Somato-Motor Haptic Processing in Posterior Inner Perisylvian Region (SII/pIC) of the Macaque Monkey

Ishida, Hiroaki; Fornia, Luca; Grandi, Laura Clara; Umiltà, Maria Alessandra; Gallese, Vittorio

doi:10.1371/journal.pone.0069931

Cited by 36 publications

(33 citation statements)

References 91 publications

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“…Fadiga et al suggested that this modulation is due to an effect along the parietal-frontal pathway. Similar interactions between motor and somatosensory signals have been shown (Ishida, Fornia, Grandi, Umilta, & Gallese, 2013;Gardner, Debowy, Ro, Ghosh, & Babu, 2002). The secondary somatosensory cortex and posterior insula cortex have reciprocal connections with the parieto-premotor grasping-related areas.…”

Section: Hand-type Neuronssupporting

confidence: 58%

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Functional Properties of Parietal Hand Manipulation–related Neurons and Mirror Neurons Responding to Vision of Own Hand Action

Maeda

Ishida

Nakajima

et al. 2015

Journal of Cognitive Neuroscience

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Parietofrontal pathways play an important role in visually guided motor control. In this pathway, hand manipulation-related neurons in the inferior parietal lobule represent 3-D properties of an object and motor patterns to grasp it. Furthermore, mirror neurons show visual responses that are concerned with the actions of others and motor-related activity during execution of the same grasping action. Because both of these categories of neurons integrate visual and motor signals, these neurons may play a role in motor control based on visual feedback signals. The aim of this study was to investigate whether these neurons in inferior parietal lobule including the anterior intraparietal area and PFG of macaques represent visual images of the monkey's own hand during a self-generated grasping action. We recorded 235 neurons related to hand manipulation tasks. Of these, 54 responded to video clips of the monkey's own hand action, the same as visual feedback during that action or clips of the experimenter's hand action in a lateral view. Of these 54 neurons, 25 responded to video clips of the monkey's own hand, even without an image of the target object. We designated these 25 neurons as "hand-type." Thirty-three of 54 neurons that were defined as mirror neurons showed visual responses to the experimenter's action and motor responses. Thirteen of these mirror neurons were classified as hand-type. These results suggest that activity of hand manipulation-related and mirror neurons in anterior intraparietal/PFG plays a fundamental role in monitoring one's own body state based on visual feedback.

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Section: Hand-type Neuronssupporting

confidence: 58%

“…The secondary somatosensory cortex and posterior insula cortex have reciprocal connections with the parieto-premotor grasping-related areas. Neurons in these areas respond both to passive somatosensory stimulation and to the motor task (Ishida et al, 2013). This network should be involved in somatosensory control of grasping.…”

Section: Hand-type Neuronsmentioning

confidence: 99%

Functional Properties of Parietal Hand Manipulation–related Neurons and Mirror Neurons Responding to Vision of Own Hand Action

Maeda

Ishida

Nakajima

et al. 2015

Journal of Cognitive Neuroscience

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“…In order to assess motor-related properties in the hand region of SII/pIC, Ishida et al (2013) trained monkeys to perform a handmanipulation motor task using three different grip types (retrieving a food morsel from a groove, a cup, or a plate). A set of neurons in the SII/pIC region was only activated during active handmanipulation of the monkey.…”

Section: Somato-motor Integration In Sii/insular Of the Macaque Monkeymentioning

confidence: 99%

“…The circuit may tie social space representation and affective touch action representation. Additionally, in terms of affective touch, neurons in the hand region of SII and the adjacent posterior insular cortex (pIC) have selectivity regarding the type of hand-manipulation that represents hand motor components during grooming, handfinger exploration, and precision grasping (Ishida et al, 2013). Furthermore, the insular cortex is the center of the integration between exteroception (e.g., CT afferents) and interoception, and it interfaces with the limbic system (Mufson et al, 1981;Mufson, 1982a, 1982b;Chikama et al, 1997;Saleem et al, 2008).…”

Section: Fig 5 (A)mentioning

confidence: 99%

Predictive coding accounts of shared representations in parieto-insular networks

2015

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“…Neurones in the S2 have been found to process not just somatosensory information, but also actions in object manipulation, specifically in the stages of motor hand grasping (Ishida et al, 2013), suggesting a role in haptic integration. The S2 also appears to encode more cognitive aspects of tactile processing, such as having representations of present and past sensory information, modulations with attention, comparisons between stimuli, correlations with behavioural decisions, and tactile discrimination learning (Hsiao et al, 2002;Murray and Mishkin, 1984;Romo et al, 2002a;Romo et al, 2002b).…”

Section: Cortical Processing Of Tactile Somatosensory Inputsmentioning

confidence: 99%

The role of tactile afference in shaping motor behaviour and implications for prosthetic innovation

Ackerley

Kavounoudias

2015

Neuropsychologia

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The present review focusses on how tactile somatosensory afference is encoded and processed, and how this information is interpreted and acted upon in terms of motor control. We relate the fundamental workings of the sensorimotor system to the rehabilitation of amputees using modern prosthetic interventions. Our sense of touch is central to our everyday lives, from allowing us to manipulate objects accurately to giving us a sense of self-embodiment. There are a variety of specialised cutaneous mechanoreceptive afferents, which differ in terms of type and density according to the skin site. In humans, there is a dense innervation of our hands, which is reflected in their vast over-representation in somatosensory and motor cortical areas. We review the accumulated evidence from animal and human studies about the precise interplay between the somatosensory and motor systems, which is highly integrated in many brain areas and often not separable. The glabrous hand skin provides exquisite, discriminative detail about touch, which is useful for refining movements. When these signals are disrupted, such as through injury or amputation, the consequences are considerable. The development of sensory feedback in prosthetics offers a promising avenue for the full integration of a missing body part. Real-time touch feedback from motor intentions aids in grip control and the ability to distinguish different surfaces, even introducing the possibility of pleasure in artificial touch. Thus, our knowledge from fundamental research into sensorimotor interactions should be used to develop more realistic and integrative prostheses.

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Somato-Motor Haptic Processing in Posterior Inner Perisylvian Region (SII/pIC) of the Macaque Monkey

Cited by 36 publications

References 91 publications

Functional Properties of Parietal Hand Manipulation–related Neurons and Mirror Neurons Responding to Vision of Own Hand Action

Functional Properties of Parietal Hand Manipulation–related Neurons and Mirror Neurons Responding to Vision of Own Hand Action

Predictive coding accounts of shared representations in parieto-insular networks

The role of tactile afference in shaping motor behaviour and implications for prosthetic innovation

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