivity factor approximately 8000) than enoximone (IC50 for PDE III 1.8 microM, and IC50 for PDE IV 160 microM, selectivity factor approximately 90). Hence, our data support the hypothesis that levosimendan exerts positive inotropy via a Ca2+-sensitizing mechanism, whereas enoximone does so via PDE inhibition with a limited PDE III versus PDE IV selectivity.

Pharmacological mechanisms contributing to the clinical efficacy of levosimendan.

Acute decompensation of chronic heart failure is a direct life-threatening situation with short-term mortality approaching 30%. A number of maladaptive changes are amplified within the cardiovascular system during the progression of chronic heart failure that makes the decompensation phase difficult to handle. Levosimendan is a new Ca2+-sensitizer for the treatment of acutely decompensated heart failure that has proved to be effective during the decompensation of chronic heart failure and acute myocardial infarction. Levosimendan differs from other cardiotonic agents that are used for acute heart failure in that it utilizes a unique dual mechanism of action: Ca2+-sensitization through binding to troponin C in the myocardium, and the opening of ATP-sensitive K+ channels in vascular smooth muscle. In general, these mechanisms evoke positive inotropy and vasodilation. Clinical studies suggested long-term benefits on mortality following short-term administration. It may, therefore, be inferred that levosimendan has additional effects on the cardiovascular system that are responsible for the prolongation of survival. Results of preclinical and clinical investigations suggest that the combination of levosimendan-induced cardiac and vascular changes has favorable effects on the coronary, pulmonary and peripheral circulations. Redistribution of the circulating blood offers an improved hemodynamic context for the development of a positive inotropic effect through Ca2+-sensitization of the contractile filaments, without a proportionate increase in myocardial oxygen consumption or the development of arrhythmias. Activation of ATP-sensitive K+ channels, both on sarcolemma and mitochondria, may protect against myocardial ischemia, and decreased levels of cytokines may prevent the development of further myocardial remodeling. Collectively, these effects of levosimendan shift the disturbed cardiovascular parameters towards normalization, thereby halting the perpetuation of the vicious cycle of heart failure progression. This may contribute to stabilization of the circulation and improved life expectancy of patients with chronic heart failure.

Effect of levosimendan on balance between ATP production and consumption in isolated perfused guinea-pig heart before ischemia or after reperfusion.

Levosimendan is a novel drug developed for treatment of decompensated heart failure. Levosimendan is a calcium sensitizer that increases contractile force of the myocardium by enhancing the sensitivity of myofilaments to calcium without increasing intracellular calcium concentration. The present study was carried out to investigate whether levosimendan induces any changes in the phosphorylation potential (ie, the balance between ATP production and consumption) in the normal heart and in the post-ischemic heart while exerting its positive inotropic effect. We show that 0.1 microM levosimendan increased the left ventricle developed pressure in the pre-ischemic and in the post ischemic hearts by 16 and 18% respectively, and the +dP/dt by 16 and 19%, respectively. At that concentration levosimendan did not cause any effect on the phosphorylation potential (1 x 10(5) M(-1) and 0.2 x 10(5) M(-1) in the pre-ischemic and post-ischemic heart, respectively) as assessed by P-NMR, although an increased beating rate (13%) and oxygen consumption (10%) was observed when adding the drug post-ischemically. Our findings are consistent with the results of a recent clinical trial (RUSSLAN), which showed that levosimendan does not induce ischemia and reduces the risk of worsening heart failure and death, in patients with left ventricular failure complicating acute myocardial infarction.

Effects of levosimendan and milrinone on oxygen consumption in isolated guinea-pig heart.

Levosimendan is a novel calcium sensitizer that increases contraction force without change in intracellular calcium ([Ca2+]i); milrinone is a phosphodiesterase inhibitor that exerts a positive inotropic effect by increasing [Ca2+]i. The effects of levosimendan and milrinone on oxygen consumption in the isolated guinea-pig heart were studied. Isolated guinea-pig hearts were paced (280 beats/min) and perfused according to the Langendorff technique. Levosimendan (0.01-1 microM) or milrinone (0.1-10 microM) were added cumulatively and changes from baseline for diastolic and systolic pressure (LVEDP and LVSP), contractility and relaxation (+dP/dt and -dP/dt), and coronary flow and oxygen consumption (CF and VO2) were calculated. Levosimendan was found to be 10 to 30 times more potent than milrinone as an inotropic agent. The effect on VO2 was markedly lower in levosimendan-perfused hearts than in milrinone-perfused hearts (P = 0.031 between the concentration-dependent effects of the two drugs). The maximum increase in VO2 was 10 +/- 4% in the levosimendan group and 38 +/- 15% in the milrinone group. The economy of the contraction was more advantageous in levosimendan-perfused hearts (P

The effects of levosimendan and OR-1896 on isolated hearts, myocyte-sized preparations and phosphodiesterase enzymes of the guinea pig.

The concentration dependences of the Ca(2+)-sensitizing and the phosphodiesterase-inhibitory effects of levosimendan (the (-) enantiomer of [[4-(1,4,5,6-tetrahydro-4-methyl-6-oxo-3-pyridazinyl)phenyl]hydrazono]propanedinitrile) and its active metabolite, OR-1896 (the (-) enantiomer of N-[4-(1,4,5,6-tetrahydro-4-methyl-6-oxo-3-pyridazinyl)phenyl] acetamide), were compared with their positive inotropic effects to reveal their mechanisms of action in guinea pig hearts. In Langendorff-perfused hearts, left ventricular +dP/dt(max) increased by 26+/-4% and 25+/-3% (mean+/-S.E.M.), with EC(50) values of 15+/-2 and 25+/-1 nM for levosimendan and OR-1896, respectively. In permeabilized myocyte-sized preparations, levosimendan and OR-1896 both increased isometric force production via Ca(2+) sensitization (at pCa 6.2), by 51+/-7% and 52+/-6%, with EC(50) values of 8+/-1 and 36+/-7 nM (P<0.05), respectively. Thus, the two molecules could be defined as Ca(2+) sensitizers and positive inotropes with very similar concentration dependences. However, major differences appeared when the phosphodiesterase-inhibitory effects of levosimendan and OR-1896 were probed on the two phosphodiesterase isoforms (phosphodiesterases III and IV) dominant in the left ventricular cardiac tissue. Levosimendan was a 40-fold more potent and a 3-fold more selective phosphodiesterase III inhibitor (IC(50) for phosphodiesterase III=2.5 nM, and IC(50) for phosphodiesterase IV=25 microM, selectivity factor approximately 10000) than OR-1896 (IC(50) for phosphodiesterase III=94 nM, and IC(50) for phosphodiesterase IV=286 microM, selectivity factor approximately 3000). Hence, our data support the hypothesis that levosimendan and OR-1896 both exert positive inotropy via a Ca(2+)-sensitizing mechanism and not via simultaneous inhibition of the phosphodiesterases III and IV isozymes in the myocardium at their maximal free plasma concentrations.