Functional neuroimaging of conversion disorder: The role of ancillary activation

Burke, Matthew J.; Ghaffar, Omar; Staines, Richard; Downar, Jonathan; Feinstein, Anthony

doi:10.1016/j.nicl.2014.09.016

Cited by 21 publications

(13 citation statements)

References 35 publications

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“…Here, we specifically extend these findings by linking ACC cortical thickness to the magnitude of endorsed somatoform dissociation experienced by patients with motor FND. An extensive literature connects the ACC to the neuropathobiology of FND (Aybek, et al, 2015; Burke, et al, 2014; Mailis-Gagnon, et al, 2003; Marshall, et al, 1997; Perez, et al, 2012; Perez, et al, 2015; Saj, et al, 2009; Voon, et al, 2016), including resting state studies characterizing abnormal ACC connectivity profiles linked to dissociation (van der Kruijs, et al, 2012) and PNES frequency (Li, et al, 2015). The caudal ACC, implicated in appraisal and the behavioral expression of affective states, is structurally connected to lateral prefrontal and premotor regions (Etkin, et al, 2011).…”

Section: Discussionmentioning

confidence: 99%

Cortical thickness alterations linked to somatoform and psychological dissociation in functional neurological disorders

Perez

Matin

Williams

et al. 2017

Human Brain Mapping

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Background: Links between dissociation and functional neurological disorder (FND)/conversion disorder are well-established, yet the pathophysiology of dissociation remains poorly understood. This MRI study investigated structural alterations associated with somatoform and psychological dissociation in FND. We hypothesized that multimodal, paralimbic cingulo-insular regions would relate to the severity of somatoform dissociation in patients with FND. Methods: FreeSurfer cortical thickness and subcortical volumetric analyses were performed in 26 patients with motor FND and 27 matched healthy controls. Patients with high dissociation as measured by the Somatoform Dissociation Questionnaire-20 (SDQ) or Dissociative Experiences Scale (DES) were compared to controls in stratified analyses. Within-group analyses were also performed with SDQ and DES scores in patients with FND. All cortical thickness analyses were whole-brain corrected at the cluster-wise level. somatoform dissociation (SDQ > 35) showed reduced left caudal anterior cingulate cortex (ACC) cortical thickness compared to controls. In within-group analyses, SDQ scores inversely correlated with left caudal ACC cortical thickness in patients with FND. Depersonalization/derealization scores positively correlated with right lateral occipital cortical thickness. Both within-group findings remained statistically significant controlling for trait anxiety/depression, borderline personality disorder and posttraumatic stress disorder, adverse life events, and motor FND subtypes in post-hoc analyses. Conclusion: Using complementary between-group and within-group analyses, an inverse association between somatoform dissociation and left caudal ACC cortical thickness was observed in patients with FND. A positive relationship was also appreciated between depersonalization/derealization severity and cortical thickness in visual association areas. These findings advance our neuropathobiological understanding of dissociation in FND. Hum Brain Mapp 39:428-439, 2018.V C 2017 Wiley Periodicals, Inc.

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Section: Discussionmentioning

confidence: 99%

Cortical thickness alterations linked to somatoform and psychological dissociation in functional neurological disorders

Perez

Matin

Williams

et al. 2017

Human Brain Mapping

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“…On the other hand, several imaging studies consistently observed activity in the IFG of CD patients with motor symptoms ( Stone et al, 2007 ), sensory ( Mailis-Gagnon et al, 2003 ), visual loss ( Werring et al, 2004 ) or amnestic disorders ( Kanaan et al, 2007 , Markowitsch et al, 1997 ). Depending on the employed experimental paradigms such as attempted movement execution ( Marshall et al, 1997 ), movement observation ( Burgmer et al, 2006 ), movement inhibition ( Cojan et al, 2009 ), mental rotation ( de Lange et al, 2010 ) or vibratory stimulation ( Burke et al, 2014 , Vuilleumier et al, 2001 ) studies have described several different neural structures to be involved or abnormally active in CD. Some of the differences could also steam from the type of paresis (flaccid or with muscle tone increase) of the CD patients that might have different neural correlates due to different levels of inhibition.…”

