Vestibulospinal Adaptation to Microgravity

Human balance control is known to be transiently disrupted after spaceflight; however, the mechanisms responsible for postflight postural ataxia are still under investigation. In this report, we propose a conceptual model of vestibulospinal adaptation based on theoretical adaptive control concepts and supported by the results from a comprehensive study of balance control recovery after spaceflight. The conceptual model predicts that immediately after spaceflight the balance control system of a returning astronaut does not expect to receive gravity-induced afferent inputs and that descending vestibulospinal control of balance is disrupted until the central nervous system is able to cope with the newly available vestibular otolith information. Predictions of the model are tested using data from a study of the neurosensory control of balance in astronauts immediately after landing. In that study, the mechanisms of sensorimotor balance control were assessed under normal, reduced, and/or altered (sway-referenced) visual and somatosensory input conditions. We conclude that the adaptive control model accurately describes the neurobehavioral responses to spaceflight and that similar models of altered sensory, motor, or environmental constraints are needed clinically to predict responses that patients with sensorimotor pathologies may have to various visual-vestibular or changing stimulus environments.

[1]  A. Berthoz,et al.  Visual contribution to rapid motor responses during postural control , 1978, Brain Research.

[2]  Millard F. Reschke,et al.  Spaceflight-induced changes in posture and locomotion , 1994 .

[3]  I B Kozlovskaya,et al.  Pathophysiology of motor functions in prolonged manned space flights. , 1981, Acta astronautica.

[4]  J Massion,et al.  Postural changes accompanying voluntary movements. Normal and pathological aspects. , 1984, Human neurobiology.

[5]  F. O. Black,et al.  Abnormal postural control associated with peripheral vestibular disorders. , 1988, Progress in brain research.

[6]  M F Reschke,et al.  Vestibular plasticity following orbital spaceflight: recovery from postflight postural instability. , 1995, Acta oto-laryngologica. Supplementum.

[7]  F. O. Black,et al.  Adaptation to altered support and visual conditions during stance: patients with vestibular deficits , 1982, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[8]  M F Reschke,et al.  Postural equilibrium following exposure to weightless space flight. , 1977, Acta oto-laryngologica.

[9]  Young Lr Adaptation to modified otolith input. , 1985 .

[10]  G. Bruyn Posture and gait: Development, adaptation and modulation By Bernard Amblard, Alain Berthoz and François Clarac (eds.), Excerpta Medica, Amsterdam-New York-Oxford, 1988, ICS 812, Dfl. 265.00 , 1989, Journal of the Neurological Sciences.

[11]  M. F. Reschke,et al.  Neurosensory and sensory-motor functions , 1996 .

[12]  R. Held,et al.  Dissociation of the Visual Placing Response into Elicited and Guided Components , 1967, Science.

[13]  M F Reschke,et al.  Recovery of Postural Equilibrium Control following Spaceflight a , 1992, Annals of the New York Academy of Sciences.

[14]  M. H. Romberg Lehrbuch der Nervenkrankheiten des Menschen , 1857 .

[15]  Arnauld Nicogossian,et al.  Space Biology and Medicine , 1993 .

[16]  S. Wray Adaptive mechanisms in gaze control. , 1986, Reviews of oculomotor research.

[17]  M F Reschke,et al.  Otolith tilt-translation reinterpretation following prolonged weightlessness: implications for preflight training. , 1985, Aviation, space, and environmental medicine.