Synchronous with Your Feelings: Sensorimotor γ Band and Empathy for Pain

Betti, Viviana; Zappasodi, Filippo; Rossini, Paolo Maria; Aglioti, Salvatore Maria; Tecchio, Franca

doi:10.1523/jneurosci.2759-09.2009

Cited by 58 publications

(38 citation statements)

References 69 publications

(89 reference statements)

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“…A recent study demonstrated that TMS over SI selectively reduced the typical corticospinal mapping of biomechanically impossible movements [Fadiga et al, 1995[Fadiga et al, , 2005Romani et al, 2005], which were associated with aversive somatic feelings, without impacting mirror responses to possible movements that did not evoke somatic feelings in the observer. Modulation of SI activity that is contingent upon observation of others' pain has also been described [Betti et al, 2009;Bufalari et al, 2007]. Therefore, it seems that the mirror function of SI is that of preferentially encoding the somatic component of action simulation.…”

Section: Discussionmentioning

confidence: 95%

“…Action observation and execution increases neural activity in both motor and somatosensory areas [Rizzolatti and Craighero, 2004]. Crucially, making the perceived action painful or more salient from a tactile or proprioceptive point of view causes an increase of the activity in SI Betti et al, 2009;Bufalari et al, 2007;Costantini et al, 2005]. A recent study demonstrated that TMS over SI selectively reduced the typical corticospinal mapping of biomechanically impossible movements [Fadiga et al, 1995[Fadiga et al, , 2005Romani et al, 2005], which were associated with aversive somatic feelings, without impacting mirror responses to possible movements that did not evoke somatic feelings in the observer.…”

Section: Discussionmentioning

confidence: 99%

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Seeing touch in the somatosensory cortex: A TMS study of the visual perception of touch

Bolognini¹,

Rossetti²,

Maravita³

et al. 2011

Human Brain Mapping

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Recent studies suggest the existence of a visuo-tactile mirror system, comprising the primary (SI) and secondary (SII) somatosensory cortices, which matches observed touch with felt touch. Here, repetitive transcranial magnetic stimulation (rTMS) was used to determine whether SI or SII play a functional role in the visual processing of tactile events. Healthy participants performed a visual discrimination task with tactile stimuli (a finger touching a hand) and a control task (a finger moving without touching). During both tasks, rTMS was applied over either SI or SII, and to the occipital cortex. rTMS over SI selectively reduced subject performance for interpreting whether a contralateral visual tactile stimulus contains a tactile event, whereas SII stimulation impaired visual processing regardless of the tactile component. These findings provide evidence for a multimodal sensory-motor system with mirror properties, where somatic and visual properties of action converge. SI, a cortical area traditionally viewed as modality-specific, is selectively implicated in the visual processing of touch. These results are in line with the existence of a sensory mirror system mediating the embodied simulation concept. Hum Brain Mapp 32:2104-2114,

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Section: Discussionmentioning

confidence: 95%

Section: Discussionmentioning

confidence: 99%

Seeing touch in the somatosensory cortex: A TMS study of the visual perception of touch

Bolognini¹,

Rossetti²,

Maravita³

et al. 2011

Human Brain Mapping

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show abstract

“…This role is not limited to neural synchrony of local brain networks, but also extends to large-scale interactions. [40][41][42][43] Therefore, investigations of connectivity, rather than power, in the resting state might contribute to disentangling the discrepancies of previous research, providing new insights into the role of gamma-band connectivity in the pathophysiology of the disorder. So far, only 2 studies have assessed gamma-band synchronization in patients with schizophrenia.…”

Section: Introductionmentioning

confidence: 99%

Increased Resting-State Gamma-Band Connectivity in First-Episode Schizophrenia

Andreou

Nolte

Leicht

et al. 2014

SCHBUL

114

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Background: Schizophrenia has long been suggested to represent a disorder with prominent neural dysconnectivity. Gamma-band oscillations are highly relevant in this context, due both to their proposed involvement in neuronal synchronization and to their association with neurotransmitter systems relevant for schizophrenia. Several task-related studies have confirmed reduced power and synchronization of gamma-band oscillations in schizophrenia, but it has been suggested that these findings might not apply to the resting state. The present study aimed to investigate resting-state gamma-band connectivity in patients with schizophrenia. Methods: Sixtyfour channel resting-state electroencephalography (eyes closed) was recorded in 22 patients with first-episode schizophrenia and 22 healthy controls matched for age and gender. Orthogonalized power envelope correlation was used as a measure of connectivity across 80 cortical regions at 40 Hz. Mean connectivity at each region was compared across groups using the nonparametric randomization approach. Additionally, the network-based statistic was applied to identify affected networks in patients. Results: Patients displayed increased mean functional gamma-band connectivity compared to controls in the left rolandic operculum. Network-based analyses indicated increased connectivity in patients within a strongly lateralized network consisting mainly of left inferior frontal/ orbitofrontal, lateral and medial temporal, and inferior parietal areas. Within this network, gamma-band connectivity was higher in patients with low positive and disorganization symptom levels. Conclusions: The present study provides a link between resting-state gamma-band connectivity and the core symptoms of schizophrenia. The observed findings are different than those reported by task-related studies, suggesting that resting-state studies might reveal new aspects in the pathophysiology of schizophrenia.

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“…Thus, this mechanism may also be important for multisensory interactions contributing to pain perception. First evidence supporting this assumption derives from the study by Betti et al [2], who reported enhanced functional coupling between primary sensory and motor cortex through neural coherence in the gamma band when participants are presented with needle-penetrating-hand clips. Thus, we suggest that the examination of oscillatory activity is a promising research target for future studies on pain processing in multisensory environments.…”

Section: Discussionmentioning

confidence: 98%

“…A more recent MEG study further investigated the effect of observing painful events on neuronal processing within the pain matrix [2]. The authors addressed the interplay of somatosensory and motor areas during the presentation of needlepenetrating-hand clips.…”

Section: Box 2: Human Experimental Pain Modelsmentioning

confidence: 99%

Pain processing in multisensory environments

et al. 2010

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Abstract“Don’t look and it won’t hurt” is common advice heard before receiving an injection, but is there any truth in this statement? Pain processing can be separated into two major components: a sensory-discriminative component, which reflects the location and intensity of a painful event, and an affective-motivational component that reflects the unpleasantness of pain. The differentiation between these components and the effects of additional sensory inputs on them becomes apparent if you watch a needle penetrating your skin: On the one hand, it may be somewhat reassuring to know precisely when and where to expect the pinprick, on the other hand, you eye-witness damage inflicted on your body, which can increase personal distress. Here we review recent studies, which demonstrate that a host of variables such as onset timing, spatial alignment, semantic meaning, and attention differentially affect how visual inputs influence pain processing. These studies also indicate that there is some truth in the opening statement.

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Synchronous with Your Feelings: Sensorimotor γ Band and Empathy for Pain

Cited by 58 publications

References 69 publications

Seeing touch in the somatosensory cortex: A TMS study of the visual perception of touch

Seeing touch in the somatosensory cortex: A TMS study of the visual perception of touch

Increased Resting-State Gamma-Band Connectivity in First-Episode Schizophrenia

Pain processing in multisensory environments

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