Daniel Kernell

Input Resistance, Electrical Excitability, and Size of Ventral Horn Cells in Cat Spinal Cord

Experiments on cat lumbosacral alpha motoneurones showed that, in comparison with cells possessing rapidly conducting axons, the cells with slowly conducting axons have the higher input resistance, that they need weaker stimulating currents to reach the threshold for repetitive firing, and that they need a relatively larger increment in current strength for a given increase in firing rate. Measurements of the number and diameters of dendritic trunks gave larger values for the larger cell bodies. The discussion deals with the interrelation between cell geometry, electrical properties, and the reflex action of alpha motoneurones.

EFFECTS OF NERVE STIMULATION ON THE METABOLISM OF RIBONUCLEIC ACID IN A MOLLUSCAN GIANT NEURONE

—In vitro experiments were performed in order to determine whether nerve stimulation would affect the RNA metabolism of an identified giant neurone (R2) in the abdominal ganglion of Aplysia californica. The electrophysiological activity of the neurone was continuously monitored with an intra‐ or extracellular microelectrode. The mere presence of an intracellular microelectrode inside the neurone had no significant effect on the incorporation of tritiated nucleosides into the RNA of the giant neurone. Prolonged electrical stimulation of ganglionic nerves, strong enough to elicit post‐synaptic spikes in the giant neurone, produced a marked increase in the amount of labelled RNA in the nucleus as well as in the cytoplasm. Electrophoresis studies suggested that this increase in labelling might concern RNA with molecular weights corresponding to ribosomal as well as to non‐ribosomal RNA.

THE EFFECT OF SPIKE ACTIVITY VERSUS SYNAPTIC ACTIVATION ON THE METABOLISM OF RIBONUCLEIC ACID IN A MOLLUSCAN GIANT NEURONE

—Previous experiments on a giant neurone (R2) from Aplysia californica have shown that a prolonged electrical stimulation of ganglionic nerves, strong enough to elicit post‐synaptic spikes in the giant neurone, caused a marked increase in the uptake of labelled nucleosides into the neuronal RNA. The results described in the present paper very strongly indicate that these effects of synaptic activation were not due to the discharge of spikes in the giant neurone itself. Spikes which were directly elicited in the giant neurone by current pulses injected into the cell through an intracellular microelectrode had no significant effect on RNA labelling. Weak stimulation of ganglionic nerves, eliciting post‐synaptic potentials but few spikes in the giant neurone, produced a small but significant increase of RNA labelling.

Recruitment and firing rate modulation of motor unit tension in a small muscle of the cat's foot

Maintained contractions were elicited in the first deep lumbrical muscle of the cats foot by electrical stimulation of the contralateral motor cortex or, reflexly, by pinching of the foot pad. The discharges of all significant motor units of the muscle were monitored by electromyography, and contractions of the various motor units were observed in isometric recordings of muscle tension. Over a wide range, muscle tension could be enhanced by an increased intensity of pad pinching or cortical stimulation. This increase in muscle tension was caused by a recruitment of new motor units as well as by an increase in the firing rate of already active motor units. The latter mechanism was clearly of great importance. Pad pinching or cortical stimulation could sometimes cause the muscle to produce a tension close to that of a maximum tetanic contraction. This was several times greater than the mean tension that would have been caused by motor unit recruitment alone (i.e. by the motor units firing at their minimum steady rate). Cortical stimulation as well as pad pinching commonly recruited weak units more easily than stronger ones of the same muscle. The recruitment order obtained in response to pad pinching often differed, however, in various details from the recruitment caused by cortical stimulation.

Reduction of the monoamine stores in the terminals of bulbospinal neurones following stimulation in the medulla oblongata

Abstract Long-lasting electrical stimulation in the medulla oblongata of anaesthetized rats caused a marked reduction of the NA and 5-HT stores of varicose nerve terminals in the spinal cord as analyzed by histochemical and biochemical (for NA) methods.