Action potentials activate voltage-dependent calcium channels and attendant increases in cytosolic calcium concentration ([Ca2+]i) in many excitable cells. The role of these channels in the regulation of [Ca2+]i in nonspiking cells that do not depolarize to membrane potentials sufficient to activate a substantial fraction of the available current is less clear. Measurements of the peak activation and steady-state inactivation of L-type calcium currents have predicted the existence of a noninactivating current window over a voltage range where channel inactivation is incomplete. The degree to which such small currents might regulate [Ca2+]i, however, has not been established. Here we demonstrate a "calcium window" in nondialyzed, quiescent smooth muscle cells over a small voltage range near the resting membrane potential. Sustained depolarizations in this voltage range, but not to more positive potentials, resulted in sustained rises in calcium, despite the fact that macroscopic inward currents were < 2 pA. The calcium window corresponded well with the predicted window current determined under the same conditions; the peak of the calcium window occurred at -30 mV, with steady-state rises in [Ca2+]i in some cells at -50 mV. Steady-state rises in [Ca2+]i following depolarization were completely blocked by nisoldipine and were augmented and shifted to more negative potentials by BAY K8644. Voltage-dependent calcium channels thus regulate steady-state calcium levels in nonspiking cells over a voltage range where macroscopic currents are only barely detectable. This voltage range is bounded at negative potentials by calcium channel activation and at more positive potentials by channel inactivation.