Your search keyword '"Tengda Zhao"' showing total 2 results

1. Test-retest reliability of white matter structural brain networks: A multiband diffusion MRI study

Author

Tengda Zhao, Yong He, Miao Cao, Zhengjia Dai, Fei Duan, Xuhong Liao, and Ni Shu

Subjects

multiband epi, Correlation coefficient, Computer science, graph theory, tractography, brain connectome, Metrics, computer.software_genre, lcsh:RC321-571, Behavioral Neuroscience, Original Research Article, reproducibility, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Biological Psychiatry, Reproducibility, Human Connectome Project, business.industry, Pattern recognition, Graph theory, Psychiatry and Mental health, Neuropsychology and Physiological Psychology, Diffusion Tensor Imaging, Neurology, Graph (abstract data type), Artificial intelligence, Data mining, business, computer, white matter, Diffusion MRI, Tractography, Neuroscience

Abstract

The multiband EPI sequence has been developed for the human connectome project to accelerate MRI data acquisition. However, no study has yet investigated the test-retest (TRT) reliability of the graph metrics of white matter (WM) structural brain networks constructed from this new sequence. Here, we employed a multiband diffusion MRI (dMRI) dataset with repeated scanning sessions and constructed both low- and high-resolution WM networks by volume- and surface-based parcellation methods. The reproducibility of network metrics and its dependence on type of construction procedures was assessed by the intra-class correlation coefficient (ICC). We observed conserved topological architecture of WM structural networks constructed from the multiband dMRI data as previous findings from conventional dMRI. For the global network properties, the first order metrics were more reliable than second order metrics. Between two parcellation methods, networks with volume-based parcellation showed better reliability than surface-based parcellation, especially for the global metrics. Between different resolutions, the high-resolution network exhibited higher TRT performance than the low-resolution in terms of the global metrics with a large effect size, whereas the low-resolution performs better in terms of local (region and connection) properties with a relatively low effect size. Moreover, we identified that the association and primary cortices showed higher reproducibility than the paralimbic/limbic regions. The important hub regions and rich-club connections are more reliable than the non-hub regions and connections. Finally, we found WM networks from the multiband dMRI showed higher reproducibility compared with those from the conventional dMRI. Together, our results demonstrated the fair to good reliability of the WM structural brain networks from the multiband EPI sequence, suggesting its potential utility for exploring individual differences and for clinical applications.

Published

2015

2. Spontaneous functional network dynamics and associated structural substrates in the human brain.

Author

Xuhong Liao, Lin Yuan, Tengda Zhao, Zhengjia Dai, Ni Shu, Mingrui Xia, Yihong Yang, Alan Evans, and Yong He

Subjects

MAGNETIC resonance imaging of the brain, FUNCTIONAL magnetic resonance imaging, GRAPH theory, ELECTROENCEPHALOGRAPHY, NEUROBEHAVIORAL disorders

Abstract

Recent imaging connectomics studies have demonstrated that the spontaneous human brain functional networks derived from resting-state functional MRI (R-fMRI) include many non-trivial topological properties, such as highly efficient small-world architecture and densely connected hub regions. However, very little is known about dynamic functional connectivity (D-FC) patterns of spontaneous human brain networks during rest and about how these spontaneous brain dynamics are constrained by the underlying structural connectivity. Here, we combined sub-second multiband R-fMRI data with graph-theoretical approaches to comprehensively investigate the dynamic characteristics of the topological organization of human whole-brain functional networks, and then employed diffusion imaging data in the same participants tofurther explore the associated structural substrates. At the connection level, we found that human whole-brain D-FC patterns spontaneously fluctuated over time, while homotopic D-FC exhibited high connectivity strength and low temporal variability. At the network level, dynamic functional networks exhibited time-varying but evident small-world and assortativity architecture, with several regions (e.g., insula, sensorimotor cortex and medial prefrontal cortex) emerging as functionally persistent hubs (i.e., highly connected regions) while possessing large temporal variability in their degree centrality. Finally, the temporal characteristics (i.e., strength and variability) of the connectional and nodal properties of the dynamic brain networks were significantly associated with their structural counterparts. Collectively, we demonstrate the economical, efficient, and flexible characteristics of dynamic functional coordination in large-scale human brain networks during rest, and highlight their relationship with underlying structural connectivity, which deepens our understandings of spontaneous brain network dynamics in humans. [ABSTRACT FROM AUTHOR]

Published

2015