scholarly article | Q13442814 |
review article | Q7318358 |
P6179 | Dimensions Publication ID | 1007745006 |
P356 | DOI | 10.1007/S00221-006-0697-Y |
P698 | PubMed publication ID | 17021896 |
P2093 | author name string | James R Lackner | |
Paul Dizio | |||
P2860 | cites work | Physiological basis and pharmacology of motion sickness: an update | Q28138034 |
The area postrema and vomiting | Q28236673 | ||
A new nausea model in humans produces mild nausea without electrogastrogram and vasopressin changes | Q30471558 | ||
Noxious stimulation of emesis. | Q33144981 | ||
The effects of vestibular system lesions on autonomic regulation: observations, mechanisms, and clinical implications | Q33153096 | ||
Perspectives of electrogastrography and motion sickness | Q33537630 | ||
Motion sickness: only one provocative conflict? | Q33537634 | ||
Modelling motion sickness and subjective vertical mismatch detailed for vertical motions. | Q33537637 | ||
Coriolis effects and motion sickness modelling | Q33537639 | ||
Vestibular autonomic regulation (including motion sickness and the mechanism of vomiting). | Q33546350 | ||
Illusory self-motion and motion sickness: a model for brain-gut interactions and nausea. | Q33734242 | ||
Pharmaceutical use by U.S. astronauts on space shuttle missions. | Q33868862 | ||
Aspects of body self-calibration | Q33946219 | ||
Artificial gravity as a countermeasure in long-duration space flight | Q34053864 | ||
Adaptive plasticity in vestibular influences on cardiovascular control | Q34060836 | ||
Comparison of treatment strategies for Space Motion Sickness | Q34089814 | ||
Treatment of severe motion sickness with antimotion sickness drug injections | Q34186243 | ||
Therapeutic effects of antimotion sickness medications on the secondary symptoms of motion sickness | Q34203232 | ||
Treatment efficacy of intramuscular promethazine for space motion sickness. | Q34361459 | ||
A retrospective study of promethazine and its failure to produce the expected incidence of sedation during space flight | Q34474672 | ||
Changes in the vestibular function during space flight. | Q34558073 | ||
Role of the vestibular system in regulating respiratory muscle activity during movement | Q34572567 | ||
The biomedical challenges of space flight | Q35019800 | ||
Anatomical position of heart in snakes with vertical orientation: a new hypothesis | Q73628375 | ||
Objective and subjective time courses of recovery from motion sickness assessed by repeated motion challenges | Q73938525 | ||
Human heart rate variability relation is unchanged during motion sickness | Q73993368 | ||
Why do astronauts suffer space sickness? | Q74468071 | ||
Diuretic as a means for rapid adaptation to weightlessness | Q74471706 | ||
A sustained hyper-g load as a tool to simulate space sickness | Q74471858 | ||
Electrical vestibular stimulation and space motion sickness | Q74472084 | ||
Development of space motion sickness in a ground-based human centrifuge | Q74472116 | ||
Pharmacotherapeutics in space | Q74478609 | ||
Predicting motion sickness during parabolic flight | Q74496565 | ||
Post-spaceflight orthostatic intolerance: possible relationship to microgravity-induced plasticity in the vestibular system | Q77486376 | ||
The menstrual cycle and susceptibility to coriolis-induced sickness | Q77643854 | ||
Optokinetic nystagmus correlates with severity of vection-induced motion sickness and gastric tachyarrhythmia | Q77694702 | ||
Importance of the vestibular system in visually induced nausea and self-vection | Q77909047 | ||
Systematic investigation of physiological correlates of motion sickness induced by viewing an optokinetic rotating drum | Q78125187 | ||
The vestibular system and cardiovascular responses to altered gravity | Q79350788 | ||
A comparison of the symptomatology experienced by healthy persons and subjects with loss of labyrinthine function when exposed to unusual patterns of centripetal force in a counter-rotating room | Q79500065 | ||
Of what importance are psychological factors in motion sickness? | Q79552086 | ||
Vertical linear self-motion perception during visual and inertial motion: more than weighted summation of sensory inputs | Q81477591 | ||
