Paradoxical effect of dofetilide on action potential duration and calcium transient amplitude in newborn rabbit ventricular myocytes.

The Na+-Ca2+ exchanger (NCX) is up-regulated in the neonatal rabbit heart. Because the duration of membrane depolarization is an important determinant of calcium entry via NCX, pharmacological agents that lengthen the action potential (AP) may significantly increase the amount of activator calcium in newborns. We tested this potentially novel therapeutic strategy by using action potential voltage clamp steps or using dofetilide, a blocker of IKr, to prolong the action potential duration (APD). The effects of changing APD on calcium transients were determined in ventricular myocytes at different developmental stages: newborn (1-4 days), juvenile (9-10 days), and adult ventricular myocytes (35 degrees C; 1 Hz). Calcium transient amplitude in neonatal myocytes increased substantially with clamping with longer APs. In contrast, exposure to dofetilide (0.1, 1, and 10 microM) under current clamp conditions increased APD in a concentration-dependent manner but had no significant effect on calcium transient amplitude in either neonates or adults. When the AP was held constant under voltage clamp conditions, dofetilide decreased the calcium transient amplitude in neonates. This effect is likely related to inhibition of sodium-calcium exchanger and L-type Ca2+ currents (ICa), as observed in separate experiments. These results suggest that dofetilide has a paradoxical effect on APD and calcium transients in the newborn heart.

Negative inotropic effect of nifedipine in the immature rabbit heart is due to shortening of the action potential.

Contractions in neonatal rabbit ventricular myocytes seem to depend predominantly on Ca2+ influx through the Na+-Ca2+ exchanger (NCX). Unexpectedly, neonates are sensitive to the negative inotropic effect of L-type Ca2+ channel blockers. L-type Ca2+ channel blockers depress contractile function indirectly in neonatal myocytes by shortening the action potential duration (APD), thereby decreasing the influx of activator Ca2+ through the NCX. Freshly isolated ventricular myocytes from adult and neonatal (1-5 d) rabbits were electrically stimulated (0.5 Hz; 35 degrees C) while action potential (AP) and Ca2+ transients (Indo-1) were recorded in the absence and presence of nifedipine (10 microM). In separate experiments, cells were voltage-clamped with a constant AP waveform (APD90=170 ms) to determine the effect of nifedipine on Ca2+ transients independent from effects on the AP. Voltage-clamp experiments confirmed that nifedipine blocks L-type Ca2+ current in neonatal myocytes. Nifedipine markedly reduced Ca2+ transient amplitude and APD in both adults (transient=20 +/- 7%; APD90=31 +/- 4% of control) and neonates (transient=38 +/- 10%; APD90=57 +/- 6% of control). When the AP was held constant by voltage clamping, nifedipine significantly reduced the amplitude of Ca2+ transients in adults (27 +/- 9% of control) but had no effect on Ca2+ transient amplitude in neonatal myocytes. These results are consistent with the concept that immature ventricular myocytes are less reliant on L-type calcium channels and are more dependent on NCX for contraction. The negative inotropic effect of L-type Ca2+ channel blockers in neonates is attributable to shortening of the AP.