Encoding of movement in near extrapersonal space in primate area VIP

Bremmer, Frank; Schlack, Anja; Kaminiarz, André; Hoffmann, K.

doi:10.3389/fnbeh.2013.00008

Cited by 28 publications

(23 citation statements)

References 39 publications

(69 reference statements)

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“…Indeed, the core brain regions of PPS—area VIP and ventral premotor cortex (Graziano et al ., ; di Pellegrino et al ., )—receive prominent vestibular, somatosensory, auditory, and visual inputs (Bremmer et al ., ; Schlack et al ., ; Chen et al ., ). Furthermore, direction‐dependent tuning of multimodal neurons has been demonstrated in VIP neurons (Bremmer et al ., , ; Schlack et al ., ), as dynamic visual and somatosensory stimuli at or close to the head induced the strongest neuronal response when monkeys are rotated in the same direction as the stimulus motion (Bremmer et al ., ). We suggest that the neurophysiological substrate for our reported behavioral effects are rooted within homologues areas of such PPS network in humans, and in particular the VIP region (Guipponi et al ., ).…”

Section: Discussionmentioning

confidence: 99%

“…The third experiment quantified the effects of vestibular stimulation on audio‐tactile interaction in peri‐head space. Based on previous evidence for direction‐specific PPS expansion during limb movements (e.g., Brozzoli et al ., ) and whole‐body walking (e.g., Noel et al ., ), as well as direction‐dependent encoding of visual, auditory, and somatosensory motion stimuli in monkey VIP neurons (Bremmer et al ., , ; Schlack et al ., ; Chen et al ., ), we hypothesized that vestibular stimulation would induce remapping of peri‐head space boundaries that depended on the directions of the presented motion stimuli. We tested this prediction in Experiment 3 by combining whole‐body Leftward or Rightward Rotation with Leftward or Rightward looming Sound stimulation, collapsed into Congruent trials (i.e., Leftward Rotation and Leftward Sound, Rightward Rotation and Rightward Sound) and Incongruent trials (i.e., Leftward Rotation and Rightward Sound, Rightward Rotation and Leftward Sound, Fig.…”

Section: Methodsmentioning

confidence: 99%

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Vestibular modulation of peripersonal space boundaries

Pfeiffer

Noel

Serino

et al. 2018

Eur J of Neuroscience

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Human-environment interactions are mediated through the body and occur within the peripersonal space (PPS), the space immediately adjacent to and surrounding the body. The PPS is taken to be a critical interface between the body and the environment, and indeed, body-part specific PPS remapping has been shown to depend on body-part utilization, such as upper limb movements in otherwise static observers. How vestibular signals induced by whole-body movement contribute to PPS representation is less well understood. In a series of experiments, we mapped the spatial extension of the PPS around the head while participants were submitted to passive whole-body rotations inducing vestibular stimulation. Forty-six participants, in three experiments, executed a tactile detection reaction time task while task-irrelevant auditory stimuli approached them. The maximal distance at which the auditory stimulus facilitated tactile reaction time was taken as a proxy for the boundary of peri-head space. The present results indicate two distinct vestibular effects. First, vestibular stimulation speeded tactile detection indicating a vestibular facilitation of somatosensory processing. Second, vestibular stimulation modulated audio-tactile interaction of peri-head space in a rotation direction-specific manner. Congruent but not incongruent audio-vestibular motion stimuli expanded the PPS boundary further away from the body as compared to no rotation. These results show that vestibular inputs dynamically update the multisensory delineation of PPS and far space, which may serve to maintain accurate tracking of objects close to the body and to update spatial self-representations.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Vestibular modulation of peripersonal space boundaries

Pfeiffer

Noel

Serino

et al. 2018

Eur J of Neuroscience

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“…Even more significant for our purpose, neurons in monkeys' area VIP have been found to be sensitive to the position of the movement relative to the observer, and to respond differentially according to whether the apparent location of the movement is situated in near or far extrapersonal space. Neuronal responses were found to be strongest for close, head-centered, approaching stimuli, in comparison to the responses to stimulation in the more distant extrapersonal space (Colby et al, 1993 ; Bremmer et al, 2013 ). The fact that approaching visual stimuli in the near, head-centered, personal space trigger neuronal responses, highlights the role of this area in guiding head movements in space, as well as in assessing the salience of moving stimuli and in preparing for avoidance reactions (Colby et al, 1993 ; Bremmer et al, 2013 ).…”

