Your search keyword '"Zhengwang Wu"' showing total 5 results

1. Mapping Genetic Topography of Cortical Thickness and Surface Area in Neonatal Brains.

Author

Ying Huang, Zhengwang Wu, Tengfei Li, Xifeng Wang, Ya Wang, Lei Xing, Hongtu Zhu, Weili Lin, Li Wang, Lei Guo, Gilmore, John H., and Gang Li

Subjects

*GENE mapping, *SURFACE area, *CEREBRAL cortex, *TOPOGRAPHY, *GENETIC correlations, *MAGNETIC resonance, *NO-tillage

Abstract

Adult twin neuroimaging studies have revealed that cortical thickness (CT) and surface area (SA) are differentially influenced by genetic information, leading to their spatially distinct genetic patterning and topography. However, the postnatal origins of the genetic topography of CT and SA remain unclear, given the dramatic cortical development from neonates to adults. To fill this critical gap, this study unprecedentedly explored how genetic information differentially regulates the spatial topography of CT and SA in the neonatal brain by leveraging brain magnetic resonance (MR) images from 202 twin neonates with minimal influence by the complicated postnatal environmental factors. We capitalized on infant-dedicated computational tools and a data-driven spectral clustering method to parcellate the cerebral cortex into a set of distinct regions purely according to the genetic correlation of cortical vertices in terms of CT and SA, respectively, and accordingly created the first genetically informed cortical parcellation maps of neonatal brains. Both genetic parcellation maps exhibit bilaterally symmetric and hierarchical patterns, but distinct spatial layouts. For CT, regions with closer genetic relationships demonstrate an anterior- posterior (A-P) division, while for SA, regions with greater genetic proximity are typically within the same lobe. Certain genetically informed regions exhibit strong similarities between neonates and adults, with the most striking similarities in the medial surface in terms of SA, despite their overall substantial differences in genetic parcellation maps. These results greatly advance our understanding of the development of genetic influences on the spatial patterning of cortical morphology. [ABSTRACT FROM AUTHOR]

Published

2023

2. Mapping developmental regionalization and patterns of cortical surface area from 29 post-menstrual weeks to 2 years of age.

Author

Ying Huang, Zhengwang Wu, Fan Wang, Dan Hu, Tengfei Li, Lei Guo, Li Wang, Weili Lin, and Gang Li

Subjects

*SURFACE area, *CEREBRAL cortex development, *THIRD trimester of pregnancy, *CEREBRAL cortex, *SENSORIMOTOR cortex, *PREGNANT women

Abstract

Surface area of the human cerebral cortex expands extremely dynamically and regionally heterogeneously from the third trimester of pregnancy to 2 y of age, reflecting the spatial heterogeneity of the underlying microstructural and functional development of the cerebral cortex. However, little is known about the developmental patterns and regionalization of cortical surface area during this critical stage, due to the lack of high-quality imaging data and accurate computational tools for pediatric brain MRI data. To fill this critical knowledge gap, by leveraging 1,037 high-quality MRI scans with the age between 29 post-menstrual weeks and 24 mo from 735 pediatric subjects in two complementary datasets, i.e., the Baby Connectome Project (BCP) and the developing Human Connectome Project (dHCP), and state-of-the-art dedicated image-processing tools, we unprecedentedly parcellate the cerebral cortex into a set of distinct subdivisions purely according to the developmental patterns of the cortical surface. Our discovered developmentally distinct subdivisions correspond well to structurally and functionally meaningful regions and reveal spatially contiguous, hierarchical, and bilaterally symmetric patterns of early cortical surface expansion. We also show that highorder association subdivisions, where cortical folds emerge later during prenatal stages, undergo more dramatic cortical surface expansion during infancy, compared with the central regions, especially the sensorimotor and insula cortices, thus forming a distinct central-pole division in early cortical surface expansion. These results provide an important reference for exploring and understanding dynamic early brain development in health and disease. [ABSTRACT FROM AUTHOR]

Published

2022

3. Soluble B7-H2 as a Novel Marker in Early Evaluation of the Severity of Acute Pancreatitis.

Author

Jian Huang, Zhengwang Wu, Shiqi Lu, Jiaqing Shen, Xiaoming Kong, and Yueping Shen

Subjects

*PANCREATITIS diagnosis, *BIOMARKERS, *C-reactive protein, *CONFIDENCE intervals, *ENZYME-linked immunosorbent assay, *FLOW cytometry, *LACTATE dehydrogenase, *LONGITUDINAL method, *PROBABILITY theory, *RESEARCH funding, *T-test (Statistics), *RECEIVER operating characteristic curves, *DATA analysis software, *LIPOPOLYSACCHARIDES, *DESCRIPTIVE statistics, *LEUKOCYTE count, *ONE-way analysis of variance

