Cerebellar-Thalamic Connectivity in Schizophrenia

Deanna, M

doi:10.1093/schbul/sbu076

Cited by 42 publications

(29 citation statements)

References 69 publications

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“…It has been suggested (Ferrarelli et al, ) that impairments in spindle activity in schizophrenia patients and in relatives sharing the genetic background (Manoach et al, ; Schilling et al, ) reflect deficits in thalamic‐reticular and thalamocortical mechanisms (Buchmann et al, ), representing a biological marker of schizophrenia. Functional magnetic resonance imaging (fMRI) resting‐state studies support the notion of functional abnormalities in thalamocortical circuits in schizophrenia (Barch, ), reporting reduced thalamic‐prefrontal cortex connectivity (Anticevic et al, ; Woodward, Karbasforoushan, & Heckers, ) as well as enhanced thalamic‐sensory motor cortices connectivity (Anticevic et al, ; Klingner et al, ; Woodward et al, ), which correlated with symptom severity in a longitudinal fMRI study (Anticevic et al, ). Furthermore, in the longitudinal fMRI resting‐state study, thalamic connectivity abnormalities predated the onset of schizophrenia (Anticevic et al, ).…”

Section: Introductionmentioning

confidence: 89%

Genetic risk factors for schizophrenia associate with sleep spindle activity in healthy adolescents

Merikanto

Utge

Lahti

et al. 2018

Journal of Sleep Research

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Schizophrenia has been associated with disturbed sleep, even before the onset of the disorder, and also in non-schizophrenic first-order relatives. This may point to an underlying genetic influence. Here we examine whether weighted polygenic risk scores (PRS) for schizophrenia are associated with sleep spindle activity in healthy adolescents. Our sample comes from a community-based cohort of 157 non-schizophrenic adolescents (57% girls) having both genetic data and an overnight sleep EEG measurement available. Based on a recent genome-wide association study, we calculated PRS for schizophrenia across the whole genome. We also calculated PRS for the CACNA1l gene region, which has been associated with both schizophrenia and sleep spindle formation. We performed an overnight sleep EEG at the homes of the participants. Stage two sleep spindles were detected using an automated algorithm. Sleep spindle amplitude, duration, intensity and density were measured separately for central and frontal derivations and for fast (13-16 Hz) and slow (10-13 Hz) spindles. PRS for schizophrenia was associated with higher fast spindle amplitude (p = 0.04), density (p = 0.006) and intensity (p = 0.04) at the central derivation, and PRS in the CACNA1l region associated with higher slow spindle amplitude (p = 0.01), duration (p = 0.03) and intensity (p = 0.002) at the central derivation. A positive association between genetic variants for schizophrenia and sleep spindle activity among healthy adolescents supports a view that sleep spindles and schizophrenia share similar genetic pathways. This study suggests that altered sleep spindle activity might serve as an endophenotype of schizophrenia.

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Section: Introductionmentioning

confidence: 89%

Genetic risk factors for schizophrenia associate with sleep spindle activity in healthy adolescents

Merikanto

Utge

Lahti

et al. 2018

Journal of Sleep Research

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“…Working memory processes encompass the ability to temporarily store and manipulate information “on-line” and given its relationship to the functioning of the dlPFC, is closely linked with executive functioning ability (for review, see Barch & Sheffield, 2014). Due to such reliable impairments in working memory in schizophrenia, five studies assessed its relationship with functional connectivity.…”

Section: Review Of Resting-state Functional Connectivity and Cognimentioning

confidence: 99%

“…In addition, abnormalities in the cerebellum have also been observed in schizophrenia, with evidence of white matter abnormalities within certain cerebellar lobes (Kim et al, 2014), as well as abnormal size and decreased blood flow in the cerebellum during a broad range of cognitive tasks (Andreasen et al, 2008; Barch, 2014). Importantly, reduced functional connectivity between the cerebellum and medial dorsal nucleus of the thalamus has been observed in schizophrenia, providing evidence of abnormalities in this portion of the CCTCC as well (Anticevic et al, 2014; Collin et al, 2011).…”

