Treatments targeting inotropy
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Oxford University Press
Abstract
Acute heart failure (HF) and in particular, cardiogenic shock are associated with high morbidity and mortality. A therapeutic dilemma is that the use of positive inotropic agents, such as catecholamines or phosphodiesteraseinhibitors, is associated with increased mortality. Newer drugs, such as levosimendan or omecamtiv mecarbil, target sarcomeres to improve systolic function putatively without elevating intracellular Ca2þ. Although meta-analyses of smaller trials suggested that levosimendan is associated with a better outcome than dobutamine, larger comparative trials failed to confirm this observation. For omecamtiv mecarbil, Phase II clinical trials suggest a favourable haemodynamic profile in patients with acute and chronic HF, and a Phase III morbidity/mortality trial in patients with chronic HF has recently begun. Here, we review the pathophysiological basis of systolic dysfunction in patients with HF and the mechanisms through which different inotropic agents improve cardiac function. Since adenosine triphosphate and reactive oxygen species production in mitochondria are intimately linked to the processes of excitation-contraction coupling, we also discuss the impact of inotropic agents on mitochondrial bioenergetics and redox regulation. Therefore, this position paper should help identify novel targets for treatments that could not only safely improve systolic and diastolic function acutely, but potentially also myocardial structure and function over a longer-term. © 2018 The Author(s).
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Acute decompensated heart failure, Adrenergic receptors, Calcium, Cardiogenic shock, Contractility, Energetics, Excitation-contraction coupling, Heart failure, Inotropes, Levosimendan, Mitochondria, Nitroxyl, Omecamtiv mecarbil, Sarcomeres, Acute disease, Animals, Antioxidants, Cardiotonic agents, Case-control studies, Catecholamines, Clinical trials as topic, Diastole, Dobutamine, Dogs, Energy metabolism, Excitation contraction coupling, Humans, Models, animal, Myocardial contraction, Nitrogen oxides, Oxidation-reduction, Phosphodiesterase inhibitors, Placebos, Receptors, adrenergic, Shock, cardiogenic, Simendan, Swine, Systole, Urea, 1,3,5,6 tetrahydro 5 methyl 6 phenyl 3,6 methano 1,5 benzodiazocine 2,4 dione, 5 [1 (3,4 dimethoxybenzoyl) 1,2,3,4 tetrahydro 6 quinolyl] 3,6 dihydro 6 methyl 2h 1,3,4 thiadiazin 2 one, Adenosine triphosphatase, Angiotensin receptor antagonist, Beta adrenergic receptor blocking agent, Cyclic amp, Cyclic amp dependent protein kinase, Digitalis, Dipeptidyl carboxypeptidase inhibitor, Epinephrine, Milrinone, Mineralocorticoid antagonist, Noradrenalin, Placebo, Reactive oxygen metabolite, Reduced nicotinamide adenine dinucleotide, Ryanodine receptor, Sodium calcium exchange protein, Sodium proton exchange protein, Adrenergic receptor, Antioxidant, Cardiotonic agent, Catecholamine, Nitrogen oxide, Phosphodiesterase inhibitor, Acute heart failure, All cause mortality, Article, Bioenergy, Calcium transport, Diastolic blood pressure, Diastolic dysfunction, Down regulation, Heart arrhythmia, Heart failure with reduced ejection fraction, Heart function, Heart hemodynamics, Heart left ventricle ejection fraction, Human, Hypotension, Lack of drug effect, New york heart association class, Nonhuman, Oxidation reduction reaction, Oxygen consumption, Pathophysiology, Pharmacokinetic parameters, Priority journal, Protein function, Systemic vascular resistance, Systolic blood pressure, Systolic dysfunction, Treatment outcome, Treatment planning, Treatment response, Animal, Animal model, Case control study, Clinical trial (topic), Dog, Drug effect, Heart contraction, Metabolism, Mitochondrion, Mortality, Pig, Sarcomere