The distribution of monosynaptic excitation from the pyramidal tract and from primary spindle afferents to motoneurones of the baboon's hand and forearm

Clough, John; Kernell, Daniel; Phillips, C. G.

doi:10.1113/jphysiol.1968.sp008598

Cited by 284 publications

(99 citation statements)

References 41 publications

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“…For example, in biceps brachii motor units, we found a large-amplitude, low-frequency oscillation that peaks at 1-2 Hz, with minimal high-frequency coherence, which is in agreement with previous studies (Farmer et al 1993a;Kim et al 2001). These findings suggest that the relative contribution of the oscillatory inputs at low and high frequencies is different in arm and hand muscles, and supports the observations of a reduced corticospinal projection to proximal as opposed to distal muscles (Clough et al 1968;Phillips and Porter 1964). Nonetheless, we did observe a weak but significant association between motor unit synchronization and high-frequency (10 -30 Hz) coherence that was stronger after eccentric exercise, suggesting that the weak inputs generating synchronization in biceps brachii also contribute to high-frequency coherence.…”

Section: Motor Unit Coherencesupporting

confidence: 81%

“…These findings are interpreted as a change in the number and/or excitability of branched corticospinal inputs used to perform these tasks (Farmer et al 1990;Schmied et al 1999). However, most measurements of the strength of motor unit synchronization in humans are performed in hand or wrist muscles, which have strong corticospinal projections to motor neurons (Clough et al 1968;Phillips and Porter 1964). In contrast, corticospinal inputs to biceps brachii motor neurons are generally weaker than in hand muscles (Palmer and Ashby 1992), and this is reflected in reduced synchrony in proximal muscles (Kim et al 2001).…”

Section: Motor Unit Synchronizationmentioning

confidence: 97%

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Motor Unit Synchronization Is Increased in Biceps Brachii After Exercise-Induced Damage to Elbow Flexor Muscles

Dartnall¹,

Nordstrom²,

Semmler³

2008

Journal of Neurophysiology

104

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Section: Motor Unit Coherencesupporting

confidence: 81%

Section: Motor Unit Synchronizationmentioning

confidence: 97%

Motor Unit Synchronization Is Increased in Biceps Brachii After Exercise-Induced Damage to Elbow Flexor Muscles

Dartnall¹,

Nordstrom²,

Semmler³

2008

Journal of Neurophysiology

104

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“…The degree of motor deficits post stroke is determined by the amount of damage to the corticospinal system (Pineiro et al 2000). Our finding that the majority of deficits in grasp performance post stroke may be due to an execution problem is consistent with the understanding that corticospinal system structures constitute the neural substrate for skilled muscle action (Clough et al 1968;Strick 1996, 2002;Fetz and Cheney 1980;Palmer and Ashby 1992;Porter and Lemon 1993).…”

Section: Contributions Of Digit Extension Ability To Graspingsupporting

confidence: 68%

Recovery of Thumb and Finger Extension and Its Relation to Grasp Performance After Stroke

Lang¹,

DeJong²,

Beebe³

2009

Journal of Neurophysiology

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Lang CE, DeJong SL, Beebe JA. Recovery of thumb and finger extension and its relation to grasp performance after stroke. J Neurophysiol 102: 451-459, 2009. First published May 20, 2009 doi:10.1152/jn.91310.2008. This study investigated how the ability to extend the fingers and thumb recovers early after stroke and how the ability to extend all of the digits affects grasping performance. We studied 24 hemiparetic patients at 3 and 13 wk post stroke. At each visit, we tested the subjects' ability to actively extend all five digits of their contralesional, affected hand against gravity and to perform a grasp movement with the same hand. Three-dimensional motion analysis captured: 1) maximal voluntary extension excursion of each digit and 2) grasp performance variables of movement time, peak aperture, peak aperture rate, and aperture path ratio. We found that finger and thumb extension improved from 3 to 13 wk, with average improvements ranging from 12 to 19°across the five digits. Grasp performance improved on two of the four variables measured. Peak apertures and peak aperture rates improved from 3 to 13 wk, but self-selected movement time and aperture path ratio did not. Stepwise multiple regression models showed that the majority of variance in grasp performance at 13 wk could be predicted by the ability to extend the index or middle finger at 3 wk, plus the change in the ability to extend the index finger from 3 to 13 wk. R 2 values ranged from 0.55 to 0.89. Our data indicate that the amount of recovery in finger and thumb extension and grasping is small from 3 to 13 wk post stroke. In people with relatively pure motor hemiparesis, one important factor underlying deficits in hand shaping during grasping is the inability to extend the fingers and thumb. Without sufficient volitional control of finger and thumb extension, successful grasping of objects will not occur.

