Discriminating cognitive status in Parkinson’s disease through functional connectomics and machine learning

Abós, Alexandra; Baggio, Hugo C.; Segura, Bàrbara; García-Díaz, Anna Isabel; Compta, Yaroslau; Martı́, Marı́a José; Valldeoriola, Francesc; Junqué, Carme

doi:10.1038/srep45347

Cited by 104 publications

(61 citation statements)

References 78 publications

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“…We initially generated a ground‐truth matrix containing a pattern of connections defined as “altered,” to be used in the simulated connectivity matrices. To make these ground‐truth effects reflect a somewhat realistic topology, we performed univariate comparisons between a sample of Parkinson's disease patients with mild cognitive impairment ( n = 27) and a group of healthy controls ( n = 38), seen in a previous study by our group to have significant resting‐state functional connectivity differences (Abós et al, ). Data acquisition and image preprocessing were identical to those used in that study.…”

Section: Methodsmentioning

confidence: 99%

“…One of the most frequently used edge‐wise methods is the network‐based statistic (NBS) (Zalesky et al, ). The NBS is designed to identify clustered effects in brain graphs, and has been used in different study settings (Abós et al, ; Cocchi et al, ; Conti et al, ; McColgan et al, ; Rigon, Voss, Turkstra, Mutlu, & Duff, ; Roberts et al, ). Specifically, the NBS is a technique that aims to identify connected components, consisting of neighboring edges that display statistical effects above a predetermined threshold (Zalesky et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Statistical inference in brain graphs using threshold‐free network‐based statistics

Baggio

Abós

Segura

et al. 2018

Human Brain Mapping

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107

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The description of brain networks as graphs where nodes represent different brain regions and edges represent a measure of connectivity between a pair of nodes is an increasingly used approach in neuroimaging research. The development of powerful methods for edge-wise group-level statistical inference in brain graphs while controlling for multiple-testing associated false-positive rates, however, remains a difficult task. In this study, we use simulated data to assess the properties of threshold-free network-based statistics (TFNBS). The TFNBS combines threshold-free cluster enhancement, a method commonly used in voxel-wise statistical inference, and network-based statistic (NBS), which is frequently used for statistical analysis of brain graphs. Unlike the NBS, TFNBS generates edge-wise significance values and does not require the a priori definition of a hard cluster-defining threshold. Other test parameters, nonetheless, need to be set. We show that it is possible to find parameters that make TFNBS sensitive to strong and topologically clustered effects, while appropriately controlling false-positive rates. Our results show that the TFNBS is an adequate technique for the statistical assessment of brain graphs.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Statistical inference in brain graphs using threshold‐free network‐based statistics

Baggio

Abós

Segura

et al. 2018

Human Brain Mapping

Self Cite

107

View full text Add to dashboard Cite

show abstract

“…One sample comprised 32 non-obese healthy seniors (51-85 years old). The recruitment procedure of this group is fully described in Abós et al (2017). Briefly, exclusion criteria consisted on presence of psychiatric or neurological comorbidity, low global intelligence quotient estimated by the WAIS-III Vocabulary subtest score (> 7 scalar score) (Wechsler, 1999), and a Mini-Mental state examination score below 25 (Folstein, Folstein, & McHugh, 1975).…”

Section: Methodsmentioning

confidence: 99%

Alterations in brain network organization in adults with obesity as compared to healthy-weight individuals and seniors

Ottino‐González

Baggio

Jurado

et al. 2019

Preprint

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Life expectancy and obesity rates have drastically increased in recent years. An unhealthy weight is related to longlasting biological deregulations that might compromise the normal course of development and jeopardize the so-called "successful aging". The aim of the current study was to test whether an obesity status could mimic the functional organization of an otherwise healthy aged brain. Thus, the current study included adults with (N = 32, mean age 34.5 ± 6.49) and without obesity (N = 34, mean age 32.7 ± 6.79) as well as adolescents with obesity (N = 30, mean age 15.3 ± 2.64) and normal-weight (N = 31, mean age 15.6 ± 2.60). A sample of stroke-free non-obese and non-demented seniors was also entered (N = 32, mean age 66.1 ± 7.43). Participants underwent resting-state MRI acquisition and graph-based measurements of segregation, integration and robustness (i.e., mean degree and strength) were calculated. Obesity in adults was followed by a broad pattern of loses in robustness when compared to healthy-weight adults and seniors, as well as increases in network segregation relative to elders. Differences in adolescents followed the same direction yet they did not survive multiple comparison adjustment. No interaction emerged when exploring the transition from childhood to adulthood accounting for body-weight status. Altogether, and yet more research is needed, an obesity status could negatively render network resilience and compromise the normal course of aging. Obesity | Aging | Maturation | Resting-state | Graph-theory

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“…e SVM is presently one of the best-known classification techniques and has computational advantages over other classification methods, and many previous studies [52][53][54][55][56] have proven that the linear SVM performs well in small sample datasets. To allow the classifier to generalize unseen data well and to avoid overfitting problems, we introduced the SVM soft margin classifier.…”

Section: Two-sample T-testsmentioning

confidence: 99%

Detecting Abnormal Brain Regions in Schizophrenia Using Structural MRI via Machine Learning

Chen

Yan

Wang

et al. 2020

Computational Intelligence and Neuroscience

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Utilizing neuroimaging and machine learning (ML) to differentiate schizophrenia (SZ) patients from normal controls (NCs) and for detecting abnormal brain regions in schizophrenia has several benefits and can provide a reference for the clinical diagnosis of schizophrenia. In this study, structural magnetic resonance images (sMRIs) from SZ patients and NCs were used for discriminative analysis. is study proposed an ML framework based on coarse-to-fine feature selection. e proposed framework used two-sample t-tests to extract the differences between groups first, then further eliminated the nonrelevant and redundant features with recursive feature elimination (RFE), and finally utilized the support vector machine (SVM) to learn the decision models with selected gray matter (GM) and white matter (WM) features. Previous studies have tended to report differences at the group level instead of at the individual level and cannot be widely applied. e method proposed in this study extends the diagnosis to the individual level and has a higher recognition rate than previous methods. e experimental results of this study demonstrate that the proposed framework distinguishes SZ patients from NCs, with the highest classification accuracy reaching over 85%. e identified biomarkers are also consistent with previous literature findings. As a universal method, the proposed framework can be extended to diagnose other diseases.

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Discriminating cognitive status in Parkinson’s disease through functional connectomics and machine learning

Cited by 104 publications

References 78 publications

Statistical inference in brain graphs using threshold‐free network‐based statistics

Statistical inference in brain graphs using threshold‐free network‐based statistics

Alterations in brain network organization in adults with obesity as compared to healthy-weight individuals and seniors

Detecting Abnormal Brain Regions in Schizophrenia Using Structural MRI via Machine Learning

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