• DocumentCode
    837956
  • Title

    Four-Chamber Heart Modeling and Automatic Segmentation for 3-D Cardiac CT Volumes Using Marginal Space Learning and Steerable Features

  • Author

    Zheng, Yefeng ; Barbu, Adrian ; Georgescu, Bogdan ; Scheuering, Michael ; Comaniciu, Dorin

  • Author_Institution
    Dept. of Integrated Data Syst., Siemens Corp. Res., Princeton, NJ
  • Volume
    27
  • Issue
    11
  • fYear
    2008
  • Firstpage
    1668
  • Lastpage
    1681
  • Abstract
    We propose an automatic four-chamber heart segmentation system for the quantitative functional analysis of the heart from cardiac computed tomography (CT) volumes. Two topics are discussed: heart modeling and automatic model fitting to an unseen volume. Heart modeling is a nontrivial task since the heart is a complex nonrigid organ. The model must be anatomically accurate, allow manual editing, and provide sufficient information to guide automatic detection and segmentation. Unlike previous work, we explicitly represent important landmarks (such as the valves and the ventricular septum cusps) among the control points of the model. The control points can be detected reliably to guide the automatic model fitting process. Using this model, we develop an efficient and robust approach for automatic heart chamber segmentation in 3D CT volumes. We formulate the segmentation as a two-step learning problem: anatomical structure localization and boundary delineation. In both steps, we exploit the recent advances in learning discriminative models. A novel algorithm, marginal space learning (MSL), is introduced to solve the 9-D similarity transformation search problem for localizing the heart chambers. After determining the pose of the heart chambers, we estimate the 3D shape through learning-based boundary delineation. The proposed method has been extensively tested on the largest dataset (with 323 volumes from 137 patients) ever reported in the literature. To the best of our knowledge, our system is the fastest with a speed of 4.0 s per volume (on a dual-core 3.2-GHz processor) for the automatic segmentation of all four chambers.
  • Keywords
    cardiovascular system; computerised tomography; image segmentation; learning (artificial intelligence); medical image processing; 3-D cardiac CT Volume; 9-D similarity transformation search problem; anatomical structure localization; automatic heart chamber segmentation; automatic model fitting; cardiac computed tomography; complex nonrigid organ; four-chamber heart modeling; learning-based boundary delineation; marginal space learning; quantitative functional analysis; ventricular septum cusps; Anatomical structure; Automatic control; Computed tomography; Functional analysis; Heart; Robustness; Search problems; Shape; Testing; Valves; Heart modeling; heart segmentation; marginal space learning; three-dimensional (3-D) object detection; Anatomy, Cross-Sectional; Artificial Intelligence; Automatic Data Processing; Finite Element Analysis; Heart; Humans; Image Processing, Computer-Assisted; Information Storage and Retrieval; Models, Cardiovascular; Pattern Recognition, Automated; Research Design; Tomography, X-Ray Computed;
  • fLanguage
    English
  • Journal_Title
    Medical Imaging, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0278-0062
  • Type

    jour

  • DOI
    10.1109/TMI.2008.2004421
  • Filename
    4601463