Statistical analysis of diffusion tensors in diffusion-weighted magnetic resonance imaging data
成果类型:
Article
署名作者:
Zhu, Hongtu; Zhang, Heping; Ibrahim, Joseph G.; Peterson, Bradley S.
署名单位:
University of North Carolina; University of North Carolina Chapel Hill; Yale University; University of North Carolina; University of North Carolina Chapel Hill; Columbia University; New York State Psychiatry Institute
刊物名称:
JOURNAL OF THE AMERICAN STATISTICAL ASSOCIATION
ISSN/ISSBN:
0162-1459
DOI:
10.1198/016214507000000581
发表日期:
2007
页码:
1085-1102
关键词:
strong consistency
least-squares
noise
mri
uncertainty
mathematics
estimators
architecture
eigenvalues
strategies
摘要:
Diffusion tensor imaging has been widely used to reconstruct the structure and orientation of fibers in biological tissues, particularly in the white matter of the brain, because it can track the effective diffusion of water along those fibers. The raw diffusion-weighted images from which diffusion tensors are estimated, however, inherently contain noise. Noise in the images produces uncertainty in the estimation of the tensors (which are 3 x 3 positive-definite matrices) and of their derived quantities, including eigenvalues, eigenvectors, and the fiber pathways that are reconstructed based on those tensor elements. The aim of this article is to provide a comprehensive theoretical framework of statistical inference for quantifying the effects of noise on diffusion tensors, on their eigenvalues and eigenvectors, and on their morphological classification. We propose a semiparametric model to account for noise in diffusion-weighted images. We then develop a one-step, weighted least squares estimate of the tensors and justify use of the one-step estimates based on our theoretical framework and computational results. We also quantify the effects of noise on the eigenvalues and eigenvectors of the estimated tensors by establishing their limiting distributions. We construct pseudo-likelihood ratio statistics to classify tensor morphologies. Simulation studies show that our theoretical results can accurately predict the stochastic behavior of the estimated eigenvalues and eigenvectors, as well as the bias that is introduced by sorting the eigenvalues by their magnitudes. Implementation of these methods is illustrated in a diffusion-weighted dataset from seven healthy human subjects.