Membrane current and intracellular Ca concentration ([Ca]i) transients were recorded from isolated rat ventricular myocytes under voltage-clamp control. The cells were dialyzed by the patch pipette solution, which contained the fluorescent Ca indicator indo-1 and 0.5 mM Na. Under these experimental conditions, Ca entry via Na-Ca exchange did not appear to be appreciable even in the absence of extracellular Na. Increasing the duration of voltage-clamp pulses from 5 to 80 ms produced [Ca]i transients of increasing amplitude, while the peak Ca current was not changed. This duration dependence of the [Ca]i transient was most demonstrable at more negative test potentials (e.g., -20 to -30 mV) and was not qualitatively modified by Na-free solutions. This latter result indicates that Ca extrusion by Na-Ca exchange is not responsible for the smaller [Ca]i transients observed when the membrane is repolarized after very brief depolarizations. Although the peak Ca current was not changed by increasing pulse duration, the integrated Ca current was increased. These observations are consistent with a Ca-release mechanism in cardiac excitation-contraction coupling in which 1) the Ca-release process can be modulated by membrane potential or 2) the Ca entering the cell via Ca channels has a preferential access [compared with Ca from the sarcoplasmic reticulum (SR)] to the site(s) that control SR Ca release. The role of Na-Ca exchange in the decline of [Ca]i during relaxation was also explored. Removal of extracellular Na (Nao) resulted in 20% slowing of the decline in [Ca]i during relaxation. From this, we conclude that the Na-Ca exchange competes with SR to remove Ca from the cytoplasm and that under our control conditions the exchanger may account for 20% of this decline. The Nao dependence of relaxation was reduced at more positive membrane potentials and increased by SR Ca loading.