scholarly journals Harmonization of Multi-Center Diffusion Tensor Tractography in Neonates with Congenital Heart Disease: Optimizing Post-Processing and Application of ComBat

Author(s):  
Benjamin D Meyers ◽  
Vincent K Lee ◽  
Lauren G Dennis ◽  
Julia Wallace ◽  
Vince Schmithorst ◽  
...  

Advanced brain imaging of neonatal macrostructure and microstructure, which has prognosticating importance, is more frequently being incorporated into multi-center trials of neonatal neuroprotection. Multicenter neuroimaging studies, designed to overcome small sample sized clinical cohorts, are essential but lead to increased technical variability. Few harmonization techniques have been developed for neonatal brain microstructural (diffusion tensor) analysis. The work presented here aims to remedy two common problems that exist with the current state of the art approaches: 1) variance in scanner and protocol in data collection can limit the researcher's ability to harmonize data acquired under different conditions or using different clinical populations. 2) The general lack of objective guidelines for dealing with anatomically abnormal anatomy and pathology. Often, subjects are excluded due to subjective criteria, or due to pathology that could be informative to the final analysis, leading to the loss of reproducibility and statistical power. This proves to be a barrier in the analysis of large multi-center studies and is a particularly salient problem given the relative scarcity of neonatal imaging data. We provide an objective, data-driven, and semi-automated neonatal processing pipeline designed to harmonize compartmentalized variant data acquired under different parameters. This is done by first implementing a search space reduction step of extracting the along-tract diffusivity values along each tract of interest, rather than performing whole-brain harmonization. This is followed by a data-driven outlier detection step, with the purpose of removing unwanted noise and outliers from the final harmonization. We then use an empirical Bayes harmonization algorithm performed at the along-tract level, with the output being a lower dimensional space but still spatially informative. After applying our pipeline to this large multi-site dataset of neonates and infants with congenital heart disease (n= 398 subjects recruited across 4 centers, with a total of n=763 MRI pre-operative/post-operative time points), we show that infants with single ventricle cardiac physiology demonstrate greater white matter microstructural alterations compared to infants with bi-ventricular heart disease, supporting what has previously been shown in literature. Our method is an open-source pipeline for delineating white matter tracts in subject space but provides the necessary modular components for performing atlas space analysis. As such, we validate and introduce Diffusion Imaging of Neonates by Group Organization (DINGO), a high-level, semi-automated framework that can facilitate harmonization of subject-space tractography generated from diffusion tensor imaging acquired across varying scanners, institutions, and clinical populations. Datasets acquired using varying protocols or cohorts are compartmentalized into subsets, where a cohort-specific template is generated, allowing for the propagation of the tractography mask set with higher spatial specificity. Taken together, this pipeline can reduce multi-scanner technical variability which can confound important biological variability in relation to neonatal brain microstructure.

2018 ◽  
Vol 17 (05) ◽  
pp. 161-167
Author(s):  
Juan Leon-Wyss ◽  
Cynthia Rosario ◽  
Janet Toribio ◽  
Herwin Speckter ◽  
Bernd Foerster ◽  
...  

AbstractThis article examines the relation between oxygen saturation and T2 star time in cyanotic congenital heart disease and its correlation to cerebral gray and white matter alterations. Magnetic resonance imaging was performed in 25 patients (mean age: 52.2 months) and 32 controls. Gray and white matter volumes, as well as fractional anisotropy and longitudinal diffusivity, were significantly reduced in patients. The reduction longitudinal diffusivity correlated to oxygen saturation and T2 star time of gray matter (p < 0.05). This diffusion tensor imaging (DTI) parameter was most affected in cyanotic congenital heart disease and because is the only parameter showing significant correlation to reduced oxygenation, it should be included more often in the follow-up of these patients over time.


2014 ◽  
Vol 51 (3) ◽  
pp. 377-383 ◽  
Author(s):  
Sarah B. Mulkey ◽  
Xiawei Ou ◽  
Raghu H. Ramakrishnaiah ◽  
Charles M. Glasier ◽  
Christopher J. Swearingen ◽  
...  

2018 ◽  
Vol 71 (18) ◽  
pp. 1986-1996 ◽  
Author(s):  
Shabnam Peyvandi ◽  
Vann Chau ◽  
Ting Guo ◽  
Duan Xu ◽  
Hannah C. Glass ◽  
...  

2018 ◽  
Vol 8 (1) ◽  
Author(s):  
Nina Gertsvolf ◽  
Jodie K. Votava-Smith ◽  
Rafael Ceschin ◽  
Sylvia del Castillo ◽  
Vince Lee ◽  
...  

2018 ◽  
Vol 71 (11) ◽  
pp. A586
Author(s):  
Jennifer Romanowicz ◽  
Ludmila Korotcova ◽  
Shruti D. Ramachandra ◽  
Paul D. Morton ◽  
Amrita Cheema ◽  
...  

Circulation ◽  
2015 ◽  
Vol 132 (suppl_3) ◽  
Author(s):  
Jennifer Romanowicz ◽  
Ludmila Korotcova ◽  
Paul Morton ◽  
Amrita Cheema ◽  
Vittorio Gallo ◽  
...  

Introduction: Reduced oxygen delivery in complex congenital heart disease (CHD) can lead to brain white matter (WM) injury in utero. Currently, no treatment exists. Tetrahydrobiopterin (BH4) is a cofactor for neuronal nitric oxide synthase, and in its absence, toxic peroxynitrite production is favored. Hypoxia activates nitric oxide synthase, which reduces BH4 availability. Hypothesis: Decreased BH4 levels underlie WM injury in the fetus with CHD, and treatment with BH4 will reduce this injury. Methods: Mice were divided into three groups: normoxic controls (Nx), hypoxic (Hx), and hypoxic with BH4 treatment (Hx-BH4). Hx and Hx-BH4 mice were kept at 10.5% FiO2 from postnatal day 3 to 11--a period of WM development equivalent to the 3rd trimester in humans. Brain BH4 levels were quantified and compared between Nx (n=11) and Hx (n=12). Densities of cells expressing CNP (marker of oligodendrocytes--cells responsible for myelination) and Caspase3 (apoptosis marker) were quantified in three WM regions and compared between groups (n=3-6 each). Western blot detected myelin basic protein (myelin marker). Results: Brain BH4 levels were depleted in Hx compared to Nx (-38.4%, p=0.02). CNP+ oligodendrocytes increased after Hx compared to Nx (Fig.1a), consistent with hypoxia-induced proliferation seen previously. BH4 treatment did not limit this proliferation (Fig.1a). Hx had increased WM apoptosis (Fig.1b), which decreased with BH4 treatment (Fig.1b). Remarkably, there was no difference in WM caspase3+ cells between Nx and Hx-BH4 (Fig.1b). There was no difference in effect across WM region. Finally, loss of myelin with hypoxia was mitigated by BH4 treatment (Fig.1c). Conclusions: Our results show that suboptimal BH4 levels influence hypoxic WM injury. BH4 treatment of phenylketonuria is safe during pregnancy, thus maternal BH4 therapy is feasible. Our data demonstrate that repurposing BH4 for use during fetal brain development has potential to limit WM injury in CHD.


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