Changes in leg movements and muscle activity with speed of locomotion and mode of progression in humans.

Knowledge of adaptations to changes in speed and mode of progression (walking-running) in human locomotion is important for an understanding of underlying neural control mechanisms and allows a comparison with more detailed animal studies. Leg movements and muscle activity patterns were studied in ten healthy males (19-29 yr) during level walking (0.4-3.0 m X s-1) and running (1.0-9.0 m X s-1) on a motor-driven treadmill. Movements were recorded in the sagittal plane with a Selspot optoelectronic system. Recordings of EMG were made from seven different muscles of one leg by means of surface electrodes. Durations, amplitudes and relative phase relationships of angular displacements and EMG activity were analysed in relation to different phases of the stride cycle (defined by the leg movements). The durations of the entire stride cycle and of the support phase were found to decrease curvilinearly with velocity. Swing and support phase durations were linearly related to cycle duration in walking, and curvilinearly related in running. The characteristic occurrence of double support phases in walking was also seen in very slow running. Support length increased with speed up to about 1.2 m both in walking and running, but was longer in walking at the same velocity. Increases in net angular displacements were largest for hip movements and for knee flexion-extension during the swing phase in running. With increasing velocity a clear shift in relative rectus femoris activity occurred from knee extension to hip flexion. Gastrocnemius lateralis (LG) was co-activated with the other leg extensors prior to foot contact in running, whereas in walking LG was not turned on until later in the support phase. The ankle flexor tibialis anterior had its main peak of activity after touch-down in walking and before touch-down in running. The same basic structure of the stride cycle as in other animals suggests similarities in the underlying neural control. Human speed adaptation is distinguished primarily by an increase in both frequency and amplitude of leg movements and by a possibility of changing between a walking and a running type of movement pattern.

[1]  D. Grieve,et al.  The relationships between length of stride, step frequency, time of swing and speed of walking for children and adults. , 1966, Ergonomics.

[2]  Murray Mp,et al.  Gait as a total pattern of movement. , 1967 .

[3]  D. B. Lucas,et al.  An in vivo study of the axial rotation of the human thoracolumbar spine. , 1967, The Journal of bone and joint surgery. American volume.

[4]  P. Rack,et al.  The effects of length and stimulus rate on tension in the isometric cat soleus muscle , 1969, The Journal of physiology.

[5]  I. Engberg,et al.  An electromyographic analysis of muscular activity in the hindlimb of the cat during unrestrained locomotion. , 1969, Acta physiologica Scandinavica.

[6]  J. Basmajian,et al.  Multifactorial analysis of walking by electromyography and computer. , 1971, American journal of physical medicine.

[7]  The Relation between Electrical Activity in Muscle and Speed of Walking and Running , 1971 .

[8]  S. Grillner The role of muscle stiffness in meeting the changing postural and locomotor requirements for force development by the ankle extensors. , 1972, Acta physiologica Scandinavica.

[9]  R. C. Nelson,et al.  Biomechanics of overground versus treadmill running. , 1972, Medicine and science in sports.

[10]  G. E. Goslow,et al.  The cat step cycle: Hind limb joint angles and muscle lengths during unrestrained locomotion , 1973, Journal of morphology.

[11]  T. Hoshikawa,et al.  Analysis of Running Pattern in Relation to Speed , 1973 .

[12]  C. Dillman Kinematic Analyses of Running , 1975, Exercise and sport sciences reviews.

[13]  M. L. Shik,et al.  Neurophysiology of locomotor automatism. , 1976, Physiological reviews.

[14]  Richard M. Herman,et al.  Human Solutions for Locomotion , 1976 .

[15]  G A Cavagna,et al.  STORAGE AND UTILIZATION OF ELASTIC ENERGY IN SKELETAL MUSCLE , 1977, Exercise and sport sciences reviews.

[16]  P. Stein Motor systems, with specific reference to the control of locomotion. , 1978, Annual review of neuroscience.

[17]  J. Halbertsma,et al.  Control of the trunk during walking in the cat. , 1979, Acta physiologica Scandinavica.

[18]  S. Grillner,et al.  The adaptation to speed in human locomotion , 1979, Brain Research.

[19]  V. Dietz,et al.  Neuronal mechanisms of human locomotion. , 1979, Journal of neurophysiology.

[20]  S. Grillner,et al.  The locomotion of the low spinal cat. I. Coordination within a hindlimb. , 1980, Acta physiologica Scandinavica.

[21]  S. Rossignol,et al.  The locomotion of the low spinal cat. II. Interlimb coordination. , 1980, Acta physiologica Scandinavica.

[22]  E Knutsson,et al.  Gait control in hemiparesis. , 1981, Scandinavian journal of rehabilitation medicine.

[23]  J M Halbertsma,et al.  On the processing of electromyograms for computer analysis. , 1981, Journal of biomechanics.

[24]  G A Cavagna,et al.  Mechanics of competition walking. , 1981, The Journal of physiology.

[25]  A. Thorstensson,et al.  Lumbar back muscle activity in relation to trunk movements during locomotion in man. , 1982, Acta physiologica Scandinavica.

[26]  P. Komi,et al.  Mechanical efficiency of positive work in running at different speeds. , 1983, Medicine and science in sports and exercise.

[27]  J. Halbertsma The stride cycle of the cat: the modelling of locomotion by computerized analysis of automatic recordings. , 1983, Acta physiologica Scandinavica. Supplementum.

[28]  S. Grillner,et al.  The effect of dorsal root transection on the efferent motor pattern in the cat's hindlimb during locomotion. , 1984, Acta physiologica Scandinavica.

[29]  V P Stokes,et al.  A new method to measure foot contact. , 1985, Journal of biomechanics.