The effects of changing the intracellular Ca concentration ([Ca]_i) on the calcium current (i_Ca) were studied in isolated single ventricular cells of the guinea-pig. [Ca]_i was varied by an intracellular perfusion technique using a suction pipette. i_Ca measured from internally perfused cells at a pCa lower than 9.0 was dependent on the extracellular Ca concentration ([Ca]_o). Increasing [Ca]_o from 1.8 to 5.4mM increased the amplitude of i_Ca, and reduction of [Ca]_o from 1.8 to 0.01mM decreased the amplitude. The inactivation time course of i_Ca became faster as [Ca]_o was increased and slower as [Ca]_o was reduced. By decreasing the pCa of the internal perfusate from 9.0 to 6.8, the amplitude of i_Ca was decreased markedly, but no significant change was observed in its time course. Analysis of the I-V curve led to the conclusion that a change in the driving force was not a major factor in the reduction of i_Ca. The "steady state inactivation" of i_Ca was measured by a double-pulse method. The amplitude of i_Ca elicited by the test pulse was smaller at pCa 7.4 than at pCa 9.0 at potentials of between -27 and +33mV. By normalizing the i_Ca amplitude, however, the "steady state inactivation" curve in the control and at high [Ca]_i overlapped. Similar results were obtained in Sr-Tyrode solution. The degree of "steady state inactivation" of i_Ca at the potentials positive to +10mV was larger in Ca-Tyrode than in Sr-Tyrode solution. It is proposed that the reduction in amplitude of i_Ca at higher [Ca]_i is caused by a reduction of the maximum conductance of i_Ca (g_Ca) and that Ca ions passing through i_Ca channels have a remarkable effect on its inactivation.