Kinematic determinants of human locomotion.

1. The aim of this study was to find kinematic patterns that are invariant across the normal range of locomotion speeds. Subjects walked at different, freely chosen speeds ranging from 0.9 to 2.1 m s‐1, while motion and ground reaction forces on the right side of the body were recorded in three‐dimensional space. 2. The time course of the anatomical angles of flexion‐extension at the hip and ankle was variable not only across subjects, but even from trial to trial in the same subject. By contrast, the time course of the changes in the angles of elevation of each limb segment (pelvis, thigh, shank and foot) relative to the vertical was stereotyped across subjects. 3. To compare the waveforms across speeds, data were scaled in time relative to gait cycle duration. The pattern of ground reaction forces was highly speed dependent. Several distinct families of curves could be recognized in the flexion‐extension angles at the hip and ankle. Instead, the waveforms of global length and elevation of the limb, elevation angles of all limb segments and flexion‐extension at the knee were invariant with speed. 4. When gait trajectories at all speeds are plotted in the position space defined by the elevation angles of the limb segments, they describe regular loops on a plane. The statistical characteristics of these angular covariations were quantified by means of principal component analysis. The first two principal components accounted together for > 99% of the total experimental variance, and were quantitatively comparable in all subjects. 5. This constraint of planar covariation of the elevation angles is closely reminiscent of that previously described for the control of posture. The existence of laws of intersegmental co‐ordination, common to the control of posture and locomotion, presumably assures the maintenance of dynamic equilibrium during forward progression, and the anticipatory adaptation to potentially destabilizing factors by means of co‐ordinated kinematic synergies of the whole body.

[1]  W. A. Petersen,et al.  POSTURAL STABILITY IN THE DOG. , 1965, The American journal of physiology.

[2]  N. A. Bernshteĭn The co-ordination and regulation of movements , 1967 .

[3]  O. I. Fukson,et al.  Recordings of neurones of the dorsal spinocerebellar tract during evoked locomotion. , 1972, Brain research.

[4]  G. Cavagna,et al.  The sources of external work in level walking and running. , 1976, The Journal of physiology.

[5]  J. F. Soechting,et al.  The role of vision in the control of posture during linear motion. , 1979, Progress in brain research.

[6]  S. Grillner Control of Locomotion in Bipeds, Tetrapods, and Fish , 1981 .

[7]  O. Pompeiano,et al.  Convergence and interaction of neck and macular vestibular inputs on vestibulospinal neurons. , 1981, Journal of neurophysiology.

[8]  J. F. Soechting,et al.  Psychophysical determination of coordinate representation of human arm orientation , 1984, Neuroscience.

[9]  L. Nashner,et al.  The organization of human postural movements: A formal basis and experimental synthesis , 1985, Behavioral and Brain Sciences.

[10]  J. F. Soechting,et al.  Path constraints on point-to-point arm movements in three-dimensional space , 1986, Neuroscience.

[11]  J. F. Soechting,et al.  Coordination of arm movements in three-dimensional space. Sensorimotor mapping during drawing movement , 1986, Neuroscience.

[12]  J Quintern,et al.  Stumbling reactions in man: significance of proprioceptive and pre‐programmed mechanisms. , 1987, The Journal of physiology.

[13]  M. Pandy,et al.  Quantitative assessment of gait determinants during single stance via a three-dimensional model--Part 1. Normal gait. , 1989, Journal of biomechanics.

[14]  R. M. Alexander,et al.  Optimization and gaits in the locomotion of vertebrates. , 1989, Physiological reviews.

[15]  S. Grillner,et al.  Visuomotor coordination in reaching and locomotion. , 1989, Science.

[16]  F Lacquaniti,et al.  The control of limb geometry in cat posture. , 1990, The Journal of physiology.

[17]  G. Ferrigno,et al.  An algorithm for 3-D automatic movement detection by means of standard TV cameras , 1990, IEEE Transactions on Biomedical Engineering.

[18]  D. Armstrong,et al.  Changes in the discharge patterns of motor cortical neurones associated with volitional changes in stepping in the cat , 1990, Neuroscience Letters.

[19]  H Forssberg,et al.  Phase-dependent modulations of anticipatory postural activity during human locomotion. , 1991, Journal of neurophysiology.

[20]  V. J. Wilson Vestibulospinal and neck reflexes: interaction in the vestibular nuclei. , 1991, Archives italiennes de biologie.

[21]  P R Cavanagh,et al.  Three-dimensional kinematics of the human knee during walking. , 1992, Journal of biomechanics.

[22]  J. Massion Movement, posture and equilibrium: Interaction and coordination , 1992, Progress in Neurobiology.

[23]  Response of pontomedullary reticulospinal neurons to vestibular stimuli in vertical planes. Role in vertical vestibulospinal reflexes of the decerebrate cat. , 1992, Journal of neurophysiology.

[24]  R E Poppele,et al.  Broad directional tuning in spinal projections to the cerebellum. , 1993, Journal of neurophysiology.

[25]  D. Winter,et al.  Control of whole body balance in the frontal plane during human walking. , 1993, Journal of biomechanics.

[26]  A. Minetti,et al.  The transition between walking and running in humans: metabolic and mechanical aspects at different gradients. , 1994, Acta physiologica Scandinavica.

[27]  F. Lacquaniti,et al.  Independent control of limb position and contact forces in cat posture. , 1994, Journal of neurophysiology.

[28]  F. Lacquaniti,et al.  Coordinate transformations in the control of cat posture. , 1994, Journal of neurophysiology.

[29]  C D Mah,et al.  Quantitative analysis of human movement synergies: constructive pattern analysis for gait. , 1994, Journal of motor behavior.

[30]  F. Lacquaniti,et al.  Representing spatial information for limb movement: role of area 5 in the monkey. , 1995, Cerebral cortex.