The neural basis of motion sickness

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Abstract

Although motion of the head and body has been suspected or known as the provocative cause for the production of motion sickness for centuries, it is only within the last 20 yr that the source of the signal generating motion sickness and its neural basis has been firmly established. Here, we briefly review the source of the conflicts that cause the body to generate the autonomic signs and symptoms that constitute motion sickness and provide a summary of the experimental data that have led to an understanding of how motion sickness is generated and can be controlled. Activity and structures that produce motion sickness include vestibular input through the semicircular canals, the otolith organs, and the velocity storage integrator in the vestibular nuclei. Velocity storage is produced through activity of vestibular-only (VO) neurons under control of neural structures in the nodulus of the vestibulo-cerebellum. Separate groups of nodular neurons sense orientation to gravity, roll/tilt, and translation, which provide strong inhibitory control of the VO neurons. Additionally, there are acetylcholinergic projections from the nodulus to the stomach, which along with other serotonergic inputs from the vestibular nuclei, could induce nausea and vomiting. Major inhibition is produced by the GABA _B receptors, which modulate and suppress activity in the velocity storage integrator. Ingestion of the GABA _B agonist baclofen causes suppression of motion sickness. Hopefully, a better understanding of the source of sensory conflict will lead to better ways to avoid and treat the autonomic signs and symptoms that constitute the syndrome.

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Most cited references 103

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The virtual reality head-mounted display Oculus Rift induces motion sickness and is sexist in its effects.

Meg Diedrick, Justin Munafo, Thomas Stoffregen (2017)

Anecdotal reports suggest that motion sickness may occur among users of contemporary, consumer-oriented head-mounted display systems and that women may be at greater risk. We evaluated the nauseogenic properties of one such system, the Oculus Rift. The head-mounted unit included motion sensors that were sensitive to users' head movements, such that head movements could be used as control inputs to the device. In two experiments, seated participants played one of two virtual reality games for up to 15 min. In Experiment 1, 22% of participants reported motion sickness, and the difference in incidence between men and women was not significant. In Experiment 2, motion sickness was reported by 56% of participants, and incidence among women (77.78%) was significantly greater than among men (33.33%). Before participants were exposed to the head-mounted display system, we recorded their standing body sway during the performance of simple visual tasks. In both experiments, patterns of pre-exposure body sway differed between participants who (later) reported motion sickness and those who did not. In Experiment 2, sex differences in susceptibility to motion sickness were preceded by sex differences in body sway. These postural effects confirm a prediction of the postural instability theory of motion sickness. The results indicate that users of contemporary head-mounted display systems are at significant risk of motion sickness and that in relation to motion sickness these systems may be sexist in their effects.

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In 1996, we are half-way through the Decade of the Brain, yet we still have few effective treatments for major disorders of the central nervous system. These include affective disorders, epilepsy, neurodegenerative disorders, brain tumours, infections and HIV encephalopathy; sufferers far outnumber the morbidity of cancer or heart disease. Increased understanding of the pharmacology of the brain and its blood supply, and methods for rational drug design, are leading to potential new drug therapies based on highly specific actions on particular target sites, such as neurotransmitter receptors and uptake systems. These methods are capable of reducing the side effects that are common with more general treatments. However, all these treatments and potential treatments meet a formidable obstacle--the blood-brain barrier. In this article, we review the properties of this barrier that complicate drug delivery to the brain, and some of the most hopeful strategies for overcoming or bypassing the barrier in humans.

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Velocity storage in the vestibulo-ocular reflex arc (VOR).

V Matsuo, T Raphan, Justus B. Cohen (1979)

Vestibular and optokinetic nystagmus (OKN) of monkeys were induced by platform and visual surround rotation. Vision prolonged per-rotatory nystagmus and cancelled or reduced post-rotatory nystagmus recorded in darkness. Presumably, activity stored during OKN summed with activity arising in the semicircular canals. The limit of summation was about 120 degrees/s, the level of saturation of optokinetic after-nystagmus (OKAN). OKN and vestibular nystagmus, induced in the same or in opposite directions diminished or enhanced post-rotatory nystagmus up to 120 degrees/s. We postulate that a common storage mechanism is used for producing vestibular nystagmus, OKN, and OKAN. Evidence for this is the similar time course of vestibular nystagmus and OKAN and their summation. In addition, stored activity is lost in a similar way by viewing a stationary surround during either OKAN or vestibular nystagmus (fixation suppression). These responses were modelled using direct pathways and a non-ideal integrator coupled to the visual and peripheral vestibular systems. The direct pathways are responsible for rapid changes in eye velocity while the integrator stores activity and mediates slower changes. The integrator stabilizes eye velocity during whole field rotation and extends the time over which the vestibulo-ocular reflex can compensate for head movement.

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Author and article information

Journal

Title: Journal of Neurophysiology

Abbreviated Title: Journal of Neurophysiology

Publisher: American Physiological Society

ISSN (Print): 0022-3077

ISSN (Electronic): 1522-1598

Publication date Created: March 01 2019

Publication date (Print): March 01 2019

Volume: 121

Issue: 3

Pages: 973-982

Affiliations

[1 ]Department of Neurology, Icahn School of Medicine at Mount Sinai, New York, New York

[2 ]Department of Neurology, New York University, New York

Article

DOI: 10.1152/jn.00674.2018

PubMed ID: 30699041

SO-VID: da52badd-c8ef-4a95-b06f-2c109cc79db6

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