Abstract

The clinical usefulness of soluble B7-H2 (sB7-H2) as an early indicator of acute pancreatitis (AP) remains unclear, so we performed the present study to investigate this issue. For our cohort, we recruited 75 patients with AP, 70 patients with other abdominal sepsis, and 20 healthy control individuals. The sB7-H2 levels of AP patients or healthy control individuals were measured by enzyme-linked immunosorbent assay (ELISA). The sB7-H2 levels in patients with AP rather than other patients with abdominal sepsis were significantly higher than those in healthy controls. Hence, we selected AP to study the clinical significance of sB7-H2 in inflammatory conditions. The sB7-H2 level was positively correlated with the white blood cell (WBC) count and the lactate dehydrogenase (LDH), high-sensitivity C-reactive protein (hs-CRP), and lipopolysaccharide LPS levels (P <.05 for each). Receiver operating characteristic (ROC) analysis revealed that sB7-H2 can distinguish moderately severe acute pancreatitis (MSAP) and severe acute pancreatitis (SAP) from mildly acute pancreatitis (MAP) with 77.8% sensitivity and 80.0% specificity; and that the levels of sB7-H2 also can distinguish SAP from MSAP and MAP with 92.0% sensitivity and 86.0% specificity. The present results indicate that sB7-H2 might be a useful marker in the clinical diagnosis of AP. [ABSTRACT FROM AUTHOR]

Published

2015

4. Developmental topography of cortical thickness during infancy.

Author

Fan Wang, Chunfeng Lian, Zhengwang Wu, Han Zhang, Tengfei Li, Yu Meng, Li Wang, Weili Lin, Dinggang Shen, and Gang Li

Subjects

*INFANTS, *NONNEGATIVE matrices, *MATRIX decomposition, *TOPOGRAPHY, *NEURAL development

Abstract

During the first 2 postnatal years, cortical thickness of the human brain develops dynamically and spatially heterogeneously and likely peaks between 1 and 2 y of age. The striking development renders this period critical for later cognitive outcomes and vulnerable to early neurodevelopmental disorders. However, due to the difficulties in longitudinal infant brain MRI acquisition and processing, our knowledge still remains limited on the dynamic changes, peak age, and spatial heterogeneities of cortical thickness during infancy. To fill this knowledge gap, in this study, we discover the developmental regionalization of cortical thickness, i.e., developmentally distinct regions, each of which is composed of a set of codeveloping cortical vertices, for better understanding of the spatiotemporal heterogeneities of cortical thickness development. We leverage an infant-dedicated computational pipeline, an advanced multivariate analysis method (i.e., nonnegative matrix factorization), and a densely sampled longitudinal dataset with 210 serial MRI scans from 43 healthy infants, with each infant being scheduled to have 7 longitudinal scans at around 1, 3, 6, 9, 12, 18, and 24 mo of age. Our results suggest that, during the first 2 y, the whole-brain average cortical thickness increases rapidly and reaches a plateau at about 14 mo of age and then decreases at a slow pace thereafter. More importantly, each discovered region is structurally and functionally meaningful and exhibits a distinctive developmental pattern, with several regions peaking at varied ages while others keep increasing in the first 2 postnatal years. Our findings provide valuable references and insights for early brain development. [ABSTRACT FROM AUTHOR]

Published

2019

5. Existence of Functional Connectome Fingerprint during Infancy and Its Stability over Months.

Author

Dan Hu, Fan Wang, Han Zhang, Zhengwang Wu, Zhen Zhou, Guoshi Li, Li Wang, Weili Lin, and Gang Li

Subjects

*INFANTS, *AGE groups, *FUNCTIONAL magnetic resonance imaging, *NEURAL development, *COGNITIVE ability

Abstract

The functional connectome fingerprint is a cluster of individualized brain functional connectivity patterns that are capable of distinguishing one individual from others. Although its existence has been demonstrated in adolescents and adults, whether such individualized patterns exist during infancy is barely investigated despite its importance in identifying the origin of the intrinsic connectome patterns that potentially mirror distinct behavioral phenotypes. To fill this knowledge gap, capitalizing on a longitudinal high-resolution structural and resting-state functional MRI dataset with 104 human infants (53 females) with 806 longitudinal scans (age, 16-876 d) and infant-specific functional parcellation maps, we observe that the brain functional connectome fingerprint may exist since infancy and keeps stable over months during early brain development. Specifically, we achieve an; 78% individual identification rate by using; 5% selected functional connections, compared with the best identification rate of 60% without connection selection. The frontoparietal networks recognized as the most contributive networks in adult functional connectome fingerprinting retain their superiority in infants despite being widely acknowledged as rapidly developing systems during childhood. The existence and stability of the functional connectome fingerprint are further validated on adjacent age groups. Moreover, we show that the infant frontoparietal networks can reach similar accuracy in predicting individual early learning composite scores as the whole-brain connectome, again resembling the observations in adults and highlighting the relevance of functional connectome fingerprint to cognitive performance. For the first time, these results suggest that each individual may retain a unique and stable marker of functional connectome during early brain development. [ABSTRACT FROM AUTHOR]

Published

2022