Section: Discussionmentioning

confidence: 99%

“…Brain areas in the lateral and medial frontal cortex as well as the supplementary motor area and basal ganglia have been suggested to be involved in this condition (for review see ( Bell et al, 2011 )). The diversity of the employed study paradigms like motor execution ( Spence et al, 2000 , Stone et al, 2007 , van Beilen et al, 2011 ), Go/Nogo ( Cojan et al, 2009 ), implicit ( de Lange et al, 2007 , de Lange et al, 2008 ) and explicit motor imagery ( Burgmer et al, 2013 , van Beilen et al, 2011 ) or vibratory stimulation ( Burke et al, 2014 , Vuilleumier et al, 2001 ) have provided a wide range of brain areas that could be involved in the clinical condition but did not isolate a core component. In addition the different and rather small sample sizes, the lack of control in motor imagery and motor execution paradigms in paretic patients as well as the heterogeneity of the included patients probably contributed to the divergent results.…”

Section: Introductionmentioning

confidence: 99%

Functional networks of motor inhibition in conversion disorder patients and feigning subjects

Hassa

Jel

Tuescher

et al. 2016

NeuroImage: Clinical

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The neural correlates of motor inhibition leading to paresis in conversion disorder are not well known. The key question is whether they are different of those of normal subjects feigning the symptoms. Thirteen conversion disorder patients with hemiparesis and twelve healthy controls were investigated using functional magnetic resonance tomography under conditions of passive motor stimulation of the paretic/feigned paretic and the non-paretic hand. Healthy controls were also investigated in a non-feigning condition. During passive movement of the affected right hand conversion disorder patients exhibited activations in the bilateral triangular part of the inferior frontal gyri (IFG), with a left side dominance compared to controls in non-feigning condition. Feigning controls revealed for the same condition a weak unilateral activation in the right triangular part of IFG and an activity decrease in frontal midline areas, which couldn't be observed in patients. The results suggest that motor inhibition in conversion disorder patients is mediated by the IFG that was also involved in inhibition processes in normal subjects. The activity pattern in feigning controls resembled that of conversion disorder patients but with a clear difference in the medial prefrontal cortex. Healthy controls showed decreased activity in this region during feigning compared to non-feigning conditions suggesting a reduced sense of self-agency during feigning. Remarkably, no activity differences could be observed in medial prefrontal cortex for patients vs healthy controls in feigning or non-feigning conditions suggesting self-agency related activity in patients to be in between those of non-feigning and feigning healthy subjects.

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“…In one study, ten subjects underwent unilateral vibrotactile stimulation of their symptomatic and asymptomatic limbs. 37 Ten brain areas showed significantly greater activation when stimulation was applied to the anesthetic body part compared to the contralateral side: right paralimbic cortices (insula and anterior cingulate cortex [ACC]), the right TPJ (angular gyrus and inferior parietal lobule), bilateral DLPFC, right orbital frontal cortex, right caudate, right ventral anterior thalamus, and left angular gyrus. Mailis-Gagnon et al reported on four patients with chronic pain and non-dermatomal sensory loss, who had deactivation of somatosensory cortex along with increased activity in the right ACC during evoked potential perceived touch, or noxious stimuli compared to unperceived stimuli.…”

Section: Methodsmentioning

confidence: 99%

Uncovering the etiology of conversion disorder: insights from functional neuroimaging

Dar¹,

Kanaan²

2016

NDT

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Conversion disorder (CD) is a syndrome of neurological symptoms arising without organic cause, arguably in response to emotional stress, but the exact neural substrates of these symptoms and the underlying mechanisms remain poorly understood with the hunt for a biological basis afoot for centuries. In the past 15 years, novel insights have been gained with the advent of functional neuroimaging studies in patients suffering from CDs in both motor and nonmotor domains. This review summarizes recent functional neuroimaging studies including functional magnetic resonance imaging (fMRI), single photon emission computerized tomography (SPECT), and positron emission tomography (PET) to see whether they bring us closer to understanding the etiology of CD. Convergent functional neuroimaging findings suggest alterations in brain circuits that could point to different mechanisms for manifesting functional neurological symptoms, in contrast with feigning or healthy controls. Abnormalities in emotion processing and in emotion-motor processing suggest a diathesis, while differential reactions to certain stressors implicate a specific response to trauma. No comprehensive theory emerges from these clues, and all results remain preliminary, but functional neuroimaging has at least given grounds for hope that a model for CD may soon be found.

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Functional neuroimaging of conversion disorder: The role of ancillary activation

Cited by 21 publications

References 35 publications

Cortical thickness alterations linked to somatoform and psychological dissociation in functional neurological disorders

Cortical thickness alterations linked to somatoform and psychological dissociation in functional neurological disorders

Functional networks of motor inhibition in conversion disorder patients and feigning subjects

Uncovering the etiology of conversion disorder: insights from functional neuroimaging

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