Abstract
Motion sickness is induced during passive locomotion in vehicles and is generated either by unfamihar bodily accelerations, to which the person has therefore not adapted, or by intersensory mismatch involving conflicting vestibular and visual stimuli (Dichgans and Brandt 1973, 1978; Benson 1977; Reason 1978; Brandt and Daroff 1980). According to the “mismatch theory”; (see also p. 3), spatial orientation and perception of movement are disturbed by a conflict between stimuli when the multisensory motion signals do not correspond to the expected pattern of sensory signals established from earlier experience with active locomotion. This may give rise to unpleasant illusions of movement with consequences of posture and the control of vehicles (Dichgans and Brandt 1978; Leibowitz et al. 1982) and to motion sickness as a result of summation. Thus, motion sickness is not a superfluous epiphenomenon of vestibular stimulation but — in a teleological sense — it represents a meaningful warning signal to withdraw the body from unusual stimulus situations which cannot be integrated with adequate dynamic spatial orientation. The first known reports on seasickness originate from Hippocrates. The major symptom of nausea is derived from the Greek word “naus” for ship. The general term “motion sickness” was coined by Irwin (1881). It stresses the phenomenological similarity of air-, sea-, car-, and space-sickness despite their different modes of provocation.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Armstrong HG (1939) Principles and practice of aviation medicine. Williams and Wilkins
Baltimore Babkin BP, Bornstein MB (1943) The effect of swinging and of binaural galvanic stimulation on the motility of the stomach in dogs. Rev Can Biol 2:336
Banta GR, Ridley WC, McHugh J, Grissett JD, Guedry FE (1987) Aerobic fitness and susceptibility to motion sickness. Aviat Space Environ Med 58:105–108
Barabas G, Matthews WS, Ferrari M (1984) Motion sickness in children with Tourette’s syndrome. Ann Neurol 15:309
Baumgarten von RJ, Thiimler R (1979) A model for vestibular function in altered gravitational states. In: Holmquist R (ed) (Cospar) Life sciences and space research. Pergamon Press, Oxford, pp 161–170
Baumgarten RJ von, Baldrighi G, Vogel H, Thümler R (1980) Physiological response to hyper-and hypogravity during rollercoaster flight. Aviat Space Environ Med 51:145–154
Benson AJ (1973) Physical characteristics of stimuli which induce motion sickness, a review. I AM Rep 532:1–20
Benson AJ (1977) Possible mechanisms of motion and space sickness. Proceedings of the European symposium on life sciences research in space. European Space Agency SP-130:101–108
Borison HL, Wang SC (1949) Functional localization of central coordinating mechanism for emesis in cat. J Neurophysiol 12:305–313
Brandt Th (1976) Optisch-vestibuläre Bewegungskrankheit, Höhenschwindel und klinische Schwindelformen. Fortschr Med 94:1177–1182
Brandt Th, Daroff RB (1980) The multisensory physiological and pathological vertigo syndromes. Ann Neurol 7:195–203
Brandt Th, Wist ER, Dichgans J (1971) Optisch induzierte Pseudo-Coriolis-Effekte und Circularvektion: Ein Beitrag zur optisch-vestibulären Interaktion. Arch Psychiatr Nervenkr 214:365–389
Brandt Th, Dichgans J, Wagner W (1974) Drug effectiveness on experimental optokinetic and vestibular motion sickness. Aerospace Med 45:1291–1297
Brandt Th, Wenzel D, Dichgans J (1976) Die Entwicklung der visuellen Stabilisation des aufrechten Standes beim Kind: Ein Reifezeichen in der Kinderneurologie. Arch Psychiatr Nervenkr 223:1–13
Brizzee KR, Igarashi M (1986) Effect of macular ablation on frequency and latency of motion-induced emesis in the squirrel monkey. Aviat Space Environ Med 57:1066–1070
