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The anti-addiction drug ibogaine inhibits cardiac ion channels: a study to assess the drug’s proarrhythmic potential

Xaver Koenig, Michael Kovar, Lena Rubi, Ágnes K. Mike, Péter Lukács, Vaibhavkumar S. Gawali, Hannes Todt, Walter Sandtner, Karlheinz Hilber

BMC Pharmacology and Toxicology September 1, 2012 Peer reviewed DOI: 10.1186/2050-6511-13-s1-a38 via OpenAlex

Summary

Ibogaine, a plant alkaloid with anti-addictive properties, inhibits human ERG potassium channels and may induce life-threatening cardiac arrhythmias. In studies, therapeutic concentrations of ibogaine reduced hERG currents at an IC50 of 4 µM and also inhibited sodium currents in human Na V 1.5 channels. While it blocked hERG channels, ibogaine did not prolong the action potential in guinea pig cardiomyocytes at low concentrations and even shortened it at higher doses. Its inhibitory effects on ion channels suggest a proarrhythmic potential, although it may also have antiarrhythmic properties.

Study at a glance

Design experimental study
Population human cardiac ion channels and mouse/guinea pig cardiomyocytes
Key finding Ibogaine inhibits cardiac ion channels at therapeutic concentrations, suggesting a potential for proarrhythmia.

Abstract

The plant alkaloid ibogaine has shown promising anti-addictive properties in animals and humans. Although not licensed as a therapeutic drug, and despite evidence that ibogaine may disturb the rhythm of the heart, this alkaloid is used as an anti-addiction drug in alternative medicine. We have recently reported that therapeutic concentrations of ibogaine inhibit human ERG (hERG) potassium channels, and thereby uncovered a mechanism by which the drug may induce life-threatening cardiac arrhythmias. Here, to assess the drug’s proarrhythmic potential in more detail, we studied the effects of ibogaine and its congener 18-methoxycoronaridine (18-MC) on various cardiac voltage-gated ion channels by using the whole cell patch clamp technique. Besides heterologously expressed ion channels in TSA-201 cells, native channels in isolated mouse and guinea pig ventricular cardiomyocytes were also studied. Finally, we performed computer simulations to estimate drug effects on the human cardiac action potential (AP). We confirmed that heterologously expressed hERG currents are reduced by ibogaine in low micromolar concentrations (IC 50 , 4 µM). Moreover, at higher concentration, the drug also reduced human Na V 1.5 sodium currents. Experiments on mouse cardiomyocytes confirmed that ibogaine also inhibits voltage-gated ion channels in their native environment. 18-MC also reduced cardiac ion currents, but less potently than ibogaine. Although blocking hERG channels, ibogaine did not prolong the AP in guinea-pig cardiomyocytes at low micromolar concentrations. Higher concentrations (>10 µM) even shortened the AP. Finally, implementation of ibogaine’s inhibitory effects on ion channels in a computer model of a human ventricular cardiomyocyte suggested that calcium channel blockade by the drug counteracts the AP-prolonging effect generated by hERG inhibition. Because ibogaine inhibits cardiac ion channels in therapeutic concentrations, the drug is potentially proarrhythmic. The risk of its administration, however, is possibly reduced by the fact that the drug also shows antiarrhythmic properties.

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