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Literature DB >> 26003125

Sound-evoked vestibular stimulation affects the anticipation of gravity effects during visual self-motion.

Iole Indovina¹, Elisabetta Mazzarella, Vincenzo Maffei, Benedetta Cesqui, Luca Passamonti, Francesco Lacquaniti.

Abstract

Humans anticipate the effects of gravity during visually simulated self-motion in the vertical direction. Here we report that an artificial vestibular stimulation consisting of short-tone bursts (STB) suppresses this anticipation. Participants pressed a button upon entering a tunnel during virtual-reality roller coaster rides in downward or forward directions. In different trials, we delivered STB, pulsed white noise (WN), or no sound (NO). In the control conditions (WN, NO), participants responded earlier during downward than forward motion irrespective of true kinematics, consistent with the a priori expectation that downward but not forward motion is accelerated by gravity. STB canceled the difference in response timing between the two directions, without affecting overall task performance. Thus, we argue that vestibular signals play a role in the anticipation of visible gravity effects during self-motion.

Entities: Chemical Species

Mesh：

Year: 2015 PMID： 26003125 DOI： 10.1007/s00221-015-4306-9

Source DB: PubMed Journal: Exp Brain Res ISSN： 0014-4819 Impact factor: 1.972

40 in total

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10. Dynamic reweighting of visual and vestibular cues during self-motion perception.

Authors: Christopher R Fetsch; Amanda H Turner; Gregory C DeAngelis; Dora E Angelaki
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5. Role of the Insula and Vestibular System in Patients with Chronic Subjective Dizziness: An fMRI Study Using Sound-Evoked Vestibular Stimulation.

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6. Altered Insular and Occipital Responses to Simulated Vertical Self-Motion in Patients with Persistent Postural-Perceptual Dizziness.

Authors: Roberta Riccelli; Luca Passamonti; Nicola Toschi; Salvatore Nigro; Giuseppe Chiarella; Claudio Petrolo; Francesco Lacquaniti; Jeffrey P Staab; Iole Indovina
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