The relative sensitivity to vibration of muscle receptors of the cat

Brown, M. Christian; Engberg, I.; Matthews, P. B. C.

doi:10.1113/jphysiol.1967.sp008330

Cited by 418 publications

(281 citation statements)

References 28 publications

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“…In previous studies, muscle vibration has been associated with high activation of various skin and subcutaneous receptors; further, it has been reported that the la-afferent of the agonist muscle also cause a very high level of activity (Baik & Lim, 2006;Brown et al, 1967;Cordo et al, 1998;Roll & Vedel, 1982). In the study of Sabin (2003), it was confirmed that the lower extremity muscles were activated by vibratory stimulation during gait, which was attributed to vibration activating la-afferent of muscle spindle.…”

Section: Discussionmentioning

confidence: 99%

The Effect of Short-term Muscle Vibration on Knee Joint Torque and Muscle Firing Patterns during a Maximal Voluntary Isometric Contraction

Lee¹,

Song²,

Ahn³

et al. 2017

Korean Journal of Sport Biomechanics

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Objective: To investigate the effect of short-term vibration frequencies on muscle force generation capabilities.Method: Six healthy participants were recruited for this study and only their dominant leg was tested. The subjects were tested under five conditions of vibration frequencies with constant amplitude: 0 Hz (no vibration), 30 Hz, 60 Hz, and 90 Hz, and the vibration amplitude was 10 mm for all frequency conditions. The vibration was applied to the rectus femoris (RF). The subjects were then instructed to maintain a steadystate isometric knee joint torque (100 Nm) for the first 6 s. After the steady-state torque production, the subjects were required to produce isometric knee joint torque by leg extension as hard as possible with a start signal within the next 3 s. The vibration was applied for ~4 s starting from 1 s before initiation of the change in the steady-state knee joint torque. Results:The results showed that the maximum voluntary torque (MVT) of the knee joint increased with the vibration frequencies. On average, the MVTs were 756.47 Nm for 0 Hz (no vibration) and 809.61 Nm for 90 Hz. There was a significant positive correlation (r = 0.71) between the MVTs and integrated electromyograms (iEMGs). Further, the co-contraction indices (CCIs) were computed, which represent the ratio of the iEMGs of the antagonist muscle to the iEMGs of all involved muscles. There was a significant negative correlation (r = 0.62) between the CCIs and MVTs, which was accompanied by a significant positive correlation (r = 0.69) between the iEMGs of the vibrated muscle (RF). There was no significant correlation between the MVTs and iEMGs of the antagonist muscle. Conclusion:The results of this study suggest that the short-term vibration on the muscle increases the level of muscle activation possibly owing to the increased Ia afferent activities, which enhances the muscle force generation capability.

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Section: Discussionmentioning

confidence: 99%

The Effect of Short-term Muscle Vibration on Knee Joint Torque and Muscle Firing Patterns during a Maximal Voluntary Isometric Contraction

Lee¹,

Song²,

Ahn³

et al. 2017

Korean Journal of Sport Biomechanics

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“…5. The size of the reflex tension from TVR-f relation depends on the discharge frequency of the unitary EMG, which occurs according to the principle of the integer multiplication of original vibratory cyclic time.It has been demonstrated in cat musclethat primary spindle endings are much more sensitive to muscle vibration than secondary endings, their maximal response frequency being around 400Hz (GRANIT and HENATSCH, 1956;BESSOU and LAPORT, 1962;BIANCONI and VAN DER MEULEN, 1963;BROWN et al, 1967). It has also been reported by several authors that group Ia afferent discharges elicited by sinusoidal stretch activate the spinal motoneuron monosynaptically (MATTHEWS, 1966;HOMMA et al, 1967).…”

