Ionic currents in mammalian fast skeletal muscle.

1. The double sucrose‐gap technique has been applied to rat skeletal muscle fibres to study the ionic currents under voltage‐clamp conditions. 2. The iliacus muscle was found to be of 'fast' type according to the characteristics of the twitch generated by an action potential. 3. Micro‐electrode measurements have shown that the intracellular potential is under good control even when an inward current develops. 4. The components of an equivalent circuit with two time constants have been estimated from the records of the capacitive current. 5. In rat muscle, between 15 and 21 degrees C, inward and outward currents are similar to sodium and potassium currents found in frog muscle at lower temperature (1‐‐3 degrees C). 6. The inward current which depends on [Na]o and is abolished by tetrodotoxin is carried by sodium ions. Related to the mean value for the holding potential (‐90.5 mV) this current reaches its maximum amplitude a +40 and +50 mV, reverses between +130 and +150 mV and its half inactivation occurs between +14 and +22 mV. The effect of low doses of tetrodotoxin suggests that two components participate in the sodium current. 7. The delayed outward current which shows inactivation is divided in two components: (i) the fast has a linear instantaneous current‐voltage relation and differs from the fast component of frog muscle in that its equilibrium potential is more negative than the resting potential; (ii) the slow has a linear instantaneous current‐voltage relation and the mean value for its equilibrium potential is 26 mV less negative than the resting potential. 8. Inward‐going rectification is present in rat muscle.