Randomization and resilience of brain functional networks as systems-level endophenotypes of schizophrenia

Lo, Chun Yi Zac; Su, Tsung Wei; Huang, Chu-Chung; Hung, Chia Chun; Chen, Wei Ling; Lan, Tsuo Hung; Lin, Ching Po; Bullmore, Edward T.

doi:10.1073/pnas.1502052112

Cited by 119 publications

(102 citation statements)

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“…A recent graph theoretical network study of patients with schizophrenia and first‐degree relatives of patients did reveal a reduced clustering coefficient in both groups with respect to controls (Lo et al. 2015). In comparison with this study, a smaller sample size ( n = 79) was used, as well as absolute wavelet correlation matrices to construct binary undirected graphs.…”

Section: Discussionmentioning

confidence: 99%

“…In addition, a graph theoretical network study of patients with schizophrenia and first‐degree relatives of patients has shown similar functional network randomization between these two groups, suggesting that this represents a marker of familial risk (Lo et al. 2015). The thus far more frequently used traditional methods (seed‐based correlation, ICA) consistently showed that unaffected siblings/first‐degree relatives share functional connectivity network alterations with their affected siblings (e.g., Whitfield‐Gabrieli and Ford 2012; Fornito et al.…”

Section: Introductionmentioning

confidence: 99%

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Reduced specialized processing in psychotic disorder: a graph theoretical analysis of cerebral functional connectivity

et al. 2016

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BackgroundPrevious research has shown that the human brain can be represented as a complex functional network that is characterized by specific topological properties, such as clustering coefficient, characteristic path length, and global/local efficiency. Patients with psychotic disorder may have alterations in these properties with respect to controls, indicating altered efficiency of network organization. This study examined graph theoretical changes in relation to differential genetic risk for the disorder and aimed to identify clinical correlates.MethodsAnatomical and resting‐state MRI brain scans were obtained from 73 patients with psychotic disorder, 83 unaffected siblings, and 72 controls. Topological measures (i.e., clustering coefficient, characteristic path length, and small‐worldness) were used as dependent variables in a multilevel random regression analysis to investigate group differences. In addition, associations with (subclinical) psychotic/cognitive symptoms were examined.ResultsPatients had a significantly lower clustering coefficient compared to siblings and controls, with no difference between the latter groups. No group differences were observed for characteristic path length and small‐worldness. None of the topological properties were associated with (sub)clinical psychotic and cognitive symptoms.ConclusionsThe reduced ability for specialized processing (reflected by a lower clustering coefficient) within highly interconnected brain regions observed in the patient group may indicate state‐related network alterations. There was no evidence for an intermediate phenotype and no evidence for psychopathology‐related alterations.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Reduced specialized processing in psychotic disorder: a graph theoretical analysis of cerebral functional connectivity

et al. 2016

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“…Finally, two graph theoretical studies (i.e. studies modeling topological patterns of connections in complex networks using nodes and lines) which analysed resting-state fMRI data referred to resilience from the perspective of functional brain networks [8,9]. Lo et al [8] reported an abnormal shift to greater randomization of brain network topology in patients with schizophrenia and their first-degree relatives compared to healthy volunteers, suggesting a marker of genetic or shared environmental risk for disorder.…”

Section: Key Pointsmentioning

confidence: 99%

“…studies modeling topological patterns of connections in complex networks using nodes and lines) which analysed resting-state fMRI data referred to resilience from the perspective of functional brain networks [8,9]. Lo et al [8] reported an abnormal shift to greater randomization of brain network topology in patients with schizophrenia and their first-degree relatives compared to healthy volunteers, suggesting a marker of genetic or shared environmental risk for disorder. These findings were associated with greater resilience to targeted attacks in silico, which was assessed as the simulated global efficiency of the remaining network after removing higher-degree nodes, implying a survival advantage of the integrity of brain networks with respect to real-life gray matter volume deficits [8].…”

Section: Key Pointsmentioning

confidence: 99%

Resilience research in schizophrenia

Mizuno

Wartelsteiner

Frajo-Apor

2016

Current Opinion in Psychiatry

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“…Furthermore, graph theory has provided abundant information on the brain's functional organization in both normal and abnormal states (Park and Friston, 2013;Fornito et al, 2016). Accumulative evidence of graph analysis on human rs-fMRI research points to its potential to identify endophenotypes of brain disorders (Bullmore and Sporns, 2009a;Wang et al, 2010b;Lo et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Functional network study on the wild type and DISC1 transgenic mice

Wu¹

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Major mental disorders such as schizophrenia (SZ), bipolar disorder and major depression create a heavy social burden and remain poorly treated. Recent reports examining the genetic and molecular structure of brain disorders discovered the gene Disrupted-in-Schizophrenia 1 (DISC1) to be significantly associated with these disorders and plays a substantial role in influencing a range of shared endophenotypes underlying these disorders. This has led to a powerful gateway to explore the underlying pathology and to achieve better diagnosis and treatments of major mental diseases. Characterising the phenotypes of DISC1 in brain functions would provide valuable insights into the mechanism of how this gene influences the brain.Resting-state fMRI (rs-fMRI) is a powerful technique being applied to more than 30 different kinds of brain disorders and different species. Findings from rs-fMRI studies on humans provide ample evidence of abnormal functional patterns in patients with mental illnesses. Specifically, altered functional connectivity (FC) and network topologies are proposed to be plausible imaging endophenotypes of psychotic disorders. However, little is known about the direct effects of gene dysfunction, such as DISC1 mutations, on restingstate brain activations. One aim of this thesis is to investigate the impacts of DISC1 on variations of resting-state functional networks (RSNs) in anaesthetized mouse brains using DISC1 transgenic mice and rs-fMRI.Before characterizing disease phenotypes in mouse models, it is necessary to understand how the mouse brain functions in normal states. Anaesthesia is currently an integrated part of most mouse rs-fMRI experiment. However, it influences blood-oxygenation-leveldependent (BOLD) fMRI signals via modulation of neurovascular coupling and brain metabolism, and therefore alters FC and topologies of RSNs. Investigating FC and its changes associated with genes therefore initially requires an understanding of the anaesthetics. Furthermore, various anaesthetic protocols are adopted by different labs leading to difficulties in result comparisons. The brain is a complex and hierarchical system, whereby its RSN architecture can be characterised from mutiple perspectives at regional or global levels. Previous mouse rs-fMRI studies have focused on long-distance FC, however, given the non-uniform influence of anaesthesia on the brain, mapping functional activations across scales in mice under different anaesthetics remain sparsely explored. Establishing this relationahsip would provide a reliable reference to study mouse brain functions in abnormal states and facilitate comparisons across laboratories. | P a g eIn the first aim of this thesis, I investigated the local connectivity in wide type (WT) mice under six commonly used anaesthetic regimens. I identified that the regional connectivity altered across the brain as a function of the expression density of receptors relative to specific agents. In addition, the depth of anaesthesia influences local synchronization.In the seco...

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Randomization and resilience of brain functional networks as systems-level endophenotypes of schizophrenia

Cited by 119 publications

References 58 publications

Reduced specialized processing in psychotic disorder: a graph theoretical analysis of cerebral functional connectivity

Reduced specialized processing in psychotic disorder: a graph theoretical analysis of cerebral functional connectivity

Resilience research in schizophrenia

Functional network study on the wild type and DISC1 transgenic mice

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