Autism spectrum disorder characterization in children by capturing local‐regional brain changes in MRI

Alvarez-Jimenez, Charlems; Múnera-Garzón, Nicolás; Zuluaga, María A.; Velasco, Nelson; Romero, Eduardo

doi:10.1002/mp.13901

Cited by 20 publications

(7 citation statements)

References 49 publications

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“…There are numerous efforts aimed at identifying cerebral markers of ASD with brain imaging techniques for diagnosis purposes (e.g., Alvarez‐Jimenez, Múnera‐Garzón, Zuluaga, Velasco, & Romero, 2020; Kong et al, 2019; Nielsen et al, 2013). However, our study along with the increasing literature reporting the absence of (Haar et al, 2016; Lefebvre et al, 2015) or very subtle (van Rooij et al, 2017) volumetric group differences, suggest that previous group differences in subcortical volumes are potentially false positives or that individual regions may not constitute useful cerebral markers to employ for the diagnosis of ASD.…”

Section: Discussionmentioning

confidence: 99%

Adjusting for allometric scaling in ABIDE I challenges subcortical volume differences in autism spectrum disorder

Williams

Peyre

Toro

et al. 2020

Human Brain Mapping

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Inconsistencies across studies investigating subcortical correlates of autism spectrum disorder (ASD) may stem from small sample size, sample heterogeneity, and omitting or linearly adjusting for total brain volume (TBV). To properly adjust for TBV, brain allometry-the nonlinear scaling relationship between regional volumes and TBVwas considered when examining subcortical volumetric differences between typically developing (TD) and ASD individuals. Autism Brain Imaging Data Exchange I (ABIDE I; N = 654) data was analyzed with two methodological approaches: univariate linear mixed effects models and multivariate multiple group confirmatory factor analyses. Analyses were conducted on the entire sample and in subsamples based on age, sex, and full scale intelligence quotient (FSIQ). A similar ABIDE I study was replicated and the impact of different TBV adjustments on neuroanatomical group differences was investigated. No robust subcortical allometric or volumetric group differences were observed in the entire sample across methods. Exploratory analyses suggested that allometric scaling and volume group differences may exist in certain subgroups defined by age, sex, and/or FSIQ. The type of TBV adjustment influenced some reported volumetric and scaling group differences. This study supports the absence of robust volumetric differences between ASD and TD individuals in the investigated volumes when adjusting for brain allometry, expands the literature by finding no group difference in allometric scaling, and further suggests that differing TBV adjustments contribute to the variability of reported neuroanatomical differences in ASD. K E Y W O R D S allometry, autism spectrum disorder, subcortical volumes, total brain volume 1 | INTRODUCTION Autism spectrum disorder (ASD) is a neurodevelopmental disorder characterized by early persistent deficits in social communication and interactions and restricted, repetitive patterns of behavior, interests, or activities. These symptoms impair social or occupational functioning and are not restricted to a developmental delay or intellectual deficiencies (American Psychiatric Association, 2013). Although prevalence estimates appear to vary by country and methods of assessments

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Section: Discussionmentioning

confidence: 99%

Adjusting for allometric scaling in ABIDE I challenges subcortical volume differences in autism spectrum disorder

Williams

Peyre

Toro

et al. 2020

Human Brain Mapping

View full text Add to dashboard Cite

show abstract

“…There are numerous efforts aimed at identifying cerebral markers of ASD with brain imaging techniques for diagnosis purposes (e.g. Alvarez-Jimenez et al, 2020; Kong et al, 2019; Nielsen et al, 2013). However, our study along with the increasing literature reporting the absence of (Haar et al, 2016; Lefebvre et al, 2015) or very subtle (van Rooij et al, 2017) volumetric group differences, suggest that previous group differences in subcortical volumes are potentially false positives or that individual regions may not constitute useful cerebral markers to employ for the diagnosis of ASD.…”

Section: Discussionmentioning

confidence: 99%

Adjusting for Allometric Scaling in ABIDE I Challenges Subcortical Volume Differences in Autism Spectrum Disorder

