Visual-vestibular interactive responses in the macaque ventral intraparietal area (VIP)

Self‐motion detection requires the interaction of a number of sensory systems for correct perceptual interpretation of a given movement and an eventual motor response. Parietal cortical areas are thought to play an important role in this function, and we have thus studied the encoding of multimodal...

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Bibliographic Details
Published in:The European journal of neuroscience 2002-10, Vol.16 (8), p.1569-1586
Main Authors: Bremmer, Frank, Klam, François, Duhamel, Jean-René, Ben Hamed, Suliann, Graf, Werner
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Animals
Evoked Potentials, Somatosensory - physiology
Eye Movements - physiology
Female
Macaca
Macaca fascicularis - anatomy & histology
Macaca fascicularis - physiology
Macaca mulatta - anatomy & histology
Macaca mulatta - physiology
Motion Perception - physiology
Neurons - physiology
Orientation - physiology
parietal
Parietal Lobe - cytology
Parietal Lobe - physiology
perception
Photic Stimulation
Physical Stimulation
Postural Balance - physiology
primate
Psychomotor Performance - physiology
self-motion
Space life sciences
Space Perception - physiology
Touch - physiology
vestibular
Vestibule, Labyrinth - physiology
Visual Cortex - cytology
Visual Cortex - physiology
Visual Fields - physiology
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Summary:Self‐motion detection requires the interaction of a number of sensory systems for correct perceptual interpretation of a given movement and an eventual motor response. Parietal cortical areas are thought to play an important role in this function, and we have thus studied the encoding of multimodal signals and their spatiotemporal interactions in the ventral intraparietal area of macaque monkeys. Thereby, we have identified for the first time the presence of vestibular sensory input to this area and described its interaction with somatosensory and visual signals, via extracellular single‐cell recordings in awake head‐fixed animals. Visual responses were driven by large field stimuli that simulated either backward or forward self‐motion (contraction or expansion stimuli, respectively), or movement in the frontoparallel plane (visual increments moving simultaneously in the same direction). While the dominant sensory modality in most neurons was visual, about one third of all recorded neurons responded to horizontal rotation. These vestibular responses were typically in phase with head velocity, but in some cases they could signal acceleration or even showed integration to position. The associated visual responses were always codirectional with the vestibular on‐direction, i.e. noncomplementary. Somatosensory responses were in register with the visual preferred direction, either in the same or in the opposite direction, thus signalling translation or rotation in the horizontal plane. These results, taken together with data on responses to optic flow stimuli obtained in a parallel study, strongly suggest an involvement of area VIP in the analysis and the encoding of self‐motion.
ISSN:0953-816X
1460-9568
DOI:10.1046/j.1460-9568.2002.02206.x