Istaroxime

Istaroxime
Legal status
Legal status
  • Investigational
Identifiers
ChemSpider 28521583
ChEMBL CHEMBL2093999
Chemical and physical data
Formula C21H32N2O3
Molar mass 360.49 g/mol
3D model (Jmol) Interactive image

Istaroxime is an investigational drug originally patented and developed by the Italian pharmaceutical company Sigma-Tau. Istaroxime is now under development for treatment of acute decompensated heart failure by CVie Therapeutics, a Taiwanese pharmaceutical company owned by Lee's Pharmaceutical Holdings Limited that in July 2012 has acquired from Sigma-Tau the patents and rights on Istaroxime and related compounds. It is still in early-stage development, having been evaluated in phase two clinical trials.[1] Istaroxime is an innovative medication as it is an effective treatment for both systolic and diastolic heart failure.[2] Systolic heart failure is characterized by impaired ventricular emptying, caused by reduced contractility, and diastolic dysfunction is defined by defective ventricular filling, caused by the heart’s inability to properly relax between beats.[3] Intracellular calcium fluxes regulate both contraction and relaxation. Cardiac muscle cells from patients with heart failure show smaller amounts of peak calcium in their cytoplasm during contraction, and slower removal.,[4][5] The mishandling of intracellular calcium is often due to problems in the cells’ ability to mediate calcium influx, and sequestration of calcium back in the sarcoplasmic reticulum.,[4][6]

Mechanism of action

Istaroxime is a positive inotropic agent[2] that mediates its action through inhibition of sodium/potassium adenosine triphosphatase (Na+/K+ ATPase).[7] Na+/K+ ATPase inhibition increases intracellular sodium levels, which reverses the driving force of the sodium/calcium exchanger, inhibiting calcium extrusion and possibly facilitating calcium entry.,[5][8] Additionally, Istaroxime increases intracellular calcium by improving the efficacy by which intracellular calcium triggers sarcoplasmic reticulum calcium release,[5][8] and by accelerating the inactivation state of L-type calcium channels, which allow for calcium influx.[9] Together the changes in calcium handling increase cell contraction.

Istaroxime also enhances the heart’s relaxation phase[5] by increasing the rate of intracellular calcium sequestration by Sarco/endoplasmic Reticulum Calcium ATPase, isotype 2a (SERCA2a).[8] SERCa2a is inhibited by phospholamban and higher phospholamban-to-SERCA2a ratios cause SERCA inhibition and impaired relaxation.[5] Istaroxime reduces SERCA2a-phospholamban interaction,[5][8] and increases SERCA2a affinity for cytosolic calcium.[7] Studies on failing human heart tissue show that Istaroxime increases SERCA2a activity up to 67%.[5]

Clinical use

Clinical trials show that Istaroxime improves ejection fraction, stroke volume and systolic blood pressure, while also enhancing ventricular filling.[1] The drug also reduces heart rate and ventricular diastolic stiffness.[1] Contrary to available inotropic therapies, Istaroxime may permit cytosolic calcium accumulation while avoiding a proarrhythmic state.[5][9][10][11] Proposed mechanisms for Istaroxime’s antiarrhythmic effect include a suppression of the transient inward calcium current directly involved in the production of delayed after-depolarizations[5] and improved calcium sequestration due to SERCA2a stimulation.[11] SERCA down-regulation in the failing myocardium[12] might sensitize patients to the detrimental effect of other currently used positive inotropes. Istaroxime’s lusitropic effect facilitates its wider margin of safety, as patients can receive higher doses without signs of arrhythmias.[10]

