EGTA and motoneuronal after‐potentials.

1. Intracellular iontophoretic injections of EGTA (5‐‐20 nA) into cat spinal motoneurones consistently greatly reduce the amplitude of the delayed after hyperpolarization (a.h.p.) that follows the spike. 2. This effect is accompanied by a large reduction (on average by 3/4) in the marked increase in input conductance normally associated with the a.h.p. 3. There is also a consistent, though less regular, tendency for the resting input conductance to decrease (on average by 1/5), as well as some depolarization. 4. Recovery of the a.h.p., the associated conductance increase and the resting conductance is ver slow. It is sometimes accelerated by injections of citrate and Cl‐, or CA2+. 5. Other hyperpolarizing phenomena, such as recurrent or othodromically‐evoked i.p.s.p.s, are not depressed by injections of EGTA. 6. When depolarization is minimal EGTA injections that markedly depress the a.h.p. do not affect the rate of rise or fall of the spike. If, as a result of depolarization, an early a.h.p. is visible, it is patently insensitive to EGTA. 7. The post‐spike depolarizing after‐potential (delayed depolarization) is not obviously affected by EGTA, apart from the usual diminution seen during depolarization. 8. Since the main action of EGTA is to bind free Ca2+, the marked depression of the a.h.p. indicates that the sharp increase in K conductance which generates the a.h.p. is probably caused by a influx of Ca2+ accompanying the action potential. It is suggested that this inward Ca2+ current may be manifested in the depolarizing after‐potential.

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[63]  By,et al.  THE RECORDING OF POTENTIALS FROM MOTO-NEURONES WITH AN INTRACELLULAR ELECTRODE , 2022 .