Shape recovery algorithms using level sets in 2-D/3-D medical imagery: a state-of-the-art review 论文

2002IEEE Transactions on Information Technology in Biomedicine引用 312
Medical Image Segmentation Techniques3D Shape Modeling and AnalysisDigital Image Processing Techniques

详细信息

发表期刊/会议
IEEE Transactions on Information Technology in Biomedicine
发表日期
2002-03-01
发表年份
2002

关键词

Medical Image Segmentation Techniques3D Shape Modeling and AnalysisDigital Image Processing Techniques

摘要

The class of geometric deformable models, also known as level sets, has brought tremendous impact to medical imagery due to its capability of topology preservation and fast shape recovery. In an effort to facilitate a clear and full understanding of these powerful state-of-the-art applied mathematical tools, this paper is an attempt to explore these geometric methods, their implementations and integration of regularizers to improve the robustness of these topologically independent propagating curves/surfaces. This paper first presents the origination of level sets, followed by the taxonomy of level sets. We then derive the fundamental equation of curve/surface evolution and zero-level curves/surfaces. The paper then focuses on the first core class of level sets, known as "level sets without regularizers." This class presents five prototypes: gradient, edge, area-minimization, curvature-dependent and application driven. The next section is devoted to second core class of level sets, known as "level sets with regularizers." In this class, we present four kinds: clustering-based, Bayesian bidirectional classifier-based, shape-based and coupled constrained-based. An entire section is dedicated to optimization and quantification techniques for shape recovery when used in the level set framework. Finally, the paper concludes with 22 general merits and four demerits on level sets and the future of level sets in medical image segmentation. We present applications of level sets to complex shapes like the human cortex acquired via MRI for neurological image analysis.