Brizzee KR, Igarashi M (1986) Effect of macular ablation on frequency of latency of motion-induced emesis in the squirrel monkey. Aviat Space Environ Med 57:1066–1070
Brown JH, Crampton GH (1966) Concomitant visual stimulation does not alter habituation of nystagmic, oculogyral or psychophysical responses to angular acceleration. Acta Otolaryngol (Stockh) 61:80–91
Bruner JM (1955) Seasickness in a destroyer escort squadron. US Armed Forces Med J 6:469–490
Chinn HI, Smith PK (1955) Motion sickness. Pharmacol Rev 7:33–83
Colehour JK (1965) Stress measurements in normal and labyrinthine defective subjects in unusual force environments. In: The role of vestibular organs in the exploration of space. NASA, Sp-77, Washington DC, pp 347–355
Collins WE, Schroeder DJ, Elam GW (1982) A comparison of some effects of three antimotion sickness drugs on nystagmic responses to angular accelerations and to optokinetic stimuli. Aviat Space Environ Med 53:1182–1189
Cowings PS, Toscano WB (1982) The relationship of motion sickness susceptibility to learned autonomic control for symptom suppression. Aviat Space Environ Med 53:570–575
Crum Brown A (1874) On the sense of rotation and the anatomy and physiology of the semicircular canal of the internal ear. J Anat Physiol 8:327–331
Cummings AJ (1958) The physiology of symptoms: III Nausea and vomiting. Am J Digest Dis 3:710–721
Desnoes Ph (1926) Seasickness. J Am Med Assoc 86:319–324
Dichgans J, Brandt Th (1973) Optokinetic motion sickness and pseudo-Coriolis-effects induced by moving visual stimuli. Acta Otolaryngol (Stockh) 76:339–348
Dichgans J, Brandt Th (1978) Visual-vestibular interaction: Effects on self-motion perception and postural control. In: Held R, Leibowitz HW, Teuber HL (eds) Handbook of sensory physiology, vol VIII, Perception. Springer, Berhn Heidelberg New York, pp 755–804
Fukuda T (1975) Postural behaviour in motion sickness. Acta Otolaryngol (Stockh) 330:9–14
Gay LN, Carliner PE (1949) The prevention and treatment of motion sickness. I. Sea sickness. Bull Johns Hopkins Hosp 84:470–487
Goltz F (1870) Über die physiologische Bedeutung der Bogengänge des Ohrlabyrinths. Pflügers Arch Ges Physiol 3:172–192
Graybiel A (1964) Vestibular sickness and some of its implications for space flight. In: Fields WS, Alfords BR (eds) Neurological aspects of auditory and vestibular disorders. CC Thomas, Springfield, chap. XI
Graybiel A (1970) Susceptibility to acute motion sickness in blind persons. Aerospace Med 41:650–653
Graybiel A (1979) Prevention and treatment of space sickness in shuttle-orbiter missions. Aviat Space Environ Med 50:171–176
Graybiel A, Wood CD, Miller EF, Cramer DB (1968) Diagnostic criteria for grading the severity of acute motion sickness. Aerospace Med 39:453–455
Graybiel A, Miller EF, Homick JL (1977) Experiment M 131: Human vestibular function. In: Biomedical results from skylab, NASA Sp. 377, Washington DC, pp 74–103
Guedry SE (1965) Orientation of the rotation-axis relative to gravity: its influence on nystagmus and the sensation of rotadon. Acta Otolaryngol (Stockh) 60:30–48
Hill J (1937) The care of the seasick. Br Med J:802–807
Hoist E von, Mittelstaedt H (1950) Das Reafferenzprinzip (Wechselwirkungen zwischen Zentralnervensystem und Peripherie). Naturwissenschaften 37:464–476
Igarashi M, Isago H, O-Uchi T, Kulecz WB, Homick JL, Reschke MF (1983) Vestibular-visual conflict sickness in the squirrel monkey. Acta Otolaryngol (Stockh) 95:193–198
Igarashi M, Kobayashi K, Kulecz WB, Isago H (1986a) Vestibular-visual conflict in pitch and yaw planes in the squirrel monkey. Aviat Space Environ Med 57:1071–1074
Igarashi M, Kobayashi K, Kulecz WV, Himi T (1986b) Changes in susceptibility to vestibular-visual conflict sickness in monkeys by repeated exposure. Acta Otolaryngol (Stockh) 102:432–437
