Multidimensional analysis and detection of informative features in human brain white matter

Richie-Halford, Adam; Yeatman, Jason D.; Simon, Noah; Rokem, Ariel

doi:10.1371/journal.pcbi.1009136

Cited by 22 publications

(24 citation statements)

References 90 publications

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“…In a recent study, age has been accurately predicted by FA and ADC metrics. 105 These results justify as well that if taking into account the microstructural measures, age is of critical importance in distinguishing between the two motor groups.…”

Section: Discussionmentioning

confidence: 66%

Machine learning-based prediction of motor status in glioma patients using diffusion MRI metrics along the corticospinal tract

Shams

Wang

Roine

et al. 2022

Brain Communications

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Along tract statistics enables white matter characterization using various diffusion MRI (dMRI) metrics. These diffusion models reveal detailed insights into white matter microstructural changes with development, pathology, and function. Here, we aim at assessing the clinical utility of dMRI metrics along the corticospinal tract, investigating whether motor glioma patients can be classified with respect to their motor status. We retrospectively included 116 brain tumor patients suffering from either left or right supratentorial, unilateral World Health Organization (WHO) grade II, III & IV gliomas with a mean age of 53.51 ± 16.32 years. 37% of patients presented with preoperative motor function deficits according to the Medical Research Council scale. At group level comparison, the highest non-overlapping dMRI differences were detected in the superior portion of the tracts’ profiles. Fractional anisotropy and fiber density decrease, apparent diffusion coefficient axial diffusivity and radial diffusivity increase. To predict motor deficits, we developed a method based on a support vector machine using histogram-based features of dMRI tract profiles (e.g., mean, standard deviation, kurtosis, and skewness), following a recursive feature elimination method. Our model achieved high performance (74% sensitivity, 75% specificity, 74% overall accuracy, and 77% area under the curve. We found that apparent diffusion coefficient, fractional anisotropy, and radial diffusivity contributed more than other features to the model. Incorporating the patient demographics and clinical features such as age, tumor WHO grade, tumor location, gender, and resting motor threshold did not affect the model’s performance, revealing that these features were not as effective as microstructural measures. These results shed light on the potential patterns of tumor-related microstructural white matter changes in the prediction of functional deficits.

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Section: Discussionmentioning

confidence: 66%

Machine learning-based prediction of motor status in glioma patients using diffusion MRI metrics along the corticospinal tract

Shams

Wang

Roine

et al. 2022

Brain Communications

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“…Failure to do so may cause spurious associations or degrade predictive performance. To demonstrate this, we selected participant age as a representative phenotypic benchmark because (i) it operates on a natural scale with meaningful units and (ii) despite the unique methodological challenges it presents for biomarker identi cation ( Nelson et al, 2020 ), brain age prediction may be diagnostic of overall brain health ( Franke et al, 2010 ; Cole et al, 2019 ; Richie-Halford et al, 2021 ). We observed the effect of varying QC cutoff on the predictive performance of an age prediction model.…”

Section: Resultsmentioning

confidence: 99%

“…We retain only the mean diffusivity (MD) and the fractional anisotropy (FA) from a diffusion kurtosis imaging (DKI) model ( Jensen et al, 2005 ), implemented in DIPY ( Henriques et al, 2021 ), and impute missing bundles using median imputation as implemented by scikit-learn ’s . Because the HBN-POD2 bundle profiles exhibit strong site effects ( Richie-Halford et al, 2021 ), we used the ComBat harmonization method to robustly adjust for site effects in the tract profiles. Initially designed to correct for site effects in gene expression studies ( Johnson et al, 2007 ), ComBat employs a parametric empirical Bayes approach to adjust for batch effects and has since been applied to multi-site cortical thickness measurements ( Fortin et al, 2018 ), multi-site DTI studies ( Fortin et al, 2017 ), and functional MRI data in the Adolescent Brain Cognitive Development Study (ABCD) ( Nielson et al, 2018 ).…”

Section: Methodsmentioning

confidence: 99%

“…We further demonstrated the impact of QC in a benchmark age prediction task (Figure 9). In this case, the increase in model performance from imposing a QC cutoff is intuitive: we know from Figure 8 that participants with low QC scores have reduced MD, but MD also decreases as participants mature (Yeatman et al, 2014;Richie-Halford et al, 2021). Eliminating participants with low QC therefore removes the ones who may look artificially older from the analysis, improving overall performance.…”

