Summary
In monkeys generating torques about the wrist we investigated changes in the excitability of pyramidal tract (PT) axons, measured as the probability of evoking antidromic responses in motor cortex with constant juxtathreshold stimuli delivered in the brain stem. When PT stimuli were delivered 2–20 ms after an orthodromic action potential in the PT neuron, the excitability of axons was elevated, with a characteristic post-spike time course. Excitability peaked at a post-spike delay of 7.0±2.7 ms (n=33). Axonal thresholds typically dropped to 80–90% of the unconditioned values (obtained for stimuli with no preceding spike). Controlling for such post-spike threshold changes by delivering stimuli at fixed post-spike delays, we found that excitability of many PT axons also fluctuated with the wrist responses, being slightly higher during flexion or extension. The phase of movement in which excitability increased had no consistent relation to the phase of movement in which the PTN fired. Taskrelated threshold changes were also seen in PTNs whose discharge was not modulated with the wrist response. Delivering a subthreshold conditioning stimulus also increased the excitability of most PT axons to a subsequent test stimulus. Such poststimulus changes may be mediated by the effects of adjacent fibers activated by the conditioning stimuli. The post-spike and post-stimulus changes added in a nonlinear way. All three types of threshold change may be mediated by a common mechanism: changes in the ionic environment of the axon produced by activity of the axon itself or its neighbors. Such changes could enhance the effectiveness of corticospinal impulses: the post-spike excitability increase could enhance the invasion of corticospinal terminals, and the interaction between neighboring fibers could enhance synchronous arrival of impulses at common targets.
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References
Adrian ED (1920) The recovery process of excitable tissues. Part 1. J Physiol (Lond) 54: 1–34
Baylor DA, Nicholls JG (1969) Changes in extracellular potassium concentration produced by neuronal activity in the central nervous system of the leech. J Physiol (Lond) 203: 555–569
Blair E, Erlanger J (1936) On the process of excitation by brief shocks in axons. Am J Physiol 114: 309–316
Canedo A, Towe AL (1985) Superposition of antidromic responses in pyramidal tract cell clusters. Exp Neurol 89: 645–658
Chung SH, Raymond SA, Lettvin J (1970) Multiple meaning of single visual units. Brain Behav Evol 3: 72–101
Clark JW, Plonsey R (1970) A mathematical study of nerve fiber interaction. Biophys J 10: 937–957
Dubner R, Sessle BJ (1971) Presynaptic excitability changes in primary afferent and corticofugal fibers projecting to trigeminal brain stem nuclei. Exp Neurol 30: 223–228
Gugino L, Stoney SD Jr, Morse RW (1972) Presynaptic facilitation and inhibition of pyramidal tract fibers terminals. Fed Proc 31: 385
Kocsis JD, Malenka RC, Waxman SG (1983) Effects of extracellular potassium concentration on the excitability of the parallel fibers of the rat cerebellum. J Physiol (Lond) 334: 225–244
Mann MD, Follett KA (1982) Excitability changes along pyramidal tract axons after sensory stimulation. Exp Neurol 78: 685–702
Mann MD, Holt WS, Towe AL (1977) Afferent modulation of the excitability of pyramidal tract fibres. Exp Neurol 55: 414–435
Markin VS (1970) Electrical interaction of parallel non-myelinated nerve fibers. I. Change in excitability of the adjacent fibre. Biofisika 15: 120–128
Merill EG, Wall PD, Yaksh TL (1978) Properties of two unmyelinated fibre tracts of the central nervous system: lateral Lissauer tract and parallel fibres of the cerebellum. J Physiol (Lond) 284: 127–145
Muir RB, Porter R (1973) The effect of a preceding stimulus on temporal facilitation at corticomotoneuronal synapses. J Physiol (Lond) 228: 749–763
Nicholson C (1983) Regulation of the ion microenvironment and neuronal excitability. In: Jasper HM, van Gelder NM (eds) Basic mechanisms of neuronal hyperexcitability. Liss, New York, pp 185–216
Phillips CG, Porter R (1964) The pyramidal projection to motoneurones of some muscle groups of the baboon's forelimb. Progr Brain Res 12: 222–242
Porter R (1970) Early facilitation of corticomotoneuronal synapses. J Physiol (Lond) 207: 733–745
Raymond SA (1979) Effects of nerve impulses on threshold of frog sciatic nerve fibers. J Physiol (Lond) 290: 273–303
Rudomin P, Jankowska E, Madrid J (1978) Presynaptic depolarization of corticospinal and rubrospinal terminal arborization produced by volleys to cutaneous nerves. Soc Neurosci Abstr 4: 571
Somjen GG (1979) Extracellular potassium in the mammalian central nervous system. Ann Rev Physiol 41: 159–177
Stefanis C, Jasper H (1964) Recurrent collateral inhibition in pyramidal tract neurons. J Neurophysiol 27: 855–877
Swadlow HA (1974) Properties of antidromically activated callosal neurons and neurons responsive to callosal input in rabbit binocular cortex. Exp Neurol 43: 429–444
Swadlow HA, Kocsis JD, Waxman SG (1980) Modulation of impulse conduction along the axonal tree. Ann Rev Biophys Bioeng 9: 143–179
Swadlow HA, Rosene DL, Waxman SG (1978) Characteristics of interhemispheric impulse conduction between prelunate gyri of the rhesus monkey. Exp Brain Res 32: 439–443
Sykova E (1983) Extracellular K+ accumulation in the central nervous system. Progr Biophys Molec Biol 42: 135–189
Wall PD (1958) Excitability changes on afferent fiber terminations and their relation to slow potentials. J Physiol (Lond) 142: 1–21
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Schmied, A., Fetz, E.E. Activity-related changes in electrical thresholds of pyramidal tract axons in the behaving monkey. Exp Brain Res 65, 352–360 (1987). https://doi.org/10.1007/BF00236308
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DOI: https://doi.org/10.1007/BF00236308