Section: 1 Cognitive Dysmetria and The Cortico-cerebellar-thalamic-mentioning

confidence: 99%

Cognition and resting-state functional connectivity in schizophrenia

Sheffield

Deanna

2016

Neuroscience & Biobehavioral Reviews

305

190

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Individuals with schizophrenia consistently display deficits in a multitude of cognitive domains, but the neurobiological source of these cognitive impairments remains unclear. By analyzing the functional connectivity of resting-state functional magnetic resonance imaging (rs-fcMRI) data in clinical populations like schizophrenia, research groups have begun elucidating abnormalities in the intrinsic communication between specific brain regions, and assessing relationships between these abnormalities and cognitive performance in schizophrenia. Here we review studies that have reported analysis of these brain-behavior relationships. Through this systematic review we found that patients with schizophrenia display abnormalities within and between regions comprising 1) the cortico-cerebellar-striatal-thalamic loop and 2) task-positive and task-negative cortical networks. Importantly, we did not observe unique relationships between specific functional connectivity abnormalities and distinct cognitive domains, suggesting that the observed functional systems may underlie mechanisms that are shared across cognitive abilities, the disturbance of which could contribute to the “generalized” cognitive deficit found in schizophrenia. We also note several areas of methodological change that we believe will strengthen this literature.

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“…Consistent with the model, the SZ group did not transition to a brain–accuracy network that engaged key subcortical, thalamic, and cerebellar regions as in the high-performing controls with the best working memory capacities. Evidence is accumulating for the thalamus as a key node in this brain–learning network in SZ (54). Studies have demonstrated thalamic hypoconnectivity between frontal and striatal regions and hyperconnectivity in sensory, somatosensory, and motor regions in chronic, early, and at-risk for SZ groups (55–58).…”

Section: Discussionmentioning

confidence: 99%

Practice and Learning: Spatiotemporal Differences in Thalamo-Cortical-Cerebellar Networks Engagement across Learning Phases in Schizophrenia

2017

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BackgroundUnderstanding how practice mediates the transition of brain–behavior networks between early and later stages of learning is constrained by the common approach to analysis of fMRI data. Prior imaging studies have mostly relied on a single scan, and parametric, task-related analyses. Our experiment incorporates a multisession fMRI lexicon-learning experiment with multivariate, whole-brain analysis to further knowledge of the distributed networks supporting practice-related learning in schizophrenia (SZ).MethodsParticipants with SZ were compared with healthy control (HC) participants as they learned a novel lexicon during two fMRI scans over a several day period. All participants were trained to equal task proficiency prior to scanning. Behavioral-Partial Least Squares, a multivariate analytic approach, was used to analyze the imaging data. Permutation testing was used to determine statistical significance and bootstrap resampling to determine the reliability of the findings.ResultsWith practice, HC participants transitioned to a brain–accuracy network incorporating dorsostriatal regions in late-learning stages. The SZ participants did not transition to this pattern despite comparable behavioral results. Instead, successful learners with SZ were differentiated primarily on the basis of greater engagement of perceptual and perceptual-integration brain regions.ConclusionThere is a different spatiotemporal unfolding of brain–learning relationships in SZ. In SZ, given the same amount of practice, the movement from networks suggestive of effortful learning toward subcortically driven procedural one differs from HC participants. Learning performance in SZ is driven by varying levels of engagement in perceptual regions, which suggests perception itself is impaired and may impact downstream, “higher level” cognition.

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Cerebellar-Thalamic Connectivity in Schizophrenia

Cited by 42 publications

References 69 publications

Genetic risk factors for schizophrenia associate with sleep spindle activity in healthy adolescents

Genetic risk factors for schizophrenia associate with sleep spindle activity in healthy adolescents

Cognition and resting-state functional connectivity in schizophrenia

Practice and Learning: Spatiotemporal Differences in Thalamo-Cortical-Cerebellar Networks Engagement across Learning Phases in Schizophrenia

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