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“…It is known that there are direct monosynaptic connexions from the motor cortex to spinal motoneurones in monkeys, apes and man, animals which possess the ability to produce fractionated finger movements, while they are lacking in animals such as cat and dog which do not possess the capacity for relatively independent finger movements (Kuypers, 1973). These direct corticomotoneuronal connexions are preferentially distributed to motoneurones supplying distal motoneurones (Kuypers, 1960) where they exert powerful e.p.s.p.s (Phillips & Porter, 1964;Clough, Kernell & Phillips, 1968;Porter, 1970).…”

Section: Introductionmentioning

confidence: 99%

Functional properties of monkey motor cortex neurones receiving afferent input from the hand and fingers

Lemon

1981

The Journal of Physiology

162

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SUMMARY1. Records have been made from area 4 of the cerebral cortex in five conscious monkeys. The properties of 216 neurones responsive to natural stimulation of the hand and fingers have been investigated.2. 46 % ofthese neurones responded only to cutaneous stimulation (especially light brushing across the glabrous skin) and a further 38 % responded only to movement of the digits. 4 % responded to brief prods of the hand. 12 % of the sample responded to more than one stimulus modality.3. Many hand-input neurones, including pyramidal tract neurones, responded at short-latency (8-15 msec) to light mechanical stimulation of the hand and to weak electrical stimulation of the median nerve.4. Responsive neurones were found at all depths of the cortical grey matter. Responses ofshortest latency were encountered in neurones probably located in layers IV and V.5. The behaviour of eighty hand-input neurones was analysed during a simple, stereotyped task which involved pulling a lever and collecting a food reward from a small well. For comparison, the activity of 117 neurones with inputs from the wrist, elbow or shoulder was also analysed.6. Nearly all hand-input neurones modulated their activity either before (48/80) or during (29/80) the retrieval of the reward which required precision grip between index finger and thumb. Many were silent during proximal arm movements and some displayed activity patterns independent of these movements.7. By contrast, the activity of many neurones with proximal arm (elbow, shoulder) inputs was unrelated to food retrieval and manipulation, but well related to arm movements.8. Forty-three of the eighty neurones had cutaneous input from the hand. Twenty-seven were active before hand contact. Thirty-five modulated their discharge when contact was made (twenty-one excitation, fourteen inhibition).9. Most hand-input neurones were more active during fractionated movements of the hand or fingers than during power or ball grips requiring simultaneous flexion of all digits. Neurones with glabrous inputs often showed intense activity during small, precise finger movements and during active tactile exploration without the aid of vision. 0022-3751/81/3680-0935 $07.50 (© 1981 The Physiological Society 498 R. N. LEMON 10. Analysis of the discharge frequency of twenty-five hand-input neurones revealed that some (mainly non-pyramidal tract neurones) had a similar mean frequency and range of modulation during both active movement and passive stimulation. Others (mainly pyramidal tract neurones) had a greater frequency range and higher mean frequency during active than during passive movements.

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The distribution of monosynaptic excitation from the pyramidal tract and from primary spindle afferents to motoneurones of the baboon's hand and forearm

Cited by 284 publications

References 41 publications

Motor Unit Synchronization Is Increased in Biceps Brachii After Exercise-Induced Damage to Elbow Flexor Muscles

Motor Unit Synchronization Is Increased in Biceps Brachii After Exercise-Induced Damage to Elbow Flexor Muscles

Recovery of Thumb and Finger Extension and Its Relation to Grasp Performance After Stroke

Functional properties of monkey motor cortex neurones receiving afferent input from the hand and fingers

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