Functional neuroimaging of visuo-vestibular interaction.

Research output: Contribution to journalArticlepeer-review

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Functional neuroimaging of visuo-vestibular interaction. / Roberts, Ed; Ahmad, Hena; Arshad, Qadeer et al.
In: Brain Structure and Function, 01.07.2017.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Roberts, E, Ahmad, H, Arshad, Q, Patel, M, Dima, D, Leech , R, Seemungal , B, Sharp , DJ & Bronstein, AM 2017, 'Functional neuroimaging of visuo-vestibular interaction.', Brain Structure and Function.

APA

Roberts, E., Ahmad, H., Arshad, Q., Patel, M., Dima, D., Leech , R., Seemungal , B., Sharp , D. J., & Bronstein, A. M. (2017). Functional neuroimaging of visuo-vestibular interaction. Brain Structure and Function.

CBE

Roberts E, Ahmad H, Arshad Q, Patel M, Dima D, Leech R, Seemungal B, Sharp DJ, Bronstein AM. 2017. Functional neuroimaging of visuo-vestibular interaction. Brain Structure and Function.

MLA

Roberts, Ed et al. "Functional neuroimaging of visuo-vestibular interaction.". Brain Structure and Function. 2017.

VancouverVancouver

Roberts E, Ahmad H, Arshad Q, Patel M, Dima D, Leech R et al. Functional neuroimaging of visuo-vestibular interaction. Brain Structure and Function. 2017 Jul 1. Epub 2016 Dec 10.

Author

Roberts, Ed ; Ahmad, Hena ; Arshad, Qadeer et al. / Functional neuroimaging of visuo-vestibular interaction. In: Brain Structure and Function. 2017.

RIS

TY - JOUR

T1 - Functional neuroimaging of visuo-vestibular interaction.

AU - Roberts, Ed

AU - Ahmad, Hena

AU - Arshad, Qadeer

AU - Patel, Mitesh

AU - Dima, Danai

AU - Leech , Rob

AU - Seemungal , Barry

AU - Sharp , David J

AU - Bronstein, Adolfo M

PY - 2017/7/1

Y1 - 2017/7/1

N2 - The brain combines visual, vestibular and proprioceptive information to distinguish between self- and world motion. Often these signals are complementary and indicate that the individual is moving or stationary with respect to the surroundings. However, conflicting visual motion and vestibular cues can lead to ambiguous or false sensations of motion. In this study, we used functional magnetic resonance imaging to explore human brain activation when visual and vestibular cues were either complementary or in conflict. We combined a horizontally moving optokinetic stimulus with caloric irrigation of the right ear to produce conditions where the vestibular activation and visual motion indicated the same (congruent) or opposite directions of self-motion (incongruent). Visuo-vestibular conflict was associated with increased activation in a network of brain regions including posterior insular and transverse temporal areas, cerebellar tonsil, cingulate and medial frontal gyri. In the congruent condition, there was increased activation in primary and secondary visual cortex. These findings suggest that when sensory information regarding self-motion is contradictory, there is preferential activation of multisensory vestibular areas to resolve this ambiguity. When cues are congruent, there is a bias towards visual cortical activation. The data support the view that a network of brain areas including the posterior insular cortex may play an important role in integrating and disambiguating visual and vestibular cues.

AB - The brain combines visual, vestibular and proprioceptive information to distinguish between self- and world motion. Often these signals are complementary and indicate that the individual is moving or stationary with respect to the surroundings. However, conflicting visual motion and vestibular cues can lead to ambiguous or false sensations of motion. In this study, we used functional magnetic resonance imaging to explore human brain activation when visual and vestibular cues were either complementary or in conflict. We combined a horizontally moving optokinetic stimulus with caloric irrigation of the right ear to produce conditions where the vestibular activation and visual motion indicated the same (congruent) or opposite directions of self-motion (incongruent). Visuo-vestibular conflict was associated with increased activation in a network of brain regions including posterior insular and transverse temporal areas, cerebellar tonsil, cingulate and medial frontal gyri. In the congruent condition, there was increased activation in primary and secondary visual cortex. These findings suggest that when sensory information regarding self-motion is contradictory, there is preferential activation of multisensory vestibular areas to resolve this ambiguity. When cues are congruent, there is a bias towards visual cortical activation. The data support the view that a network of brain areas including the posterior insular cortex may play an important role in integrating and disambiguating visual and vestibular cues.

M3 - Article

JO - Brain Structure and Function

JF - Brain Structure and Function

SN - 1863-2653

ER -