AMIODARONE BLOCKS THE INWARD RECTIFIER POTASSIUM CHANNEL IN ISOLATED GUINEA-PIG VENTRICULAR CELLS

We examined the effects of amiodarone (5-20 mu M) on both whole-cell i nward rectifier potassium current (I-K1) and single I-K1 channel activ ity in isolated guinea pig ventricular myocytes using patch-clamp tech niques. In whole-cell voltage-clamp experiments (n = 8), amiodarone (1 0-20 mu M) caused only a small reduction of outward current at -50 mV (12 +/- 6%, no significant difference, N.S.). However, inward current was significantly reduced at -120 mV (21 +/- 7%; P <.05). When CdCl2 ( 100 mu M) and tetrodotoxin (10 mu M) were used to block inward Ca++ an d Na+ current, respectively, amiodarone significantly reduced I-K1 in both the inward (14 +/- 5% at -120 mV; P <.02) and outward (12 +/- 5% at -50 mV; P <.05; n = 11) directions. However, block required high dr ug concentrations (10-20 mu M) and was slow in onset. In contrast, ami odarone did not affect membrane current when I-K1 had been previously blocked by Ba++ (5 mM). In inside-out patch-clamp experiments, amiodar one (5 mu M) reduced single I-K1 channel open probability by increasin g interburst interval (from 0.6 +/- 0.03 to 3.1 +/- 0.9 sec; n = 5; P <.05) with no significant difference in the duration of mean open and closed times or the number of shut events within a burst. The net resu lt was that there was only a small change in both burst duration and s ingle-channel kinetics within a burst. Complete channel block occurred after the increase in interburst interval (n = 6 of six cells). In ce ll-attached patches, amiodarone exerted similar effects on single-chan nel behavior except that, as for whole-cell experiments, the onset of block was slow and required higher drug concentrations (greater than o r equal to mu M). We conclude that amiodarone 1) reduces whole-cell I- K1 by Virtue of a direct blocking action, 2) inhibits single I-K1 chan nel activity by prolonging interburst interval and 3) interacts either with a hydrophobic site within the membrane and/or a hydrophilic site accessible only from within the cell.