Parcellation of the Healthy Neonatal Brain into 107 Regions Using Atlas Propagation through Intermediate Time Points in Childhood

Blesa, Manuel; Serag, Ahmed; Wilkinson, A G; Anblagan, Devasuda; Telford, Emma J.; Pataky, Rozalia; Sparrow, Sarah; Macnaught, Gillian; Semple, Scott; Bastin, Mark E.; Boardman, James P.

doi:10.3389/fnins.2016.00220

Cited by 37 publications

(43 citation statements)

References 72 publications

(106 reference statements)

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“…Our algorithm, in particular, showed robust performance due to 1) the use of a robust state estimation technique (Agamennoni et al, 2012) for inter-slice motion correction through dynamic motion tracking, and 2) detection and rejection of intra-slice motion and robust reconstruction through weighted linear least squares estimation. The processing pipeline developed in this study for fetal brain DWI analysis, technical advances in fetal brain MRI reconstruction, new advances in fetal brain functional MRI analysis (Seshamani et al, 2016), along with spatiotemporal atlases of the fetal brain (Gholipour et al, 2014a, 2017; Serag et al, 2012) and neonates (Blesa et al, 2016; Makropoulos et al, 2016) can significantly improve the use of in-vivo MRI and DWI to study the development of human brain connectome in-utero . This in-turn facilitates the use of MRI as a powerful imaging modality for the analysis of neurodevelopmental disorders caused by preterm birth, growth restriction, or congenital anomalies.…”

Section: Discussionmentioning

confidence: 99%

“…Atlas-based parcellation was performed based on 90 anatomical regions mapped to the spatiotemporal fetal brain MRI atlas (Gholipour et al, 2017) from the neonatal brain MRI atlas developed by Blesa et al (2016). We studied structural connectivity based on streamlines connecting all pairs of anatomical regions.…”

Section: Methodsmentioning

confidence: 99%

“…The corrected masked image is registered to the atlas space using the algorithm discussed by Gholipour et al (2012), and tissue segmentation and anatomical parcellation is obtained from multi-atlas segmentation using label propagation through ANTS deformable registration (Avants et al, 2008) and probabilistic label fusion (Akhondi-Asl and Warfield, 2013). A spatiotemporal fetal brain MRI atlas (Gholipour et al, 2014b, 2017) is used in this process with anatomical parcellations adopted from the neonatal brain atlases by Blesa et al (2016). The DWI stacks of slices are processed with the algorithm developed and discussed in section 2.1.…”

Section: Figurementioning

confidence: 99%

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Temporal slice registration and robust diffusion-tensor reconstruction for improved fetal brain structural connectivity analysis

et al. 2017

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Diffusion weighted magnetic resonance imaging, or DWI, is one of the most promising tools for the analysis of neural microstructure and the structural connectome of the human brain. The application of DWI to map early development of the human connectome in-utero, however, is challenged by intermittent fetal and maternal motion that disrupts the spatial correspondence of data acquired in the relatively long DWI acquisitions. Fetuses move continuously during DWI scans. Reliable and accurate analysis of the fetal brain structural connectome requires careful compensation of motion effects and robust reconstruction to avoid introducing bias based on the degree of fetal motion. In this paper we introduce a novel robust algorithm to reconstruct in-vivo diffusion-tensor MRI (DTI) of the moving fetal brain and show its effect on structural connectivity analysis. The proposed algorithm involves multiple steps of image registration incorporating a dynamic registration-based motion tracking algorithm to restore the spatial correspondence of DWI data at the slice level and reconstruct DTI of the fetal brain in the standard (atlas) coordinate space. A weighted linear least squares approach is adapted to remove the effect of intra-slice motion and reconstruct DTI from motion-corrected data. The proposed algorithm was tested on data obtained from 21 healthy fetuses scanned in-utero at 22–38 weeks gestation. Significantly higher fractional anisotropy values in fiber-rich regions, and the analysis of whole-brain tractography and group structural connectivity, showed the efficacy of the proposed method compared to the analyses based on original data and previously proposed methods. The results of this study show that slice-level motion correction and robust reconstruction is necessary for reliable in-vivo structural connectivity analysis of the fetal brain. Connectivity analysis based on graph theoretic measures show high degree of modularity and clustering, and short average characteristic path lengths indicative of small-worldness property of the fetal brain network. These findings comply with previous findings in newborns and a recent study on fetuses. The proposed algorithm can provide valuable information from DWI of the fetal brain not available in the assessment of the original 2D slices and may be used to more reliably study the developing fetal brain connectome.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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Temporal slice registration and robust diffusion-tensor reconstruction for improved fetal brain structural connectivity analysis

et al. 2017

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“…congenital heart disease or preterm neonates), using bespoke processing pipelines or pipelines developed using adult data but optimised for neonates (Boardman et al, 2006; Miller et al, 2007; Ball et al, 2010; Serag et al, 2016). There are some fetal and neonatal structural MRI atlases (for example: Gousias et al, 2012; Shi et al, 2011; Blesa et al, 2016; Makropoulos et al, 2016; Kabdebon et al, 2014; Oishi et al, 2011), but to our knowledge there are no perinatal image banks hosting normal data acquired from multiple studies and sites. A perinatal subsection of the BRAINS database is under development (www.brainsimagebank.ac.uk), and the developing Human Connectome Project (http://wp.doc.ic.ac.uk/dhcp/) aims to make data available from 1500 fetuses and newborns between 20–44 weeks’ post-menstrual age.…”

