Abstract
The finite mixture (FM) model is the most commonly used model for statistical segmentation of brain magnetic resonance (MR) images because of its simple mathematical form and the piecewise constant nature of ideal brain MR images. However, being a histogram-based model, the FM has an intrinsic limitation--no spatial information is taken into account. This causes the FM model to work only on well-defined images with low levels of noise; unfortunately, this is often not the the case due to artifacts such as partial volume effect and bias field distortion. Under these conditions, FM model-based methods produce unreliable results. In this paper, we propose a novel hidden Markov random field (HMRF) model, which is a stochastic process generated by a MRF whose state sequence cannot be observed directly but which can be indirectly estimated through observations. Mathematically, it can be shown that the FM model is a degenerate version of the HMRF model. The advantage of the HMRF model derives from the way in which the spatial information is encoded through the mutual influences of neighboring sites. Although MRF modeling has been employed in MR image segmentation by other researchers, most reported methods are limited to using MRF as a general prior in an FM model-based approach. To fit the HMRF model, an EM algorithm is used. We show that by incorporating both the HMRF model and the EM algorithm into a HMRF-EM framework, an accurate and robust segmentation can be achieved. More importantly, the HMRF-EM framework can easily be combined with other techniques. As an example, we show how the bias field correction algorithm of Guillemaud and Brady (1997) can be incorporated into this framework to achieve a three-dimensional fully automated approach for brain MR image segmentation.
Highlights
M agnetic resonance imagine (MRI) is an advanced medical imaging technique providing rich information about the human soft tissue anatomy
In order to address this problem, we have developed a hidden Markov random field (HMRF) model, which is a stochastic process generated by a MRF whose state sequence cannot be observed directly but which can be observed through a field of observations
We show that by incorporating both the HMRF model and the EM algorithm into a mathematically sound HMRF-EM framework, an accurate and robust segmentation approach can be achieved, which is demonstrated through experiments on both simulated images and real data, and comparison made with the finite mixture (FM)-EM framework
Summary
M agnetic resonance imagine (MRI) is an advanced medical imaging technique providing rich information about the human soft tissue anatomy. Being a histogram-based model, the FM has an intrinsic limitation—spatial information is not taken into account because all the data points are considered to be independent samples drawn from a population Such a limitation causes the FM model to work only on well-defined images with low levels of noise; this is often not the case with MR images due to artifacts such as the partial volume effect and bias field distortion. The importance of the HMRF model derives from MRF theory, in which the spatial information in an image is encoded through contextual constraints of neighboring pixels By imposing such constraints, we expect neighboring pixels to have the same class labels (in the case of piecewise constant images) or similar intensities (in the case of piecewise continuous images). Comparison with other methods and experimental results are shown, followed by discussions and future work in the final section
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