Resting-state functional heterogeneity of the right insula contributes to pain sensitivity

Veréb, Dániel; Kincses, Bálint; Spisák, Tamás; Schlitt, Frederik; Szabó, Nikoletta; Faragó, Péter; Kocsis, Krisztián; Bozsik, Bence; Tóth, Eszter; Király, András; Zunhammer, Matthias; Schmidt‐Wilcke, Tobias; Bingel, Ulrike; Kincses, Zsigmond Tamás

doi:10.1038/s41598-021-02474-x

Cited by 17 publications

(12 citation statements)

References 41 publications

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“…In fact, recent meta-analytic evidence of resting-state functional connectivity points to the existence of a pain-related network centered on the anterior insula [40]. The activation associated with both pain-related (posterior insula) activation, and that associated with PE-related (anterior insula) activation correspond well with connectivity gradients observed along the posterior-anterior axis [41][42][43].…”

Section: Discussionmentioning

confidence: 67%

Pain-related learning signals in the human insula

Horing

Büchel

2022

Preprint

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Pain is not only a perceptual phenomenon, but also a preeminent learning signal. In reinforcement learning models, prediction errors (PEs) play a crucial role, i.e. the mismatch between expectation and sensory input. In particular, advanced learning models require the representation of different types of PEs, namely signed PEs (whether more or less pain was expected) to specify the direction of learning, and unsigned PEs (the absolute deviation from an expectation) to adapt the learning rate. The insula has been shown to play an important role in pain intensity coding and in signaling surprise. However, mainly unsigned PEs could be identified in the anterior insula. It remains an open question whether these PEs are specific to pain, and whether signed PEs are also represented in the insula. To answer these questions, 47 subjects learned associations of two conditioned stimuli (CS) with four unconditioned stimuli (US; painful heat or loud sound, of one low and one high intensity each) while undergoing functional magnetic resonance imaging (fMRI) and skin conductance response (SCR) measurements. CS-US associations reversed multiple times between intensities and between sensory modalities, generating frequent PEs. SCRs indicated comparable nonspecific characteristics of the two modalities. fMRI analyses focusing on the insular and opercular cortices contralateral to painful stimulation showed that activation in the anterior insula correlated with unsigned intensity PEs. Importantly, this unsigned PE signal was similar for pain and aversive sounds and also modality PEs, indicating an unspecific aversive surprise signal. Conversely, signed pain intensity PE signals were modality-specific and located in the dorsal posterior insula, an area previously implicated in pain intensity processing. Previous studies have identified abnormal insula function and abnormal learning as potential causes of pain chronification. Our findings link these results and suggest one potential mechanism, namely a misrepresentation of learning relevant prediction errors in the insular cortex.

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Section: Discussionmentioning

confidence: 67%

Pain-related learning signals in the human insula

Horing

Büchel

2022

Preprint

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“…However, recent investigation has suggested the region may be better appreciated as a gradually changing topographical gradient of functional and anatomical connections along the rostrocaudal axis. While discrete subunits are described throughout this manuscript, selecting small/discrete subregions of interest for analysis may provide significant results that may not reflect the totality of activations or connectivity in a given brain region ( 162 , 163 ).…”

Section: Central Representation Of Painmentioning

confidence: 99%

“…Anterior insula (AI) is involved in processing emotion, including empathy, and activation of this subregion is found in affective processing ( 161 , 164 ). AI has strong functional and anatomical connections with the thalamus and cognitive and emotional parts of the prefrontal cortex as well as the amygdala and some cingulate regions, particularly the ACC, and can have increased or decreased functional associations with these areas in chronic pain ( 163 , 164 ). The strongest connections to the prefrontal cortex are to the dorsolateral prefrontal cortex, as well as areas associated with cognitive-evaluative processing and outcome anticipation (orbitofrontal cortex) and with the regulation of emotions and cognitive pain modulation (ventrolateral prefrontal cortex) ( 163 , 164 ).…”