Section: Data Collectionmentioning

confidence: 99%

Improving data availability for brain image biobanking in healthy subjects: Practice-based suggestions from an international multidisciplinary working group

et al. 2017

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Brain imaging is now ubiquitous in clinical practice and research. The case for bringing together large amounts of image data from well-characterised healthy subjects and those with a range of common brain diseases across the life course is now compelling. This report follows a meeting of international experts from multiple disciplines, all interested in brain image biobanking. The meeting included neuroimaging experts (clinical and non-clinical), computer scientists, epidemiologists, clinicians, ethicists, and lawyers involved in creating brain image banks. The meeting followed a structured format to discuss current and emerging brain image banks; applications such as atlases; conceptual and statistical problems (e.g. defining ‘normality’); legal, ethical and technological issues (e.g. consents, potential for data linkage, data security, harmonisation, data storage and enabling of research data sharing). We summarise the lessons learned from the experiences of a wide range of individual image banks, and provide practical recommendations to enhance creation, use and reuse of neuroimaging data. Our aim is to maximise the benefit of the image data, provided voluntarily by research participants and funded by many organisations, for human health. Our ultimate vision is of a federated network of brain image biobanks accessible for large studies of brain structure and function.

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“…Following preprocessing, we defined 90 cortical and subcortical regions according to the Automated Anatomical Labeling (Tzourio-Mazoyer et al, 2002) algorithm of the Edinburgh Neonatal Atlas ENA33 segmentation tool (Cabez et al, 2016). According to Cabez et al, the ENA33 tool was transformed from an adult atlas, so it is consistent with adult label protocols, and the size of each brain region in the atlas corresponds to its actual size in the neonatal brain.…”

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confidence: 99%

Hub distribution of the brain functional networks of newborns prenatally exposed to maternal depression and SSRI antidepressants

Rotem-Kohavi

Williams²,

Müller

et al. 2019

Depress Anxiety

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Background: Prenatal maternal depression (PMD) and selective serotonin reuptake inhibitor (SSRI) antidepressants are associated with increased developmental risk in infants. Reports suggest that PMD is associated with hyperconnectivity of the insula and the amygdala, while SSRI exposure is associated with hyperconnectivity of the auditory network in the infant brain. However, associations between functional brain organization and PMD and/or SSRI exposure are not well understood. Methods:We examined the relation between PMD or SSRI exposure and neonatal brain functional organization. Infants of control (n = 17), depressed SSRI-treated (n = 20) and depressed-only (HAM-D ≥ 8) (n = 16) women, underwent resting-state functional magnetic resonance imaging at postnatal Day 6. At 6 months, temperament was assessed using Infant Behavioral Questionnaire (IBQ). We applied GTA and partial least square regression (PLSR) to the resting-state time series to assess group differences in modularity, and connector and provincial hubs.Results: Modularity was similar across all groups. The depressed-only group showed higher connector hub values in the left anterior cingulate, insula, and caudate as well as higher provincial hub values in the amygdala compared to the control group. The SSRI group showed higher provincial hub values in Heschl's gyrus relative to the depressed-only group. PLSR showed that newborns' hub values predicted 10% of the variability in infant temperament at 6 months, suggesting different developmental patterns between groups.Conclusions: Prenatal exposures to maternal depression and SSRIs have differential impacts on neonatal functional brain organization. Hub values at 6 days predict variance in temperament between infant groups at 6 months of age. K E Y W O R D Sdepression, fMRI, infant, prenatal exposure, SSRIs

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Parcellation of the Healthy Neonatal Brain into 107 Regions Using Atlas Propagation through Intermediate Time Points in Childhood

Cited by 37 publications

References 72 publications

Temporal slice registration and robust diffusion-tensor reconstruction for improved fetal brain structural connectivity analysis

Temporal slice registration and robust diffusion-tensor reconstruction for improved fetal brain structural connectivity analysis

Improving data availability for brain image biobanking in healthy subjects: Practice-based suggestions from an international multidisciplinary working group

Hub distribution of the brain functional networks of newborns prenatally exposed to maternal depression and SSRI antidepressants

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