References

  1. 1 2 3 Shah, S.J., MD, Blair, J.E.A., Filippatos, G.S., Macarie, C., Ruzyllo, W., Korewicki, J., Bubenek-Turconi, S.I., Ceracchi, M., Bianchetti, M., Carminati, P., Kremastinos, D., Grzybowski, J., Valentini, G., Sabbah, H.N., Gheorghiade, M. 2009. Effects of istaroxime on diastolic stiffness in acute heart failure syndromes: Results from the Hemodynamic, Echocardiographic, and Neurohormonal Effects of Istaroxime, a Novel Intravenous Inotropic and Lusitropic Agent: a Randomized Controlled Trial in Patients Hospitalized with Heart Failure (HORIZON-HF) trial. American Heart Journal, 157 (6): 1035-1041.
  2. 1 2 Mattera, G.G., Giudice, P.L., Loi, F.M.P., Vanoli, E., Gagnol, J.P., Borsini, F., and Carminati, P. 2007. Istaroxime: A New Luso-Inotropic Agent for Heart Failure. American Journal of Cardiology, 99(2A): 33A-40A.
  3. Gheorghiade, M., Ambrosy, A.P., Ferrandi, M., Ferrari, P. 2011. Combining SERCA2a activation and Na-K ATPase inhibition: a promising new approach to managing acute heart failure syndromes with low cardiac output. Discovery medicine, 12 (63):141-151.
  4. 1 2 Davies, C.H., Davia, K., Bennett, J.G., Pepper, J.R., Poole-Wilson, P.A., Harding, S.E. 1995. Reduced contraction and altered frequency response of isolated ventricular myocytes from patients with heart failure. Circulation, 92: 2540 –2549.
  5. 1 2 3 4 5 6 7 8 9 Micheletti, R., Palazzo, F., Barassi, P., Giacalone, G., Ferrandi, M., Schiavone, A., Moro, B., Parodi, O., Ferrari, P., and Bianchi, G. 2007. Istaroxime, a Stimulator of Sarcoplasmic Reticulum Calcium Adenosine Triphosphatase Isoform 2a Activity, as a Novel Therapeutic Approach to Heart Failure. American Journal of Cardiology, 99: 24-32.
  6. Lehnart, S. E., Schillinger, W., Pieske, B., Prestle, J., Just, H., Hasenfuss, G. 1998. Sarcoplasmic Reticulum Proteins in Heart Failure. Annals of the New York Academy of Sciences, 853: 220-30.
  7. 1 2 Rocchetti, M., Besana, A., Mostacciuolo, G., Micheletti, R., Ferrari, P., Sarkozi, S., Szegedi, C., Jona, I., and Zaza, A. 2005. Modulation of sarcoplasmic reticulum function by Na+/K+ pump inhibitors with different toxicity: digoxin and PST2744 [(E,Z)-3-((2- aminoethoxy)imino)androstane-6,17-dione hydrochloride]. Journal of Pharmacology and Experimental Therapeutics, 313: 207–215.
  8. 1 2 3 4 Rocchetti, M., Alemanni, M., Mostacciuolo, G., Barassi, P., Altomare, C., Chisci, R., Micheletti, R., Ferrari, P., and Zaza. A. 2008. Modulation of Sarcoplasmic Reticulum Function by PST2744 [Istaroxime; (E,Z)-3-((2-Aminoethoxy)imino) Androstane-6,17- dione Hydrochloride)] in a Pressure-Overload Heart Failure Model. Journal of Pharmacology and Experimental Therapeutics, 326: 957-965.
  9. 1 2 Rocchetti, M., Besana, A., Mostacciuolo, G., Ferrari, P., Micheletti, R., and Zaza, A. 2003. Diverse Toxicity Associated with Cardiac Na+/K+ Pump Inhibition: Evaluation of Electrophysiological Mechanisms. Journal of Pharmacology and Experimental Therapeutics, 305: 765-771.
  10. 1 2 Adamson, P.B., Vanoli, E., Mattera, G.G., Germany, R., Gagnol, J., Carminati, P., and Schwartz, P.J. 2003. Hemodynamic Effects of a New Inotropic Compound, PST-2744, in Dogs With Chronic Ischemic Heart Failure. Journal of Cardiovascular Pharmacology, 42: 169–173.
  11. 1 2 Alemanni, M., Rocchetti, M., Re, D., Zaza, A. 2011. Role and Mechanism of Subcellular Ca2+ Distribution in the Action of Two Inotropic Agents with Different Toxicity. Journal of Molecular and Cellular Cardiology, 50.5: 910-918.
  12. Movsesian, M.A., Karimi, M., Green, K., and Jones, L.R. 1994. Ca(2+)-transporting ATPase, phospholamban, and calsequestrin levels in nonfailing and failing human myocardium. Circulation, 90: 653-657.
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