The mechanisms by which low [K+]o induces spontaneous activity was studied in sheep Purkinje fibers. Purkinje strands were superfused in vitro and membrane potentials were recorded by means of a microelectrode technique. The results show that low [K+]o increases the slope and amplitude of early diastolic depolarization, sharpens the transition between early and late diastolic depolarizations, induces an after-potential and large pre-potentials through a negative shift of an oscillatory zone. Pre-potentials occur progressively sooner during diastole and merge with the after-potential to induce uninterrupted spontaneous discharge. During recovery, when the rate slows, after- and pre-potentials separate once more, the slower discharge decreasing the after-potentials but not the pre-potentials. Low [K+]o has little effect on the plateau, but markedly slows phase 3 repolarization and may altogether prevent it. At depolarized levels, voltage oscillations, slow responses, sinusoidal fluctuations or quiescence may be present depending on voltage. During the recovery, a train of either sub-threshold oscillations or spontaneous action potentials appear towards the end of phase 3 repolarization. The cessation of the action potentials unmasks large sub-threshold oscillations, that occur in the oscillatory zone. Drive, high [Ca2+]o and norepinephrine increase slope and amplitude of early diastolic depolarization as low [K+]o does. In low [K+]o, Cs+ prevents spontaneous discharge at polarized levels, but not the decrease in resting potential nor the onset of slow responses at depolarized levels. Cs+ blocks the train of oscillations and of action potentials occurring during recovery. We conclude that low [K+]o steepens early diastolic depolarization and increases its amplitude through an after-potential that results from an increased Ca2+ load; allows the attainment of the threshold through Cs+-sensitive voltage oscillations which develop when the oscillatory zone is entered either by diastolic depolarization or by phase 3 repolarization; and causes voltage oscillations also at depolarized levels, but through a Cs+-insensitive different mechanism.
The mechanisms by which low [K(+)](o) induces spontaneous activity was studied in sheep Purkinje fibers. Purkinje strands were superfused in vitro and membrane potentials were recorded by means of a microelectrode technique. The results show that low [K(+)](o) increases the slope and amplitude of early diastolic depolarization, sharpens the transition between early and late diastolic depolarizations, induces an after-potential and large pre-potentials through a negative shift of an oscillatory zone. Pre-potentials occur progressively sooner during diastole and merge with the after-potential to induce uninterrupted spontaneous discharge. During recovery, when the rate slows, after- and pre-potentials separate once more, the slower discharge decreasing the after-potentials but not the pre-potentials. Low [K(+)](o) has little effect on the plateau, but markedly slows phase 3 repolarization and may altogether prevent it. At depolarized levels, voltage oscillations, slow responses, sinusoidal fluctuations or quiescence may be present depending on voltage. During the recovery, a train of either sub-threshold oscillations or spontaneous action potentials appear towards the end of phase 3 repolarization. The cessation of the action potentials unmasks large sub-threshold oscillations, that occur in the oscillatory zone. Drive, high [Ca(2+)](o) and norepinephrine increase slope and amplitude of early diastolic depolarization as low [K(+)](o) does. In low [K(+)](o), Cs(+) prevents spontaneous discharge at polarized levels, but not the decrease in resting potential nor the onset of slow responses at depolarized levels. Cs(+) blocks the train of oscillations and of action potentials occurring during recovery. We conclude that low [K(+)](o) steepens early diastolic depolarization and increases its amplitude through an after-potential that results from an increased Ca(2+) load; allows the attainment of the threshold through Cs(+)-sensitive voltage oscillations which develop when the oscillatory zone is entered either by diastolic depolarization or by phase 3 repolarization; and causes voltage oscillations also at depolarized levels, but through a Cs(+)-insensitive different mechanism.
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