Motion sickness | Q94392978 | ||
Salivary changes associated with seasickness | Q62937253 | ||
Comparison of susceptibility to motion sickness during rotation at 30 rpm in the earth-horizontal, 10 degrees head-up, and 10 degrees head-down positions | Q67539562 | ||
First Intramuscular Administration in the U.S. Space Program | Q67803385 | ||
The effective intensity of Coriolis, cross-coupling stimulation is gravitoinertial force dependent: implications for space motion sickness | Q68796405 | ||
Sudden emesis following parabolic flight maneuvers: implications for space motion sickness | Q68796407 | ||
Pharmacological interventions for motion sickness: cardiovascular effects | Q68832315 | ||
Electrogastrography: current issues in validation and methodology | Q69002620 | ||
Asymmetric otolith function and increased susceptibility to motion sickness during exposure to variations in gravitoinertial acceleration level | Q69198016 | ||
Gastrointestinal motility in space motion sickness | Q69439642 | ||
The influence of gravitoinertial force level on oculomotor and perceptual responses to Coriolis, cross-coupling stimulation | Q69439652 | ||
The influence of gravitoinertial force level on oculomotor and perceptual responses to sudden stop stimulation | Q69439654 | ||
Fluid shifts in weightlessness | Q69439669 | ||
Space shuttle inflight and postflight fluid shifts measured by leg volume changes | Q69439671 | ||
Adaptation to vection-induced symptoms of motion sickness | Q69662609 | ||
General autonomic components of motion sickness | Q69735335 | ||
Motion sickness incidence as a function of the frequency and acceleration of vertical sinusoidal motion | Q69750574 | ||
Evaluation of sixteen anti-motion sickness drugs under controlled laboratory conditions | Q69861160 | ||
Motion sickness | Q69896441 | ||
Motion sickness susceptibility in parabolic flight and velocity storage activity | Q70153140 | ||
Reducing motion sickness: a comparison of autogenic-feedback training and an alternative cognitive task | Q70392957 | ||
The relationship of motion sickness susceptibility to learned autonomic control for symptom suppression | Q70446148 | ||
Semicircular canals as a primary etiological factor in motion sickness | Q70490354 | ||
Effect of environmental temperature on sweat onset during motion sickness | Q70496204 | ||
Elicitation of motion sickness by head movements in the microgravity phase of parabolic flight maneuvers | Q70580681 | ||
Effect of gravitoinertial force on ocular counterrolling | Q70593761 | ||
Motion sickness, vascular changes accompanying pseudo-coriolis-induced nausea | Q70741935 | ||
Cardiorespiratory dynamics in the ox and giraffe, with comparative observations on man and other mammals | Q70875165 | ||
Effect of neurovestibular stimulation on autonomic regulation | Q70904631 | ||
Structural elements in the concept of motion sickness | Q71113089 | ||
Progressive adaptation to Coriolis accelerations associated with 1-rpm increments in the velocity of the slow rotation room | Q71137698 | ||
Motion sickness: a special case of sensory rearrangement | Q71140307 | ||
A sudden-stop vestibulovisual test for rapid assessment of motion sickness manifestations | Q71154007 | ||
Evaluation of the relationship between motion sickness symptomatology and blood pressure, heart rate, and body temperature | Q71154086 | ||
Space motion sickness: Skylab revisited | Q71325468 | ||
Motion sickness incidence during a round-the-world yacht race | Q71560194 | ||
Asian hypersusceptibility to motion sickness | Q71576462 | ||
Another function of the inner ear: facilitation of the emetic response to poisons | Q71725582 | ||
Space motion sickness: phenomenology, countermeasures, and mechanisms | Q71725600 | ||
Physiological and behavioral effects of tilt-induced body fluid shifts | Q71786297 | ||
Blood flow and pressure in the giraffe carotid artery | Q72046053 | ||
Space sickness and fluid shifts: a hypothesis | Q72181928 | ||
Relations between motion sickness susceptibility, the spiral after-effect and loudness estimation | Q72214955 | ||