Irwin JA (1881) The pathology of seasickness. Lancet 11:907–909
Isaacs B (1957) The influence of head and body position on the emetic action of apomorphine in man. Clin Sci 16:215–221
James W (1882) The sense of dizziness in deaf-mutes. Am J Otol 4:239–254
Johnson WH, Taylor NBG (1961) The importance of head movements in studies involving stimulation of the organ of balance. Acta Otolaryngol (Stockh) 53:211–218
Johnson WH, Meek JC, Graybiel A (1962) Effects of labyrinthectomy on canal sickness in squirrel monkey. Ann Otol Rhinol Laryngol 71:289–298
Kennedy RS, Graybiel A, McDonough RC, Beckwith FD (1968) Symptomatology under storm conditions in the North Atlantic in control subjects and in persons with bilateral labyrinth defects. Acta Otolaryngol (Stockh) 66:533–540
Kurashvili AE (1963) Vestibular reactivity during the cumulative action of slow centripetal accelerations. Office of Technical Services, FTD-MT-63–179
Lackner JR, Graybiel A (1974) Elicitation of vestibular side effects by regional vibration of the head. Aerospace Med 45:1267–1272
Lackner JR, Graybiel AN (1979) Some influences of vision on susceptibility to motion sickness. Aviat Space Environ Med 50:1122–1125
Lackner JR, Graybiel A (1986a) Sudden emesis following parabolic flight maneuvers: implications for space motion sickness. Aviat Space Environ Med 57:343–347
Lackner JR, Graybiel A (1986b) Head movements in non-terrestrial force environments elicit motion sickness: implications for the etiology of space motion sickness. Aviat Space Environ Med 57:443–448
Lawther A, Griffin MJ (1988) A survery of the occurrence of motion sickness amongst passengers at sea. Aviat Space Environ Med 59:399–406
Leger A, Money KE, Landolt JP, Cheung BS, Rodden BE (1981) Motion sickness caused by rotations about earth-horizontal and earth-vertical axes. J Appl Physiol 50:469–477
Leibowitz HW, Post RB, Brandt Th, Dichgans J (1982) Implications of recent developments in dynamic spatial orientation and visual resolution for vehicle guidance. In: Wertheim AH, Wagenaar WA, Leibowitz HW (eds) Tutorials on motion perception. Plenum Press, New York, pp 231–260
Leigh RJ, Daroff RB (1985) Space motion sickness: Etiological hypotheses and a proposal for diagnostic clinical examination. Aviat Space Environ Med 56:469–473
Llano GA (1955) Airmen against the sea – an analysis of sea survival experiences. Maxwell AFB, Research Studies Institute, ADTIC Publ G-104
Mach E (1875) Grundlinien der Lehre von den Bewegungsempfindungen. Engelmann, Leipzig
Manning GW, Steward WG (1949) Effect of body position on incidence of motion sickness. J Appl Physiol 1:619–628
Marshall JE, Brown JH (1966) Visual arousal interaction and specificity of nystagmic habituation. US Army Medical Research Laboratory, Fort Knox, Rept No 688
McCauley ME (1984) Research issues in simulator sickness. Proceedings of a workshop. National Academy Press, Washington
McNally WJ, Stuart EA, Morton G (1942) Effect of labyrinthectomy on motion sickness in animals. In: Proceedings of the conference on motion sickness. National Research Council of Canada, Toronto, Rept No. C-748
Mehler WR (1983) Observations on the connectivity of the parvicellular reticular formation with respect to a vomiting center. Brain Behav Evol 23:63–80
Melvill Jones G, Mandl G (1980) “Motion” sickness due to vision reversal: its disappearance in stroboscopic light. Ann NY Acad Sci 374:303–311
Miller EF, Graybiel A (1972) Semicircular canals as a primary etiological factor in motion sickness. Aerospace Med 43:1065–1074
Money KE (1970) Motion sickness. Physiol Rev 50:1–39
Money KE, Cheung BS (1983) Another function of the inner ear: facilitation of the emetic response to poisons. Aviat Space Environ Med 54:208–211
