Corticospinal Tract Jitter
Corticospinal influences on distal and proximal muscles of the upper limb were studied in 14 normal volunteers. The techniques of electrical and magnetic corticospinal tract activation through intact scalp were used. Recordings were made of the discharges of single motor units from the abductor digiti minimi and biceps brachii muscles. Poststimulus time histograms (PSTHs) of the motor unit discharges were constructed. The latency variation of consecutive single motor unit responses (the corticospinal tract jitter) was determined for each period of increased firing probability (peak). The rise time of excitatory postsynaptic potential (EPSP) was estimated from the duration of the period of increased firing probability, and its amplitude from the size of the PSTH peak. The threshold stimuli produced one or more narrow periods of increased firing probability in the PSTHs of all the motor units studied. A relatively small corticospinal tract jitter (289–428 µs in abductor digiti minimi and 358–431 µs in biceps brachii muscle) with no statistically significant differences between the muscles was found in each period of increased firing probability. The rise time of EPSP in both muscles ranged between 1.1 and 1.5 ms. The size of the first peaks after the anodal stimulation indicated that of the underlying EPSP amplitude was approx. 5.0 mV for the abductor digiti minimi and approx. 4.7 mV for the biceps brachii motor units. The finding of relatively small corticospinal tract jitter and short EPSPs rise times seem to support the existence of a monosynaptic projection from the brain to the motoneurones innervating both muscles. The estimated sizes of EPSPs also suggest similar effectiveness of synaptic transmission in both cases. Our results do not support the anticipated greater effectiveness of corticospinal tract connexions to the motoneurones supplying distal muscles of the upper limb.