Adaptation of cat motoneurons to sustained and intermittent extracellular activation.

Spielmann, John M.; Laouris, Yiannis; Nordstrom, Michael A.; Robinson, Grant A.; Reinking, Robert M.; Stuart, Douglas G.

doi:10.1113/jphysiol.1993.sp019625

Cited by 94 publications

(82 citation statements)

References 40 publications

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“…Although the excitability of motoneurons can be altered through repetitive activation (Spielmann et al, 1993;Gandevia et al, 1999) or through ongoing changes in afferent input (Martin et al, 2008), neither of these mechanisms is likely to produce the differential effects observed here, as both afferents and motoneurons experienced the same total extra activity in each conditioning protocol. Furthermore, this extra activity was very little compared with normal motoneuron firing in voluntary contractions (Ͼ15 Hz) (Bellemare et al, 1983).…”

Section: Discussionmentioning

confidence: 92%

Voluntary Motor Output Is Altered by Spike-Timing-Dependent Changes in the Human Corticospinal Pathway

Taylor¹,

Martin²

2009

J. Neurosci.

126

167

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Repeated pairs of timed presynaptic and postsynaptic potentials cause lasting changes in efficacy of transmission at many synapses. The corticospinal tract is the major pathway controlling voluntary movement in humans, and corticospinal neurons have monosynaptic connections to motoneurons of many muscles. We hypothesized that corticospinal transmission in humans could be altered by delivering, to the corticospinal-motoneuronal synapses, timed pairs of presynaptic volleys (produced by cortical stimulation) and antidromic postsynaptic volleys (by peripheral nerve stimulation). To test corticospinal transmission, electrical cervicomedullary stimuli evoked motor responses [cervicomedullary motor-evoked potentials (CMEPs)] in biceps brachii before and for 1 h after conditioning with 50 paired cortical and peripheral nerve stimuli. Seven interstimulus intervals (ISIs) of conditioning stimulus pairs were tested on different days. With one ISI (ϩ3 ms; cortical before peripheral nerve stimulation), CMEPs were significantly increased in size by 33 Ϯ 30% (mean Ϯ SD; n ϭ 7) from 4 until 32 min after conditioning. With two other ISIs (Ϫ13 ms, ϩ22 ms), CMEPs were decreased from ϳ30 until 60 min after conditioning (by 25 Ϯ 23% and 27 Ϯ 32%; n ϭ 8). The remaining ISIs produced no changes. In a second study, subjects performed weak bilateral voluntary elbow flexion contractions before and after conditioning of the right elbow flexors. Conditioning ISIs that increased or decreased CMEPs similarly increased or decreased voluntary force and EMG on the right. Thus, depending on their timing, repeated paired stimuli can potentiate or depress corticospinal transmission, and these changes are functionally relevant. We suggest that bidirectional spike-timing-dependent plasticity can be induced at corticospinal-motoneuronal synapses and can influence voluntary motor output.

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Section: Discussionmentioning

confidence: 92%

Voluntary Motor Output Is Altered by Spike-Timing-Dependent Changes in the Human Corticospinal Pathway

Taylor¹,

Martin²

2009

J. Neurosci.

126

167

View full text Add to dashboard Cite

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“…Intrinsic motoneuronal properties also change with fatigue. In animals, when motoneurons are repetitively stimulated by sustained intracellular currents, many cells either reduce their discharge or stop firing (Kernell and Monster, 1982a,b;Spielmann et al, 1993;Sawczuk et al, 1997). Similarly, in humans, the synaptic drive necessary to maintain repetitive firing of single motor units increases during weak contractions (Johnson et al, 2004).…”

Section: Discussionmentioning

confidence: 99%

Fatigue-Sensitive Afferents Inhibit Extensor but Not Flexor Motoneurons in Humans

