Comparison of bootstrap approaches for estimation of uncertainties of DTI parameters

• Published in: NeuroImage (Orlando, Fla.) Vol. 33; no. 2; pp. 531 - 541
• Main Authors: Chung, SungWon, Lu, Ying, Henry, Roland G.
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.11.2006; Elsevier Limited
• Subjects: Acquisitions & mergers; Bias; Bootstrap; Brain - anatomy & histology; Brain Mapping - methods; Computer simulation; Diffusion tensor; Economic models; Estimating techniques; Fiber tracking; Humans; Hypotheses; Hypothesis testing; Image Processing, Computer-Assisted; Magnetic Resonance Imaging - methods; Methods; Monte Carlo simulation; MRI; Population; Probability distribution; Regression analysis; Reproducibility of Results; Standard deviation; Studies; Fiber tracking; Bootstrap; Diffusion tensor; MRI; Monte Carlo simulation
• ISSN: 1053-8119; 1095-9572
• DOI: 10.1016/j.neuroimage.2006.07.001

Bootstrap is an empirical non-parametric statistical technique based on data resampling that has been used to quantify uncertainties of diffusion tensor MRI (DTI) parameters, useful in tractography and in assessing DTI methods. The current bootstrap method (repetition bootstrap) used for DTI analysis performs resampling within the data sharing common diffusion gradients, requiring multiple acquisitions for each diffusion gradient. Recently, wild bootstrap was proposed that can be applied without multiple acquisitions. In this paper, two new approaches are introduced called residual bootstrap and repetition bootknife. We show that repetition bootknife corrects for the large bias present in the repetition bootstrap method and, therefore, better estimates the standard errors. Like wild bootstrap, residual bootstrap is applicable to single acquisition scheme, and both are based on regression residuals (called model-based resampling). Residual bootstrap is based on the assumption that non-constant variance of measured diffusion-attenuated signals can be modeled, which is actually the assumption behind the widely used weighted least squares solution of diffusion tensor. The performances of these bootstrap approaches were compared in terms of bias, variance, and overall error of bootstrap-estimated standard error by Monte Carlo simulation. We demonstrate that residual bootstrap has smaller biases and overall errors, which enables estimation of uncertainties with higher accuracy. Understanding the properties of these bootstrap procedures will help us to choose the optimal approach for estimating uncertainties that can benefit hypothesis testing based on DTI parameters, probabilistic fiber tracking, and optimizing DTI methods.