Williams

Peyre

Toro

et al. 2020

Preprint

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To properly adjust for total brain volume (TBV), brain allometry - the non-linear scaling relationship between regional volumes and TBV - was considered when examining subcortical volumetric differences between typically developing (TD) and Autistim Spectrum Disorder (ASD) individuals. Autism Brain Imaging Data Exchange I (N = 654) data was analyzed with two methodological approaches: univariate Linear Mixed Effects Models and multivariate Multiple Group Confirmatory Factor Analyses. Analyses were conducted on the entire sample and in subsamples based on age, sex, and Full Scale Intelligence Quotient (FSIQ). A similar ABIDE I study was replicated and the impact of different TBV adjustments on neuroanatomical group differences was investigated. No robust subcortical allometric or volumetric group differences were observed in the entire sample across methods. Exploratory analyses suggested that allometric scaling and volume group differences may exist in certain subgroups defined by age, sex, and/or FSIQ. The type of TBV adjustment influenced some reported volumetric and scaling group differences. This study supports the absence of robust volumetric differences between ASD and TD individuals in the investigated volumes when adjusting for brain allometry, expands the literature by finding no group difference in allometric scaling, and further suggests that differing TBV adjustments contribute to the variability of reported neuroanatomical differences in ASD.

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“…In ASD research, T1-weighted is often used to observe structural changes in the brain, such as gray matter volume, cortical thickness, and connectivity between brain regions ( Jianfeng et al, 2019 ; Conti et al, 2020 ). By comparing T1-weighted images of ASD patients with healthy controls, researchers can discover structural differences in certain brain regions of ASD patients, which may be related to cognitive, social, and emotional disorders in ASD ( Alvarez-Jimenez et al, 2020 ; Samian et al, 2021 ). Arterial spin labeling (ASL) is a non-invasive imaging technique used to study brain function and neural activity.…”

Section: Introductionmentioning

confidence: 99%

Diagnosis for autism spectrum disorder children using T1-based gray matter and arterial spin labeling-based cerebral blood flow network metrics

Liu,

Yu,

et al. 2024

Front. Neurosci.

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IntroductionAutism Spectrum Disorder (ASD) is a complex neurodevelopmental condition characterized by impairments in motor skills, communication, emotional expression, and social interaction. Accurate diagnosis of ASD remains challenging due to the reliance on subjective behavioral observations and assessment scales, lacking objective diagnostic indicators.MethodsIn this study, we introduced a novel approach for diagnosing ASD, leveraging T1-based gray matter and ASL-based cerebral blood flow network metrics. Thirty preschool-aged patients with ASD and twenty-two typically developing (TD) individuals were enrolled. Brain network features, including gray matter and cerebral blood flow metrics, were extracted from both T1-weighted magnetic resonance imaging (MRI) and ASL images. Feature selection was performed using statistical t-tests and Minimum Redundancy Maximum Relevance (mRMR). A machine learning model based on random vector functional link network was constructed for diagnosis.ResultsThe proposed approach demonstrated a classification accuracy of 84.91% in distinguishing ASD from TD. Key discriminating network features were identified in the inferior frontal gyrus and superior occipital gyrus, regions critical for social and executive functions in ASD patients.DiscussionOur study presents an objective and effective approach to the clinical diagnosis of ASD, overcoming the limitations of subjective behavioral observations. The identified brain network features provide insights into the neurobiological mechanisms underlying ASD, potentially leading to more targeted interventions.

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Autism spectrum disorder characterization in children by capturing local‐regional brain changes in MRI

Cited by 20 publications

References 49 publications

Adjusting for allometric scaling in ABIDE I challenges subcortical volume differences in autism spectrum disorder

Adjusting for allometric scaling in ABIDE I challenges subcortical volume differences in autism spectrum disorder

Adjusting for Allometric Scaling in ABIDE I Challenges Subcortical Volume Differences in Autism Spectrum Disorder

Diagnosis for autism spectrum disorder children using T1-based gray matter and arterial spin labeling-based cerebral blood flow network metrics

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