Your search keyword '"Sun, Shu-wei"' showing total 3 results

1. Comparison of mouse brain DTI maps using K-space average, image-space average, or no average approach.

Author

Sun, Shu-Wei, Mei, Jennifer, and Tuel, Keelan

Subjects

*BRAIN mapping, *COMPARATIVE studies, *LABORATORY mice, *DIFFUSION tensor imaging, *K-spaces, *MAGNETIC resonance imaging of the brain

Abstract

Abstract: Diffusion tensor imaging (DTI) is achieved by collecting a series of diffusion-weighted images (DWIs). Signal averaging of multiple repetitions can be performed in the k-space (k-avg) or in the image space (m-avg) to improve the image quality. Alternatively, one can treat each acquisition as an independent image and use all of the data to reconstruct the DTI without doing any signal averaging (no-avg). To compare these three approaches, in this study, in vivo DTI data were collected from five normal mice. Noisy data with signal-to-noise ratios (SNR) that varied between five and 30 (before averaging) were then simulated. The DTI indices, including relative anisotropy (RA), trace of diffusion tensor (TR), axial diffusivity (λ║), and radial diffusivity (λ⊥), derived from the k-avg, m-avg, and no-avg, were then compared in the corpus callosum white matter, cortex gray matter, and the ventricles. We found that k-avg and m-avg enhanced the SNR of DWI with no significant differences. However, k-avg produced lower RA in the white matter and higher RA in the gray matter, compared to the m-avg and no-avg, regardless of SNR. The latter two produced similar DTI quantifications. We concluded that k-avg is less preferred for DTI brain imaging. [Copyright &y& Elsevier]

Published

2013

2. Keyhole and zero-padding approaches for reduced-encoding diffusion tensor imaging of the mouse brains

Author

Sun, Shu-Wei, Chen, Yu-Jen, Chou, Kun-Hsien, and Chu, Woei-Chyn

Subjects

*DIAGNOSTIC imaging, *LABORATORY mice, *CARDIAC imaging, *MAGNETIC resonance imaging, *MODALITY (Theory of knowledge), *K-spaces

Abstract

Abstract: Keyhole diffusion tensor imaging (keyhole DTI) was previously proposed in cardiac imaging to reconstruct DTI maps from the reduced phase-encoding images. To evaluate the feasibility of keyhole DTI in brain imaging, keyhole and zero-padding DTI algorithms were employed on in vivo mouse brain. The reduced phase-encoding portion, also termed as the sharing rate, was varied from 50% to 90% of the full k-space. Our data showed that zero-padding DTI resulted in decreased fractional anisotropy (FA) and decreased mean apparent diffusion coefficient (mean ADC) in white matter (WM) regions. Keyhole DTI showed a better edge preservation on mean ADC maps but not on FA maps as compared to the zero-padding DTI. When increasing the sharing rate in keyhole approach, an underestimation of FA and an over- or underestimation of mean ADC were measured in WM depending on the selected reference image. The inconsistency of keyhole DTI may add a challenge for the wide use of this modality. However, with a carefully selected directive diffusion-weighted image to serve as the reference image in the keyhole approach, this study demonstrated that one may obtain DTI indices of reduced-encoding images with high consistency to those derived with full k-space DTI. [ABSTRACT FROM AUTHOR]

Published

2010

3. Fixation, not death, reduces sensitivity of DTI in detecting optic nerve damage

Author

Sun, Shu-Wei, Liang, Hsiao-Fang, Xie, Mingqiang, Oyoyo, Udochukwu, and Lee, Amy

Subjects

*TISSUE fixation (Histology), *OPTIC nerve injuries, *DIFFUSION tensor imaging, *MYELINATION, *ISCHEMIA, *LABORATORY mice, *FORMALDEHYDE

Abstract

Abstract: The changes of directional diffusivities derived from diffusion tensor imaging (DTI), i.e. decreased axial diffusivity (λ ||) and increased radial diffusivity (λ ⊥), have shown significant correlation with axonal and myelin damage, respectively. However, after formalin fixation, reduced sensitivity of λ || in detecting axonal damage in tissue has raised the concern of applying DTI ex vivo. In order to distinguish whether death or the fixation process diminishes the sensitivity of DTI in detecting lesions, in vivo, pre-fixed postmortem, and fixed postmortem DTI were conducted on mouse optic nerves 3 and 14 days after transient retinal ischemia. Our data showed that, from in vivo to pre-fixed postmortem, λ || and λ ⊥ decreased by 50 to 70% in both healthy and injured optic nerves (3 and 14 day injury). From pre-fixed postmortem to fixed postmortem, λ || and λ ⊥ decreased by 40 to 50% in normal and 3-day injured optic nerves, but only by 15 to 25% in 14-day injured optic nerves. Consequently, for the 14-day injured optic nerves, the differences between healthy and injured nerves were not preserved after fixation: the 40% decreased λ|| and 200% increased λ⊥ in injured nerves as compared to the normal nerves were measured in vivo and pre-fixed postmortem, but after the fixation process, 300% increased λ⊥ and insignificant changes in λ|| were found in injured nerves as compared to the normal nerves. This study clarified that fixation process, but not death, could change the sensitivity of DTI in detecting injury. [Copyright &y& Elsevier]

Published

2009