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pubmed:abstractText |
Unitary Na+ currents of myocardial mouse cells were studied at room temperature in 10 cell-attached patches, each containing one and only one channel. Small-pore patch pipettes (resistance 10-97 M omega when filled with 200% Tyrode's solution) with exceptionally thick walls were used. Observed were both rapidly inactivating (6 patches) and slowly inactivating (3 patches) Na+ currents. In one patch, a slow transition from rather fast to slow inactivation was detected over a time of 0.5 h. A short and a long component of the open-channel life time were recorded at the beginning, but only a short one at the end of the experiment. Concomitantly, the first latency was slowed. Amplitude histograms showed that the electrochemical driving force across the pore of the channel did not change during this time. In three patches, a fast and repetitive switching between different modes of Na+ channel action could be clearly identified by plotting the long-time course of the averaged current per trace. The ensemble-averaged current formed in each mode was different in kinetics and amplitude. Each mode had a characteristic mean open-channel life time and distribution of first latency, but the predominant single-channel current amplitude was unaffected by mode switches. It is concluded that two types of changes in kinetics may happen in a single Na+ channel: fast and reversible switches between different modes, and a slow loss of inactivation.
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