Gray matter covariations and core symptoms of autism. The EU-AIMS Longitudinal European Autism Project

Mei, Ting; Llera, Alberto; Floris, Dorothea L.; Forde, Natalie J.; Tillmann, Julian; Durston, Sarah; Moessnang, Carolin; Banaschewski, Tobias; Holt, Rosemary; Baron‐Cohen, Simon; Rausch, Annika; Loth, Eva; Dell’Acqua, Flavio; Charman, Tony; Murphy, Declan; Ecker, Christine; Beckmann, Christian F.; Buitelaar, Jan K.

doi:10.1101/2020.06.26.171827

Cited by 1 publication

(1 citation statement)

References 56 publications

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“…6 To date, SBM has been predominantly used in single-scanner studies to investigate neuroanatomical differences between populations and neuroanatomical correlates of demographic or clinical characteristics. [7][8][9][10] More recently, SBM has also been employed in collaborative studies, [11][12][13][14] since pooling of multi-scanner magnetic resonance imaging (MRI) data from multiple sites has gained research momentum in the past decade. 15,16 Theoretically, SBM assumes common SBPs and varying loading parameters across all subjects of the investigated cohort.…”

Section: Introductionmentioning

confidence: 99%

SS-Detect: Development and Validation of a New Strategy for Source-Based Morphometry in Multi-Scanner Studies

Shi-qing

Keeling

et al. 2020

Preprint

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Background and PurposeSource-based morphometry (SBM) is a data-driven multivariate approach for interrogating covariation in structural brain patterns (SBPs) across subjects and quantifying the subject-specific loading parameters of these patterns. This approach has been used in multi-centre studies pooling magnetic resonance imaging (MRI) data across different scanners to advance the reproducibility of neuroscience research. In the present study, we developed an analysis strategy for Scanner-Specific Detection (SS-Detect) of SBPs in multiscanner studies, and evaluated its performance relative to a conventional strategy.MethodsWe conducted two simulation experiments. In the first experiment, the SimTB toolbox was used to generate simulation datasets mimicking twenty different scanners with common and scanner-specific SBPs. In the second experiment, we generated one simulated SBP from empirical datasets from two different scanners.ResultsThe outputs of the conventional strategy were limited to whole-sample-level results across all scanners; the outputs of SS-Detect included whole-sample-level and scanner-specific results. In the first simulation experiment, SS-Detect successfully estimated all simulated SBPs, including the common and scanner-specific SBPs whereas the conventional strategy detected only some of the whole-sample SBPs. The second simulation experiment showed that both strategies could detect the simulated SBP. Quantitative evaluations of both experiments demonstrated greater accuracy of the SS-Detect in estimating spatial SBPs and subject-specific loading parameters.ConclusionsSS-Detect outperformed the conventional strategy in terms of accurately estimating spatial SBPs and loading parameters both at whole-sample and scanner-specific levels and can be considered advantageous when SBM is applied to a multi-scanner study.

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