Qi Zhong scite author profile

Until now, dynamic functional connectivity (dFC) based on functional magnetic resonance imaging is typically estimated on a set of predefined regions of interest (ROIs) derived from an anatomical or static functional atlas which follows an implicit assumption of functional homogeneity within ROIs underlying temporal fluctuation of functional coupling, potentially leading to biases or underestimation of brain network dynamics. Here, we presented a novel computational method based on dynamic functional connectivity degree (dFCD) to derive meaningful brain parcellations that can capture functional homogeneous regions in temporal variance of functional connectivity. Several spatially distributed but functionally meaningful areas that are well consistent with known intrinsic connectivity networks were identified through independent component analysis (ICA) of time‐varying dFCD maps. Furthermore, a systematical comparison with commonly used brain atlases, including the Anatomical Automatic Labeling template, static ICA‐driven parcellation and random parcellation, demonstrated that the ROI‐definition strategy based on the proposed dFC‐driven parcellation could better capture the interindividual variability in dFC and predict observed individual cognitive performance (e.g., fluid intelligence, cognitive flexibility, and sustained attention) based on chronnectome. Together, our findings shed new light on the functional organization of resting brains at the timescale of seconds and emphasized the significance of a dFC‐driven and voxel‐wise functional homogeneous parcellation for network dynamics analyses in neuroscience.

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Design and Model Test of Structural Monitoring and Assessment System for Trimaran

Tang¹,

Ren²,

Zhong³

2019

brod

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Due to the unique structural design of multihull, the structural response on trimaran is often more complex than the response of monohull in navigation. In order to ensure the safety of trimaran navigation and predict the potential damage of local structure, the structure monitoring technology is applied. According to the structural characteristics of trimaran, structural monitoring and assessment system for multihull is designed and introduced in detail, and corresponding model test is taken to demonstrate its effectiveness. The selfpropelled trimaran model is installed with sensors in different longitudinal positions to monitor the variety of structural responses in irregular waves. And three real-time structural strength assessment methods in the system are used respectively to indicate the structural state about hull longitudinal strength, local yielding strength and fatigue strength. The influence of different wave azimuths and monitoring positions on structural strength assessment is analysed. Finally, these measured data and analyses results will provide technical support for design and installation of the monitoring system on actual trimaran.

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Constitutive Modeling and Finite Element Analysis of Myxomatous Mitral Leaflet Tissue

Zhong

Zeng

Huang

et al. 2014

J. Mech. Med. Biol.

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Although rarely discussed, material modeling of the myxomatous leaflet is considered as the cornerstone of mitral valve finite element analysis. The present study presents an incompressible, hyperelastic constitutive model to characterize myxoid mitral leaflet tissue mechanics. The model incorporates the transversely isotropic response and the layered structure of the tissue. First, an analytical constitutive model for the tissue is developed based on continuum mechanics and layered composites theory. Second, the material constants of the constitutive equation are determined by fitting the model to the experimental data. The analytical material model is then implemented using solid finite element methods by simulating a biaxial tensile test. A numerical simulation of the out-of-plane pressure loading is also conducted. Both the analytical outcomes and the simulated results agree well with experimental data and show good mutual agreement. The calculated strain distribution of the out-of-plane pressure loading simulation indicates myxoid leaflets exhibit enhanced extensibility and decreased stiffness compared to normal valves; the radial direction is more extensible than the circumferential direction. The presented material approximation is able to capture the myxomatous mitral leaflet mechanics. The results of the numerical simulation conform to those of the experimental tests.

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Qi Zhong

Functional parcellation of the hippocampus from resting-state dynamic functional connectivity

Impact of 36 h of total sleep deprivation on resting-state dynamic functional connectivity

Brain parcellation driven by dynamic functional connectivity better capture intrinsic network dynamics

Design and Model Test of Structural Monitoring and Assessment System for Trimaran

Constitutive Modeling and Finite Element Analysis of Myxomatous Mitral Leaflet Tissue

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About

Qi Zhong

Functional parcellation of the hippocampus from resting-state dynamic functional connectivity

Impact of 36 h of total sleep deprivation on resting-state dynamic functional connectivity

Brain parcellation driven by dynamic functional connectivity better capture intrinsic network dynamics

Design and Model Test of Structural Monitoring and Assessment System for Trimaran

Constitutive Modeling and Finite Element Analysis of Myxomatous Mitral Leaflet Tissue

Contact Info

Product

Resources

About

Impact of 36 h of total sleep deprivation on resting-state dynamic functional connectivity