Section: Central Representation Of Painmentioning

confidence: 99%

“…AI has strong functional and anatomical connections with the thalamus and cognitive and emotional parts of the prefrontal cortex as well as the amygdala and some cingulate regions, particularly the ACC, and can have increased or decreased functional associations with these areas in chronic pain ( 163 , 164 ). The strongest connections to the prefrontal cortex are to the dorsolateral prefrontal cortex, as well as areas associated with cognitive-evaluative processing and outcome anticipation (orbitofrontal cortex) and with the regulation of emotions and cognitive pain modulation (ventrolateral prefrontal cortex) ( 163 , 164 ). Expectation and behavioral avoidance of a negative outcome activate AI, and the region is thought to impose emotional states that are informed by the evaluation of affective events ( 161 , 164 ).…”

Section: Central Representation Of Painmentioning

confidence: 99%

“…Posterior insular (PI) regions are thought to process interoceptive, somatosensory, visceral, and pain stimuli ( 7 , 161 , 164 , 165 ). PI has its strongest connections to SII (structural and resting state analyses) and SI (structural) along with other somatosensory areas, and has some resting state association with the pMCC as well ( 163 , 164 ). Activations in PI are found as stimuli progress from innocuous to painful in intensity with little activation in the absence of noxious input.…”

Section: Central Representation Of Painmentioning

confidence: 99%

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Supraspinal Mechanisms Underlying Ocular Pain

Pondelis

Moulton

2022

Front. Med.

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Supraspinal mechanisms of pain are increasingly understood to underlie neuropathic ocular conditions previously thought to be exclusively peripheral in nature. Isolating individual causes of centralized chronic conditions and differentiating them is critical to understanding the mechanisms underlying neuropathic eye pain and ultimately its treatment. Though few functional imaging studies have focused on the eye as an end-organ for the transduction of noxious stimuli, the brain networks related to pain processing have been extensively studied with functional neuroimaging over the past 20 years. This article will review the supraspinal mechanisms that underlie pain as they relate to the eye.

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Somatotopic disruption of the functional connectivity of the primary sensorimotor cortex in complex regional pain syndrome type 1

Hotta,

Saari,

Harno

et al. 2023

Human Brain Mapping

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In complex regional pain syndrome (CRPS), the representation area of the affected limb in the primary sensorimotor cortex (SM1) reacts abnormally during sensory stimulation and motor actions. We recorded 3T functional magnetic resonance imaging resting‐state data from 17 upper‐limb CRPS type 1 patients and 19 healthy control subjects to identify alterations of patients' SM1 function during spontaneous pain and to find out how the spatial distribution of these alterations were related to peripheral symptoms. Seed‐based correlations and independent component analyses indicated that patients' upper‐limb SM1 representation areas display (i) reduced interhemispheric connectivity, associated with the combined effect of intensity and spatial extent of limb pain, (ii) increased connectivity with the right anterior insula that positively correlated with the duration of CRPS, (iii) increased connectivity with periaqueductal gray matter, and (iv) disengagement from the other parts of the SM1 network. These findings, now reported for the first time in CRPS, parallel the alterations found in patients suffering from other chronic pain conditions or from limb denervation; they also agree with findings in healthy persons who are exposed to experimental pain or have used their limbs asymmetrically. Our results suggest that CRPS is associated with a sustained and somatotopically specific alteration of SM1 function, that has correspondence to the spatial distribution of the peripheral manifestations and to the duration of the syndrome.

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Resting-state functional heterogeneity of the right insula contributes to pain sensitivity

Cited by 17 publications

References 41 publications

Pain-related learning signals in the human insula

Pain-related learning signals in the human insula

Supraspinal Mechanisms Underlying Ocular Pain

Somatotopic disruption of the functional connectivity of the primary sensorimotor cortex in complex regional pain syndrome type 1

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