Martin¹,

Smith²,

Butler³

et al. 2006

J. Neurosci.

158

159

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The role of group III and IV muscle afferents in controlling the output from human muscles is poorly understood. We investigated the effects of these afferents from homonymous or antagonist muscles on motoneuron pools innervating extensor and flexor muscles of the elbow. In study 1, subjects (n ϭ 8) performed brief maximal voluntary contractions (MVCs) of elbow extensors before and after a 2 min MVC of the extensors. During MVCs, electromyographic responses from triceps were evoked by stimulation of the corticospinal tracts [cervicomedullary motor evoked potentials (CMEPs)]. The same subjects repeated the protocol, but input from fatigue-sensitive afferents was prolonged after the fatiguing contraction by maintained muscle ischemia. In study 2, CMEPs were evoked in triceps during brief extensor MVCs before and after a 2 min sustained flexor MVC (n ϭ 7) or in biceps during brief flexor MVCs before and after a sustained extensor MVC (n ϭ 7). Again, ischemia was maintained after the sustained contractions. During sustained MVCs of the extensors, CMEPs in triceps decreased by ϳ35%. Without muscle ischemia, CMEPs recovered within 15 s, but with maintained ischemia, they remained depressed (by ϳ28%; p Ͻ 0.001). CMEPs in triceps were also depressed (by ϳ20%; p Ͻ 0.001) after fatiguing flexor contractions, whereas CMEPs in biceps were facilitated (by ϳ25%; p Ͻ 0.001) after fatiguing extensor contractions. During fatigue, inputs from group III and IV muscle afferents from homonymous or antagonist muscles depress extensor motoneurons but facilitate flexor motoneurons. The more pronounced inhibitory influence of these afferents on extensors suggests that these muscles may require greater cortical drive to generate force during fatigue.

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“…The second phase is termed late SFA. It follows early SFA, and it occurs over many tens of seconds or even minutes (Kernell and Monster, 1982b;Spielmann et al, 1993). Some studies discuss three phases of SFA, with the addition of an "immediate" phase occurring over the first few spikes of a repetitive train (Sawczuk et al, 1995).…”

Section: Spike Frequency Adaptationmentioning

confidence: 99%

“…It is possible, however, that the high variance in interspike interval could occlude an underlying early SFA process. Given that late SFA is seen even with intermittent stimulation (Spielmann et al, 1993), then if it is present during locomotion, one should record an overall slowing of the firing rate over tens of seconds to minutes. We have presented evidence demonstrating late SFA during a period of time following brainstem stimulation but prior to establishment of locomotor activity (Krawitz et al, 1996).…”

Section: State-dependence Of Motoneuron Properties: Modulation Duringmentioning

confidence: 99%

Beginning at the end: Repetitive firing properties in the final common pathway

Brownstone

2006

Progress in Neurobiology

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Since the early 20th century, it has been recognized that motoneurons must fire repetitive trains of action potentials to produce muscle contraction. In 1932, Sir John Eccles, together with Hebbel Hoff, found that action potential spike trains in motor axons were produced by "rhythmic centres", which were within the motoneurons themselves. Two decades later, Eccles attended a Cold Spring Harbor Symposium in NY, USA entitled "The Neuron". Two of the many notable presentations at this symposium were juxtaposed: one by Eccles from the University of Otago, Dunedin, NZL, and the other by J. Walter Woodbury and Harry Patton from the University of Washington, Seattle, USA. Both presentations included data obtained using sharp microelectrodes to study the intracellularly recorded potentials of cat motoneurons. In this review, I discuss some of the events leading up to and surrounding this jointly accomplished advance and proceed to discussion of subsequent studies over 5+ decades that have made use of intracellular recordings from motoneurons to study their repetitive firing behavior. This begins with early descriptions of primary and secondary range firing, and continues to the discovery of dendritic persistent inward currents and their relation to plateau potentials, synaptic amplification, and motoneuronal firing. Following a brief description of the possible mechanisms underlying spike frequency adaptation, I discuss the modulation of repetitive firing properties during various motor behaviors. It has become increasingly clear that the central nervous system has exquisite control of the repetitive firing of motoneurons. Eccles' work laid the foundation for the present-day study of these processes.

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Adaptation of cat motoneurons to sustained and intermittent extracellular activation.

Cited by 94 publications

References 40 publications

Voluntary Motor Output Is Altered by Spike-Timing-Dependent Changes in the Human Corticospinal Pathway

Voluntary Motor Output Is Altered by Spike-Timing-Dependent Changes in the Human Corticospinal Pathway

Fatigue-Sensitive Afferents Inhibit Extensor but Not Flexor Motoneurons in Humans

Beginning at the end: Repetitive firing properties in the final common pathway

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