A predictive test for space motion sickness | Q72691661 | ||
Otolith organ activity within earth standard, one-half standard and zero gravity environments | Q72893905 | ||
Autogenic-feedback training exercise is superior to promethazine for control of motion sickness symptoms | Q73068959 | ||
The absence of residual effects attributable to the otolith organs following unilateral labyrinthectomy in man | Q73069770 | ||
Physiological effects induced by antiorthostatic hypokinesia | Q73221042 | ||
Promethazine as a motion sickness treatment: impact on human performance and mood states. | Q48710991 | ||
Simulation of space adaptation syndrome on earth | Q49160388 | ||
Nausogenic properties of various dynamic and static force environments. | Q50124438 | ||
Car‐sickness in Twins | Q50128227 | ||
Motion sickness susceptibility and related behavioral characteristics in men and women. | Q51022183 | ||
Motion sickness susceptibility fluctuates through the menstrual cycle. | Q51836072 | ||
Use of promethazine to hasten adaptation to provocative motion. | Q52025814 | ||
Sopite syndrome: a sometimes sole manifestation of motion sickness | Q52111994 | ||
The effect of autogenic training and biofeedback on motion sickness tolerance. | Q52199486 | ||
Effect of sickness severity on habituation to repeated motion challenges in aircrew referred for airsickness treatment. | Q52207529 | ||
Genetical and Developmental Aspects of Susceptibility to Motion Sickness and Frost-bite | Q52333994 | ||
Prevention of overt motion sickness by incremental exposure to otherwise highly stressful coriolis accelerations | Q52337122 | ||
Spacelab experiments on space motion sickness. | Q52607725 | ||
Tachygastria and motion sickness. | Q53956461 | ||
On Predictive Equations for Subjective Judgments of Vertical and Horizon in a Force Field | Q54193554 | ||
A model for vestibular function in altered gravitational states | Q56905764 | ||
Alterations in R–R variability associated with experimental motion sickness | Q57207048 | ||
Plastic changes in processing of graviceptive signals during spaceflight potentially contribute to postflight orthostatic intolerance. | Q35750894 | ||
Physiological, pharmacokinetic, and pharmacodynamic changes in space | Q35851988 | ||
Motion sickness: a synthesis and evaluation of the sensory conflict theory | Q37905203 | ||
Effect of direction of head movement on motion sickness caused by Coriolis stimulation | Q38558372 | ||
Horizontal angular VOR changes in orbital and parabolic flight: human neurovestibular studies on SLS-2. | Q38561827 | ||
Vestibular influences on the autonomic nervous system | Q38563284 | ||
Horizontal angular VOR, nystagmus dumping, and sensation duration in spacelab SLS-1 crewmembers. | Q38567596 | ||
M.I.T./Canadian vestibular experiments on the Spacelab-1 mission: 4. Space motion sickness: symptoms, stimuli, and predictability | Q38591987 | ||
Clinical characterization and etiology of space motion sickness | Q38593822 | ||
Individual differences in susceptibility to motion sickness among six Skylab astronauts | Q39589941 | ||
General remarks on the role of the vestibular system in weightlessness | Q39677373 | ||
Motion Sickness: An Evolutionary Hypothesis | Q40650528 | ||
Successful Transfer Of Adaptation Acquired In A Slow Rotation Room To Motion Environments In Navy Flight Training | Q40670302 | ||
Gravity, blood circulation, and the adaptation of form and function in lower vertebrates | Q41012082 | ||
Labyrinth and cerebral-spinal fluid pressure changes in guinea pigs and monkeys during simulated zero G | Q41023232 | ||
Rotation at 30 RPM about the A axis after 6 hours in the 10 degree head-down position: effect on susceptibility to motion sickness | Q41027464 | ||
Preflight adaptation training for spatial orientation and space motion sickness | Q41031148 | ||
Further evidence to support disconjugate eye torsion as a predictor of space motion sickness | Q41113755 | ||
Validating the hypothesis of otolith asymmetry as a cause of space motion sickness | Q41122263 | ||
Prediction of space motion sickness susceptibility by disconjugate eye torsion in parabolic flight | Q41181335 | ||
