Abstract
This article focuses on postural anticipation and multi-joint coordination during locomotion in healthy and autistic children. Three questions were addressed: (1) Are gait parameters modified in autistic children? (2) Is equilibrium control affected in autistic children? (3) Is locomotion adjusted to the experimenter-imposed goal? Six healthy children and nine autistic children were instructed to walk to a location (a child-sized playhouse) inside the psychomotor room of the pedopsychiatric centre located approximately 5 m in front of them. A kinematic analysis of gait (ELITE system) indicates that, rather than gait parameters or balance control, the main components affected in autistic children during locomotion are the goal of the action, the orientation towards this goal and the definition of the trajectory due probably to an impairment of movement planning.
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References
G. I. Allen N. Tsukahara (1974) ArticleTitleCerebrocerebellar communication systems Physiological Reviews 54 957–1006
Assaiante, C., Thomachot, B., Aurenty, R., & Amblard, B. (1998). Organization of lateral balance control in toddlers during the first year of independent walking. Journal of Motor Behaviour, 114–129.
C. Assaiante (1998) ArticleTitleDevelopment of locomotor balance control in healthy children. [Review] Neuroscience and Biobehavioural Reviews 22 527–532
C. Assaiante B. Amblard (1995) ArticleTitleAn ontogenetic model for the sensorimotor organization of balance control in humans Human Movement Science 14 13–43
C. Assaiante B. Amblard (1993) ArticleTitleOntogenesis of head stabilization in space during locomotion in children: Influence of visual cues Experimental Brain Research 93 499–515
C. Assaiante B. Thomachot R. Aurenty (1993) ArticleTitleHip stabilization and lateral balance control in toddlers during the first four months of autonomous walking Neuroreport 4 875–878
C. Barthelemy N. Bruneau J. M. Cottet-Eymard J. Jouve B. Garreau G. Lelord J. P. Muh L. Peyrin (1988) ArticleTitleUrinary free and conjugated catecholamines and metabolites in autistic children Journal of Autism Developmental Disorder 18 583–591
N. Bernstein (1967) The coordination and regulation of movement Pergamon Press London
Berthoz A. (1991). Les systèmes sensorimoteurs: mècanismes et propriétés adaptives. In: Rapport du séminaire de prospective microgravité, “Sciences physiques et Sciences de la vie” du CNES. 1991; 22–27.
Y. Brenière B. Brill R. Fontaine (1989) ArticleTitleAnalysis of the transition from upright stance to steady state locomotion in children with under 200 days of autonomous walking Journal of Motor Behaviour 20 20–37
B. Bril Y. Brenière (1988) Do temporal invariances exist as early as the first six months of independent walking? B. Amblard A. Berthoz F. Clarac (Eds) Posture and Gait:␣Development, Adaptation and Modulation Elsevier Amsterdam 23–31
B. Bril Y. Brenière (1993) Posture and independent locomotion in early childhood: Learning to walk or learning dynamic postural control? G. Savelsberg (Eds) The Development of Co-ordination in Infancy Elsevier Amsterdam 337–358
R. G. Brown C. D. Marsden (1990) ArticleTitleCognitive function in Parkinson’s disease: From description to theory TINS 13 21–29
B. Bussel A. Roby-Bramy Ph. Azouvi A. Biraben A. Yakovleff J. P. Held (1988) ArticleTitleMyoclonus in a patient with spinal cord transection. Possible involvement of the spinal stepping generator Brain 111 1235–1245
J. L. Contreras-Vidal G. E. Stelmach (1995) ArticleTitleA neural model of basal ganglia-thalamocortical relations in normal and Parkinsonian movement Biological Cybernetics 73 467–476
E. Courchesne J. Townsend N. A. Akshoomoff O. Saitoh R. Yeung-Courchesne A. J. Lincoln H. E. James R. H. Haas L. Schreibman L. Lau (1994) ArticleTitleImpairment in shifting attention in autistic and cerebellar patients Behavioural Neuroscience 108 848–865
A. R. Damasio R. G. Maurer (1978) ArticleTitleA neurological model for childhood autism Archives of Neurology 35 777–786
G. Ferrigno A. Pedotti (1985) ArticleTitleELITE: A digital dedicated hardware system for movement analysis via real-time TV signal processing IEEE Transactions on Biomedical Engineering 32 943–950
H. Forssberg (1982) Spinal locomotor functions and descending control B. Sjolund A. Bjorklund (Eds) Brain Stem Control of Spinal Mechanisms Elsevier Biomedical Press Amsterdam
S. Grillner (1975) ArticleTitleLocomotion in vertebrates: Central mechanisms and reflex interaction Physiological Reviews 55 247–304
V. S. Gurfinkel Y. S. Levik O. V. Kazennikov V.␣A. Selionov (1998) ArticleTitleLocomotor-like movements evoked by leg muscle vibration in humans The European Journal of Neuroscience 10 1608–1612
G. E. Grossman R. J. Leigh L. A. Abel D. J. Lanska S. E. Thurston (1988) ArticleTitleFrequency and velocity of rotational head perturbation during locomotion Experimental Brain Research 70 470–476
T. Hashimoto M. Tayama M. Miyazaki K. Murakawa S. Shimakawa Y. Yoneda Y. Kuroda (1993a) ArticleTitleBrainstem involvement in high functioning autistic children Acta Neurologica Scandinavica 88 123–128
T. Hashimoto M. Tayama M. Miyazaki K. Murakawa Y. Kuroda (1993b) ArticleTitleBrainstem and cerebellar vermis involvement in autistic children Journal of Child Neurology 8 149–153
M. Hallett M. K. Lebiedowska S. L. Thomas S. J. Stanhope M. B. Denckla J. Rumsey (1993) ArticleTitleLocomotion of autistic adults Archives of Neurology 50 1304–1308
V. Jones M. Prior (1985) ArticleTitleMotor imitation abilities and neurological signs in autistic children Journal of Autism Developmental Disorders 15 37–46
L. Kanner (1943) ArticleTitleAutistic disturbances of affective contact Nervous Child 2 217–250
R. Kohen-Raz F. R. Volkmar D. J. Cohen (1992) ArticleTitlePostural control in children with autism Journal of Autism Developmental Disorders 22 419–432
G. Lelord B. Garreau C. Barthelemy N. Bruneau D. Sauvage (1986) ArticleTitleNeurological aspects of infantile autism. [Review] Encephale 12 71–76.