Money KE, Friedberg J (1964) The role of the semicircular canals in causation of motion sickness and nystagmus in the dog. Can J Physiol Pharmacol 42:793–801
Oman CM (1982) A heuristic mathematical model for the dynamics of sensory conflict and motion sickness. Acta Otolaryngol (Stockh) Suppl 392:1–44
Parker DE, Reschke MF, Gierke von HE, Lessard CS (1987) Effects of proposed preflight adaptation training on eye movements, self-motion perception, and motion sickness: a progress report. Aviat Space Environ Med 58:42–49
Parrot AC (1989) Transdermal scopolamine: a review of its effects upon motion sickness, psychological performance, and physiological functioning. Aviat Space Environm Med 60:1–9
Probst Th, Krafczyk S, Büchele W, Brandt Th (1982) Visuelle Prävention der Bewegungskrankheit im Auto. Arch Psychiatr Nervenkr 231:409–421
Reason JT (1978) Motion sickness adaptation: a neural mismatch model. J Roy Soc Med 71:819–829
Reason JT, Graybiel A (1970) Changes in subjective estimates of well-being during the onset and remission of motion sickness symptomatology in the slow rotation room. Aerospace Med 41:166–171
Schubert G (1931) Über die physiologischen Auswirkungen der Coriolis-Kräfte bei Trudelbewegungen des Flugzeuges. Acta Otolaryngol (Stockh) 16:39–47
Sjöberg AA (1931) Experimentelle Studien über den Auslösungsmechanismus der Seekrankheit. Acta Otolaryngol (Stockh) Suppl 14:136
Stevens SS (1957) On the psychophysical law. Psychol Rev 64:153–181
Tokola O, Laitinen LA, Aho J, Gothoni G, Vapaatalo H (1984) Drug treatment of motion sickness: scopolamine alone and combined with ephedrine in real and simulated situations. Aviat Space Environ Med 55:636–641
Toscano WV, Cowings PS (1982) Reducing motion sickness: A comparison of autogenic-feedback training and an alternative cognitive task. Aviat Space Environ Med 53:449–453
Treisman, M (1977) Motion sickness: an evolutionary hypothesis. Science 197:493–495
Tyler DB (1946) The influence of placebo, body position, and medication on motion sickness. Am J Physiol 146:458–466
Tyler DB, Bard P (1949) Motion sickness. Physiol Rev 29:311–369
Wang SC, Chinn HJ (1956) Experimental motion sickness in dogs. Importance of labyrinth and vestibular cerebellum. Am J Physiol 185:617–623
Wood CD, Graybiel A (1968) Evaluadon of sixteen anti-motion sickness drugs under controlled laboratory conditions. Aerospace Med 39:1341–1344
Wood CD, Graybiel A (1970) Evaluation of anti-motion sickness drugs: A new effective remedy revealed. Aerospace Med 41:932–933
Wood CD, Graybiel A, McDonough R (1966a) Human centrifuge studies on the relative effectiveness of some anti-motion sickness drugs. Aerospace Med 37:187–190
Wood CD, Graybiel A, Kennedy RS (1966b) Comparison of effectiveness of some antimotion sickness drugs using recommended and larger than recommended doses as tested in the slow rotation room. Aerospace Med 37:259–262
Wood CD, Kennedy RE, Graybiel A, Trumbull R, Wherry RJ (1966c) Clinical effecdveness of and-motion sickness drugs. JAMA 198:1155–1158
Wood CD, Manno JE, Manno BR, Redetzki HM, Wood M, Vekovius A (1984) Side effects of antimotion sickness drugs. Aviat Space Environ Med 55:113–116
Author information
Authors and Affiliations
Rights and permissions
Copyright information
© 1991 Springer-Verlag London Limited
About this chapter
Cite this chapter
Brandt, T. (1991). Motion Sickness. In: Vertigo: Its Multisensory Syndromes. Clinical Medicine and the Nervous System. Springer, London. https://doi.org/10.1007/978-1-4471-3342-1_25
Download citation
DOI: https://doi.org/10.1007/978-1-4471-3342-1_25
Publisher Name: Springer, London
Print ISBN: 978-1-4471-3344-5
Online ISBN: 978-1-4471-3342-1
eBook Packages: Springer Book Archive