Section: Discussionmentioning

confidence: 99%

“…Neuronal responses were found to be strongest for close, head-centered, approaching stimuli, in comparison to the responses to stimulation in the more distant extrapersonal space (Colby et al, 1993 ; Bremmer et al, 2013 ). The fact that approaching visual stimuli in the near, head-centered, personal space trigger neuronal responses, highlights the role of this area in guiding head movements in space, as well as in assessing the salience of moving stimuli and in preparing for avoidance reactions (Colby et al, 1993 ; Bremmer et al, 2013 ). This interpretation is supported by evidence showing that monkeys display defensive behaviors such as protecting the face with their arms following VIP electrical stimulation (Cooke and Graziano, 2004 ; Graziano and Cooke, 2006 ).…”

Section: Discussionmentioning

confidence: 99%

Looming sensitive cortical regions without V1 input: evidence from a patient with bilateral cortical blindness

Hervais-Adelman

Legrand

Zhan

et al. 2015

Front. Integr. Neurosci.

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Fast and automatic behavioral responses are required to avoid collision with an approaching stimulus. Accordingly, looming stimuli have been found to be highly salient and efficient attractors of attention due to the implication of potential collision and potential threat. Here, we address the question of whether looming motion is processed in the absence of any functional primary visual cortex and consequently without awareness. For this, we investigated a patient (TN) suffering from complete, bilateral damage to his primary visual cortex. Using an fMRI paradigm, we measured TN's brain activation during the presentation of looming, receding, rotating, and static point lights, of which he was unaware. When contrasted with other conditions, looming was found to produce bilateral activation of the middle temporal areas, as well as the superior temporal sulcus and inferior parietal lobe (IPL). The latter are generally thought to be involved in multisensory processing of motion in extrapersonal space, as well as attentional capture and saliency. No activity was found close to the lesioned V1 area. This demonstrates that looming motion is processed in the absence of awareness through direct subcortical projections to areas involved in multisensory processing of motion and saliency that bypass V1.

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“…The macaque ventral intraparietal area, VIP (Colby et al, 1993), is a polysensory area in the fundus of the intraparietal sulcus that encodes visual, vestibular, auditory and somatosensory stimuli. It is particularly sensitive to visual stimuli located near the observer in depth (Bremmer et al, 2013;Colby et al, 1993;Yang et al, 2011) and to air puffs on the face (Avillac et al, 2005), suggesting that it may be specialised for encoding nearby objects such as reach targets and/or obstacles during locomotion. There is evidence not only for visual-vestibular integration (discussed below), but also for visualauditory (Schlack et al, 2005) and visual-somatosensory (Avillac et al, 2007) integration.…”

Section: Vip/hvipmentioning

confidence: 99%

Distributed Visual–Vestibular Processing in the Cerebral Cortex of Man and Macaque

et al. 2017

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Recent advances in understanding the neurobiological underpinnings of visual–vestibular interactions underlying self-motion perception are reviewed with an emphasis on comparisons between the macaque and human brains. In both species, several distinct cortical regions have been identified that are active during both visual and vestibular stimulation and in some of these there is clear evidence for sensory integration. Several possible cross-species homologies between cortical regions are identified. A key feature of cortical organization is that the same information is apparently represented in multiple, anatomically diverse cortical regions, suggesting that information about self-motion is used for different purposes in different brain regions.

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Encoding of movement in near extrapersonal space in primate area VIP

Cited by 28 publications

References 39 publications

Vestibular modulation of peripersonal space boundaries

Vestibular modulation of peripersonal space boundaries

Looming sensitive cortical regions without V1 input: evidence from a patient with bilateral cortical blindness

Distributed Visual–Vestibular Processing in the Cerebral Cortex of Man and Macaque

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