J. Massion (1997) Cerveau et Motricité. Fonctions sensori-motrices Presses universitaires de France Paris
R. G. Maurer A. R. Damasio (1982) ArticleTitleChildhood autism from the point of view of behavioral neurology Journal Autism Developmental Disorders 12 195–205
B. Milner L. R. Squire E. R. Kandel (1998) ArticleTitleCognitive neuroscience and the study of memory Neuron 20 445–468
N. J. Minshew B. Luna J. A. Sweeney (1999) ArticleTitleOculomotor evidence for neocortical systems but not cerebellar dysfunction in autism Neurology 52 917–922
T. Ohnishi H. Matsuda T. Hashimoto T. Kunihiro M. Nishikawa T. Uema M. Sasaki (2000) ArticleTitleAbnormal regional cerebral blood flow in childhood autism Brain 123 1838–1844
E. M. Ornitz (1974) ArticleTitleThe modulation of sensory input and motor output in autistic children Journal of Autism Childhood Schizophrenia 4 197–215
Patla, A. E. (1991). Adaptability of human gait. Implication for the control of locomotion. In G. E. Stelmach, & P. A. Vroon (Eds.), Advances in Psychology. North-Holland, Amsterdam, New York, Oxford, Tokyo, 78, 3–17
Plumet, M. H., Hughes C., Tardif C., & Mouren-Siméoni M. C. (1998). L’hypothèse d’un déficit des fonctions exécutives dans l’autisme. In J. Nadel B. Rogé, (Eds.), Psychologie française, Autisme: l’option biologique 1. Recherche, Presses universitaires de Grenoble 43, 157–167
T. Pozzo A. Berthoz L. Lefort (1990) ArticleTitleHead stabilization during various locomotor task in humans. I. Normal subject Experimental Brain Research 82 97–106
J. M. Rumsey M. Ernst (2000) ArticleTitleFunctional neuroimaging of autistic disorders Mental retardation and Developmental Disabilities Research Reviews 6 171–179
Schmitz, C., Martineau, J., Barthélémy, C., Assaiante, C. (2003). Motor control and children with autism: Deficit of anticipatory function? Neurosciences Letters, 4, 348(1), 17–20
L. I. Sears C. Vest S. Mohamed J. Bailey B. J. Ranson J. Piven (1999) ArticleTitleAn MRI study of the basal ganglia in autism Progress in Neuro-Psychopharmacology & Biological Psychiatry 23 613–624
P. Teitelbaum O. Teitelbaum J. Nye J. Fryman R. G. Maurer (1998) ArticleTitleFree in PMC Movement analysis in infancy may be useful for early diagnosis of autism Proceedings of the National Academy of Sciences of the United States of America 95 13982–13987
J. Townsend E. Courchesne J. Covington M. Westerfield N. S. Harris P. Lyden T. P. Lowry G. A. Press (1999) ArticleTitleSpatial attention deficits in patients with acquired or developmental cerebellar abnormality Journal of Neuroscience 19 5632–5643
J. A. Vilensky A. R. Damasio R. G. Maurer (1981) ArticleTitleGait disturbances in patients with autistic behavior: A preliminary study Archives of Neurology 38 646–649
D. A. Winter (1991) The biomechanics and motor control of human gait: Normal elderly and pathological EditionNumber2 University of Waterloo Press Waterloo
M. H Woollacott C. Assaiante B. Amblard (1996) Development of balance and gait control A. M. Bronstein T. Brandt M. H. Woollacott (Eds) Disorders of balance, posture and gait Arnold London 41–63
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Vernazza-Martin, S., Martin, N., Vernazza, A. et al. Goal Directed Locomotion and Balance Control in Autistic Children. J Autism Dev Disord 35, 91–102 (2005). https://doi.org/10.1007/s10803-004-1037-3
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DOI: https://doi.org/10.1007/s10803-004-1037-3