Journal ArticleDOI
Cerebral potentials and leg muscle e.m.g. responses associated with stance perturbation
TLDR
It was concluded that the leg muscle e.m. reactions are mediated by a polysynaptic spinal reflex pathway which depends on a supraspinal control and the cerebral potentials seem to represent afferent signals which can be supposed to be subjected to modification and processing by suPRaspinal motor centres, according to the actual requirements.Abstract:
In order to investigate the neuronal mechanisms underlying the compensatory movements following stance disturbance, leg muscle e.m.g. responses and cerebral potentials evoked by a treadmill acceleration impulse were analysed. It was found that the displacement was followed by a cerebral potential of a latency of 40–45 ms and EMG responses in the calf muscles at a latency of 65–70 ms. The e.m.g. responses represented specific compensatory reactions to the mode of perturbation (with a gastrocnemius activation following positive acceleration but a tibialis ant. activation following negative acceleration). The cerebral potentials, however, showed a common pattern to both conditions. In addition, the leg muscle e.m.g. reactions were not altered by learning effects and by forewarning of displacement onset, while the amplitude of the cerebral potentials was significantly smaller in these conditions compared to those produced in response to randomly induced perturbations. It was therefore concluded that the leg muscle e.m.g. reactions are mediated by a polysynaptic spinal reflex pathway which depends on a supraspinal control. The cerebral potentials seem to represent afferent signals which can be supposed to be subjected to modification and processing by supraspinal motor centres, according to the actual requirements.read more
Citations
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Journal ArticleDOI
Dynamic Sensorimotor Interactions in Locomotion
TL;DR: Together these mechanisms contribute to the continuous dynamic adjustment of sensorimotor interactions, ensuring that the central program and feedback mechanisms are congruous during locomotion.
Journal ArticleDOI
Center of mass velocity-position predictions for balance control
Yi-Chung Pai,James L. Patton +1 more
TL;DR: These findings expand the long-held concept that balance is based on CM position limits (i.e. the horizontal CM position has to be confined within the BOS to guarantee stable standing) to a concept based onCM velocity-position limits.
Journal ArticleDOI
Cortical control of postural responses.
Jesse V. Jacobs,Fay B. Horak +1 more
TL;DR: The cerebral cortex likely influences longer latency postural responses both directly via corticospinal loops and indirectly via communication with the brainstem centers that harbor the synergies for postural responding, thereby providing both speed and flexibility for pre-selecting and modifying environmentally appropriate responses to a loss of balance.
Journal ArticleDOI
Cognitive demands and cortical control of human balance-recovery reactions
Brian E. Maki,William E. McIlroy +1 more
TL;DR: This review is to summarize recent literature pertaining to the cognitive demands and cortical control of balance-recovery reactions, focussing on five emerging sources of evidence.
Journal ArticleDOI
Afferent control of human stance and gait: evidence for blocking of group I afferents during gait.
TL;DR: It is concluded that during gait the signals of group I afferents are blocked at both segmental and supraspinal levels which was tested by tibial nerve stimulation, and it is suggested that the e.g. and leg muscle e.m. responses induced in the leg by gait perturbations are evoked by group II afferentials and mediated via a spinal pathway.
References
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OtherDOI
Control of Locomotion in Bipeds, Tetrapods, and Fish
TL;DR: The sections in this article are:==================PREGNSSI and EMG information as mentioned in this paper, Biomechanical and Electromyographical Information, Biophysics, Physiology and Physiological Information.
OtherDOI
Integration in Spinal Neuronal Systems
TL;DR: The sections in this article are: Methodological Considerations, General Summary and Epilogue, Ascending Pathways that Monitor Segmental Interneuronal Activity, and Evidence That Ascending FRA Pathways Monitor Activity in interneurons of Reflex Pathways.
Journal ArticleDOI
Neuronal mechanisms of human locomotion
TL;DR: The surface electromyogram of human leg muscles was recorded during running at different speeds and indicated that a spinal stretch reflex could become mechanically effective within the shortest stance phase measured in a fast sprint.
Journal ArticleDOI
Gating of somatosensory evoked potentials during different kinds of movement in man
Rushton Dn,Rothwell Jc,Craggs +2 more
TL;DR: It is concluded that a gating action is exerted in the brain on somatosensory afferent activity, after it first reaches the cortex, and that this gatingaction associated with movement is controlled by other afferent signals from the stimulated limb, and particularly from the stimulating digit.
Journal ArticleDOI
Corrective reactions to stumbling in man: neuronal co-ordination of bilateral leg muscle activity during gait.
Wiltrud Berger,Dietz,Quintern J +2 more
TL;DR: Electromyogram responses of lower leg muscles, and corresponding movements were studied following a perturbation of the limb during walking, produced by either a randomly timed, short acceleration or decelerating impulse applied to the treadmill, or a unilateral triceps surae contraction induced by tibial nerve stimulation.