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confidence: 93%

Tonic Vibration Reflex in Human and Monkey Subjects

1971

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Summary 1. Both in human subjects and monkeys, the tonic vibration reflex, TVR, was observed during vibratory stimulation of the muscle. In the latter, TVR reaches its maximum soon after vibratory application. 2. In the monkey, unitary EMG was recorded during vibratory stimulation and nonsequential interspike interval histograms were obtained. Intervals of unitary EMG were shown to occur on the principle of integer multiplication of the vibratory cyclic time. 3. A gradual increase or decrease of TVR during vibratory stimulation in the human subject or the monkey is effected by the EMG discharges of shorter or longer firing intervals which occur on this principle. 4. Both in human subjects and monkeys, the TVR becomes larger with the higher range of vibratory frequency. Beyond a certain vibratory frequency the TVR shows a gradual decrease. The relationship between the TVR and the vibratory frequency was called the TVR-f relation. There is an optimal frequency of vibratory stimulation for producing the largest TVR tension. 5. The size of the reflex tension from TVR-f relation depends on the discharge frequency of the unitary EMG, which occurs according to the principle of the integer multiplication of original vibratory cyclic time.It has been demonstrated in cat musclethat primary spindle endings are much more sensitive to muscle vibration than secondary endings, their maximal response frequency being around 400Hz (GRANIT and HENATSCH, 1956;BESSOU and LAPORT, 1962;BIANCONI and VAN DER MEULEN, 1963;BROWN et al., 1967). It has also been reported by several authors that group Ia afferent discharges elicited by sinusoidal stretch activate the spinal motoneuron monosynaptically (MATTHEWS, 1966;HOMMA et al., 1967).Vibration of the muscle tendon in awake human subject causes a gradual

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“…Neurons were considered to respond to activated muscle proprioceptors when they (1) were sensitive to sinusoidal muscle stretching (Lundberg and Winsbury, 1960;Bianconi and van der Meulen, 1963;Brown et al, 1967;Matthews and Stein, 1969;Stuart et al, 1970;Mackie et al, 1998), showing a tight phase locking at the tested frequencies of 130 -135 Hz (Mackie et al, 1998); (2) produced spike bursting during stretching, a rapid drop in discharge on completion of the dynamic phase of stretching, and then a relatively slow drop during the holding phase (Matthews, 1933;Harvey and Matthews, 1961;Matthews, 1981;Edin and Vallbo, 1990); and (3) showed silenced firing during muscle shortening (stretch release) (Matthews, 1981;Edin and Vallbo, 1990;Grill and Hallet, 1995). It became clear during the first successful experiments in three distinct animals that cells responding in a 1:1 fashion to 130 -135 Hz muscular sinusoidal vibration also responded to manual muscle stretch (by flexing or extending the appropriated articulation), showing bursting discharges during the dynamic phase of stretching followed by a fall in discharge rate during holding and silenced firing during shortening.…”

Section: Methodsmentioning

confidence: 99%

Processing Afferent Proprioceptive Information at the Main Cuneate Nucleus of Anesthetized Cats

Leiras¹,

Velo²,

Martín-Cora³

et al. 2010

J. Neurosci.

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Medial lemniscal activity decreases before and during movement, suggesting prethalamic modulation, but the underlying mechanisms are largely unknown. Here we studied the mechanisms underlying proprioceptive transmission at the midventral cuneate nucleus (mvCN) of anesthetized cats using standard extracellular recordings combined with electrical stimulation and microiontophoresis. Dual simultaneous recordings from mvCN and rostroventral cuneate (rvCN) proprioceptive neurons demonstrated that microstimulation through the rvCN recording electrode induced dual effects on mvCN projection cells: potentiation when both neurons had excitatory receptive fields in muscles acting at the same joint, and inhibition when rvCN and mvCN cells had receptive fields located in different joints. GABA and/or glycine consistently abolished mvCN spontaneous and sensory-evoked activity, an effect reversed by bicuculline and strychnine, respectively; and immunohistochemistry data revealed that cells possessing strychnine-sensitive glycine receptors were uniformly distributed throughout the cuneate nucleus. It was also found that proprioceptive mvCN projection cells sent ipsilateral collaterals to the nucleus reticularis gigantocellularis and the mesencephalic locomotor region, and had slower antidromic conduction speeds than cutaneous fibers from the more dorsally located cluster region.The data suggest that (1) the rvCN-mvCM network is functionally related to joints rather than to single muscles producing an overall potentiation of proprioceptive feedback from a moving forelimb joint while inhibiting, through GABAergic and glycinergic interneurons, deep muscular feedback from other forelimb joints; and (2) mvCN projection cells collateralizing to or through the ipsilateral reticular formation allow for bilateral spreading of ascending proprioceptive feedback information.

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The relative sensitivity to vibration of muscle receptors of the cat

Cited by 418 publications

References 28 publications

The Effect of Short-term Muscle Vibration on Knee Joint Torque and Muscle Firing Patterns during a Maximal Voluntary Isometric Contraction

The Effect of Short-term Muscle Vibration on Knee Joint Torque and Muscle Firing Patterns during a Maximal Voluntary Isometric Contraction

Tonic Vibration Reflex in Human and Monkey Subjects

Processing Afferent Proprioceptive Information at the Main Cuneate Nucleus of Anesthetized Cats

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