Changes in extracellular potassium during the spontaneous activity of medullary respiratory neurones

Abstract

In 34 cats, the changes in extracellular potassium ion activity (a_K) and extracellular spike activity within the pool of respiratory neurones in the dorsormedial and ventrolateral medulla were recorded using microelectrodes filled with a liquid potassium ion exchange resin. Cyclic changes in a_K which parallel central respiratory activity were restricted to those regions where respiratory neurones are known to be localized. The largest changes in a_K (0.1–0.3 mmol · l⁻¹) were found within the ventral pool of inspiratory neurones. The a_K increased during inspiration in parallel with the pattern of phrenic nerve activity. The smallest changes in a_K (0.02–0.06 mmol · l⁻¹) were observed within the ventral pool of expiratory neurones. Here, a_K showed a transient increase during both inspiration and expiration. Within the dorsal pool of inspiratory neurones, small fluctuations of a_K were observed paralleling phrenic nerve activity and the afferent discharge of the intact vagal nerves. After the vagal nerves were cut, the changes in a_K then paralleled phrenic nerve activity. The variations in a_K within the ventral pool of respiratory neurones did not change after bilateral section of vagal nerves. Repetitive stimulation of the vagal nerves (0.1–0.5V, 0.05 ms) produced an increase in a_K only within the dorsal pool of inspiratory neurones, whereas repetitive spinal cord stimulation (5–10V, 0.05 ms) resulted in an increase of a_K within the ventral pool of respiratory neurones. The amplitude of the cyclic changes in a_K increased significantly whenever the electrode approached individual respiratory neurones as verified by the amplitude and shape of the spikes recorded by the reference barrel. The maximal changes in a_K then reached a peak amplitude of 1.3–1.5 mmol · l⁻¹, the pattern of a_K changes resembling that measured within the pools of neurones. The a_K started to rise prior to the discharge of action potentials, indicating that the efflux of K⁺-ions was produced as a consequence of synaptic transmission. The functional importance of these changes in extracellular potassium is discussed.