Section: Preprocessing and Quality Control Increase The Impact Of Ope...mentioning

confidence: 99%

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An open, analysis-ready, and quality controlled resource for pediatric brain white-matter research

Richie-Halford

Cieslak

et al. 2022

Preprint

Self Cite

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We created resources to facilitate research on the role of human brain microstructure in the development of mental health disorders, based on openly-available diffusion MRI (dMRI) data from the Healthy Brain Network (HBN) study. First, we curated the HBN dMRI data (N=2747) into the Brain Imaging Data Structure and preprocessed it according to best-practices, including denoising and correcting for motion effects, susceptibility-related distortions, and eddy currents. Preprocessed, analysis-ready data was made openly available. Data quality plays a key role in the analysis of dMRI, and we provide automated quality control (QC) scores for every scan, as part of the data release. To scale QC to this large dataset, we trained a neural network through the combination of a small data subset scored by experts and a larger set scored by community scientists. The network performs QC highly concordant with that of experts on a held out set (ROC-AUC=0.947). A further analysis of the neural network demonstrates that it relies on image features with relevance to QC. Altogether, this work both delivers a resource for transdiagnostic research in brain connectivity and pediatric mental health and serves as a novel tool for automated QC of large datasets.

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“…The HBN dataset was selected because the age range was appropriate for the desired age-based analysis, and because many of the MRI scans were known to be corrupted with artifacts based on our prior experience with this dataset ( Luna et al, 2021 ). Prior research has demonstrated a linear relationship between participant age and FA ( Rathee et al, 2016 ; Richie-Halford et al, 2021 ). Exploiting this fact, a proof-of-concept analysis examined the bivariate correlation between mean whole-brain FA and participant age.…”

Section: Methodsmentioning

confidence: 97%

Automated Multiclass Artifact Detection in Diffusion MRI Volumes via 3D Residual Squeeze-and-Excitation Convolutional Neural Networks

Ettehadi

Kashyap

Zhang

et al. 2022

Front. Hum. Neurosci.

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Diffusion MRI (dMRI) is widely used to investigate neuronal and structural development of brain. dMRI data is often contaminated with various types of artifacts. Hence, artifact type identification in dMRI volumes is an essential pre-processing step prior to carrying out any further analysis. Manual artifact identification amongst a large pool of dMRI data is a highly labor-intensive task. Previous attempts at automating this process are often limited to a binary classification (“poor” vs. “good” quality) of the dMRI volumes or focus on detecting a single type of artifact (e.g., motion, Eddy currents, etc.). In this work, we propose a deep learning-based automated multiclass artifact classifier for dMRI volumes. Our proposed framework operates in 2 steps. In the first step, the model predicts labels associated with 3D mutually exclusive collectively exhaustive (MECE) sub-volumes or “slabs” extracted from whole dMRI volumes. In the second step, through a voting process, the model outputs the artifact class present in the whole volume under investigation. We used two different datasets for training and evaluating our model. Specifically, we utilized 2,494 poor-quality dMRI volumes from the Adolescent Brain Cognitive Development (ABCD) and 4,226 from the Healthy Brain Network (HBN) dataset. Our results demonstrate accurate multiclass volume-level main artifact type prediction with 96.61 and 97.52% average accuracies on the ABCD and HBN test sets, respectively. Finally, in order to demonstrate the effectiveness of the proposed framework in dMRI pre-processing pipelines, we conducted a proof-of-concept dMRI analysis exploring the relationship between whole-brain fractional anisotropy (FA) and participant age, to test whether the use of our model improves the brain-age association.

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Multidimensional analysis and detection of informative features in human brain white matter

Cited by 22 publications

References 90 publications

Machine learning-based prediction of motor status in glioma patients using diffusion MRI metrics along the corticospinal tract

Machine learning-based prediction of motor status in glioma patients using diffusion MRI metrics along the corticospinal tract

An open, analysis-ready, and quality controlled resource for pediatric brain white-matter research

Automated Multiclass Artifact Detection in Diffusion MRI Volumes via 3D Residual Squeeze-and-Excitation Convolutional Neural Networks

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