Space motion sickness during 24 flights of the space shuttle | Q41259827 | ||
Quantitative analysis of the velocity characteristics of optokinetic nystagmus and optokinetic after-nystagmus | Q41318000 | ||
Ocular torsion in upright and tilted positions during hypo- and hypergravity of parabolic flight | Q41418065 | ||
Otolith tilt-translation reinterpretation following prolonged weightlessness: implications for preflight training | Q41484387 | ||
A heuristic mathematical model for the dynamics of sensory conflict and motion sickness | Q41556085 | ||
Optokinetic motion sickness: attenuation of visually-induced apparent self-rotation by passive head movements | Q41667593 | ||
Sensory conflict theory and space sickness: our changing perspective. | Q41673316 | ||
Pharmacology of motion sickness. | Q41673334 | ||
Managing space motion sickness. | Q41673341 | ||
Parabolic flight reveals independent binocular control of otolith-induced eye torsion | Q41709283 | ||
Comparison of the effects of a selective muscarinic receptor antagonist and hyoscine (scopolamine) on motion sickness, skin conductance and heart rate | Q42144684 | ||
Spatial orientation and balance control changes induced by altered gravitoinertial force vectors | Q43609483 | ||
The stability of individual patterns of autonomic responses to motion sickness stimulation | Q43762076 | ||
Instability of ocular torsion in zero gravity: possible implications for space motion sickness. | Q44027695 | ||
Spectral analysis of tachygastria recorded during motion sickness. | Q44198545 | ||
Motion sickness susceptibility and aerobic fitness: a longitudinal study | Q44253370 | ||
A provocative test for grading susceptibility to motion sickness yielding a single numerical score | Q44357900 | ||
Nystagmus, turning sensations, and illusory movement in motion sickness susceptibility | Q44423036 | ||
The relation of motion sickness to the spatial-temporal properties of velocity storage | Q44463318 | ||
The critical role of velocity storage in production of motion sickness | Q44684761 | ||
Visually-induced sickness in normal and bilaterally labyrinthine-defective subjects | Q44847496 | ||
Treatment of motion sickness in parabolic flight with buccal scopolamine | Q44906048 | ||
The menstrual cycle and susceptibility to virtual simulation sickness | Q45226860 | ||
Altered sensory-motor control of the head as an etiological factor in space-motion sickness | Q45361915 | ||
Optokinetic motion sickness: continuous head movements attenuate the visual induction of apparent self-rotation and symptoms of motion sickness | Q46142314 | ||
Lack of gender difference in motion sickness induced by vestibular Coriolis cross-coupling. | Q46305494 | ||
Reliability of psychophysiological responses across multiple motion sickness stimulation tests | Q46472225 | ||
Effects of baclofen on the angular vestibulo-ocular reflex | Q46845505 | ||
Otolith function in hypo- and hypergravity: relation to space motion sickness | Q46892710 | ||
The effects of gravitoinertial force level and head movements on post-rotational nystagmus and illusory after-rotation | Q48129061 | ||
Cardiovascular responses elicited by linear acceleration in humans | Q48213038 | ||
Body volume changes during simulated microgravity: auditory changes, segmental fluid redistribution, and regional hemodynamics | Q48261830 | ||
Roll motion stimuli: sensory conflict, perceptual weighting and motion sickness. | Q48272595 | ||
Relationship between motion sickness, migraine and menstruation in crew members of a "round the world" yacht race | Q48272649 | ||
European vestibular experiments on the Spacelab-1 mission: 1. Overview | Q48407813 | ||
Autonomic reaction to vestibular damage | Q48425491 | ||
P433 | issue | 3 | |
P921 | main subject | motion sickness | Q309067 |
P1104 | number of pages | 23 | |
P304 | page(s) | 377-399 | |
P577 | publication date | 2006-10-05 | |
P1433 | published in | Experimental Brain Research | Q13358841 |
P1476 | title | Space motion sickness | |
P478 | volume | 175 |
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