Spike propagation and conduction failure in the rat neural lobe.

1. Single units were recorded from the rat hypothalamo-neurohypophysial system in vivo to test the hypothesis that action potential conduction failure might contribute to the relative inefficiency of neurohypophysial hormone release at low frequencies of stimulation, and following prolonged stimulation. 2. Recordings were made from the cell bodies of supraoptic neurones which project to the neural lobe of the pituitary. Stimuli applied to the neural lobe evoked antidromic action potentials (in ten of forty cells) at times when the axonal membrane at the site of stimulation should have been refractory following the passage of a spontaneous, orthodromically conducted action potential. This observation suggests that failure of orthodromic action potentials may occur intermittently in the neural lobe. 3. Recordings from single units in the neural lobe showed similar spontaneous patterns of activity to those seen from cell bodies in the supraoptic nucleus. 4. Stimuli applied to the neural stalk evoked orthodromically conducted spikes in these single units: evoked spikes followed stimulation faithfully at 50-80 Hz for 1 s or at 20 Hz for 1 min. Such stimulation was accompanied by a reduction in spike height and a prolongation of latency. 5. Comparable changes were seen in the latency and amplitude of evoked potentials recorded from the neural lobe with low-resistance electrodes. 6. Stalk stimulation at 50 Hz for 1 s was accompanied by a reduction in the threshold for initiation of action potentials, suggesting an increase in the excitability of neural lobe axons. 7. We conclude that, during low-frequency activation, spike failure occurs intermittently in neurohypophysial axons, and that changes in the excitability of the axons during activation at high frequencies may contribute to the facilitation of neurohypophysial hormone release that occurs with increasing frequencies of stimulation.