Information

  • Publication Type: PhD-Thesis
  • Workgroup(s)/Project(s):
  • Date: November 2013
  • Date (Start): September 2010
  • Date (End): 2013
  • 1st Reviewer: Eduard GröllerORCID iD
  • 2nd Reviewer: Univ.Doz. Dipl.-Ing. Dr.techn. Miloš Šrámek
  • Rigorosum: 25. November 2013
  • First Supervisor: Eduard GröllerORCID iD

Abstract

Cardiovascular diseases occur with increasing frequency in our society. Their diagnosis often requires tailored visualization techniques, e.g., to examine the blood flow channel in case of luminal narrowing. Curved Planar Reformation (CPR) addresses this field by creating longitudinal sections along the centerline of blood vessels. With the possibility to rotate around an axis, the entire vessel can be assessed for possible vascular abnormalities (e.g., calcifications on the vessel wall, stenoses, and occlusions).

In this thesis, we present a visualization technique, called Centerline Reformation (CR), that offers the possibility to investigate the interior of any blood vessel, regardless of its spatial orientation. Starting from the projected vessel centerlines, the lumen of any vessel is generated by employing wavefront propagation in image space. The vessel lumen can be optionally delineated by halos, to enhance spatial relationships when examining a dense vasculature. We present our method in a focus+context setup, by rendering a different kind of visualization around the lumen. We explain how to resolve correct visibility of multiple overlapping vessels in image space. Additionally, our visualization method allows the examination of a complex vasculature by means of interactive vessel filtering and subsequent visual querying.

We propose an improved version of the Centerline Reformation (CR) technique, by generating a completely three-dimensional reformation of vascular structures using ray casting. We call this process Curved Surface Reformation (CSR). In this method, the cut surface is smoothly extended into the surrounding tissue of the blood vessels. Moreover, automatically generated cutaways reveal as much of the vessel lumen as possible, while still retaining correct visibility. This technique offers unrestricted navigation within the inspected vasculature and allows diagnosis of any tubular structure, regardless of its spatial orientation.

The growing amount of data requires increasing knowledge from a user in order to select the appropriate visualization method for their analysis. In this thesis, we present an approach that externalizes the knowledge of domain experts in a human readable form and employs an inference system to provide only suitable visualization techniques for clinical diagnosis, namely Smart Super Views. We discuss the visual representation of such automatically suggested visualizations by encoding the respective relevance into shape and size of their view. By providing a smart spatial arrangement and integration, the image becomes the menu itself. Such a system offers a guided medical diagnosis by domain experts.

After presenting the approach in a general setting, we describe an application scenario for diagnostic vascular visualization techniques. Since vascular structures usually consist of many vessels, we describe an anatomical layout for the investigation of the peripheral vasculature of the human lower extremities. By aggregating the volumetric information around the vessel centerlines in a circular fashion, we provide only a single static image for the assessment of the vessels. We call this method Curvicircular Feature Aggregation (CFA). In addition, we describe a stability analysis on the local deviations of the centerlines of vessels to determine potentially imprecise definitions. By conveying this information in the visualization, a fast visual analysis of the centerline stability is feasible.

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BibTeX

@phdthesis{mistelbauer_2013_SIV,
  title =      "Smart Interactive Vessel Visualization in Radiology ",
  author =     "Gabriel Mistelbauer",
  year =       "2013",
  abstract =   "Cardiovascular diseases occur with increasing frequency in
               our society. Their diagnosis often requires tailored
               visualization techniques, e.g., to examine the blood flow
               channel in case of luminal narrowing. Curved Planar
               Reformation (CPR) addresses this field by creating
               longitudinal sections along the centerline of blood vessels.
               With the possibility to rotate around an axis, the entire
               vessel can be assessed for possible vascular abnormalities
               (e.g., calcifications on the vessel wall, stenoses, and
               occlusions).   In this thesis, we present a visualization
               technique, called Centerline Reformation (CR), that offers
               the possibility to investigate the interior of any blood
               vessel, regardless of its spatial orientation. Starting from
               the projected vessel centerlines, the lumen of any vessel is
               generated by employing wavefront propagation in image space.
               The vessel lumen can be optionally delineated by halos, to
               enhance spatial relationships when examining a dense
               vasculature. We present our method in a focus+context setup,
               by rendering a different kind of visualization around the
               lumen. We explain how to resolve correct visibility of
               multiple overlapping vessels in image space. Additionally,
               our visualization method allows the examination of a complex
               vasculature by means of interactive vessel filtering and
               subsequent visual querying.   We propose an improved version
               of the Centerline Reformation (CR) technique, by generating
               a completely three-dimensional reformation of vascular
               structures using ray casting. We call this process Curved
               Surface Reformation (CSR). In this method, the cut surface
               is smoothly extended into the surrounding tissue of the
               blood vessels. Moreover, automatically generated cutaways
               reveal as much of the vessel lumen as possible, while still
               retaining correct visibility. This technique offers
               unrestricted navigation within the inspected vasculature and
               allows diagnosis of any tubular structure, regardless of its
               spatial orientation.   The growing amount of data requires
               increasing knowledge from a user in order to select the
               appropriate visualization method for their analysis. In this
               thesis, we present an approach that externalizes the
               knowledge of domain experts in a human readable form and
               employs an inference system to provide only suitable
               visualization techniques for clinical diagnosis, namely
               Smart Super Views. We discuss the visual representation of
               such automatically suggested visualizations by encoding the
               respective relevance into shape and size of their view. By
               providing a smart spatial arrangement and integration, the
               image becomes the menu itself. Such a system offers a guided
               medical diagnosis by domain experts.   After presenting the
               approach in a general setting, we describe an application
               scenario for diagnostic vascular visualization techniques.
               Since vascular structures usually consist of many vessels,
               we describe an anatomical layout for the investigation of
               the peripheral vasculature of the human lower extremities.
               By aggregating the volumetric information around the vessel
               centerlines in a circular fashion, we provide only a single
               static image for the assessment of the vessels. We call this
               method Curvicircular Feature Aggregation (CFA). In addition,
               we describe a stability analysis on the local deviations of
               the centerlines of vessels to determine potentially
               imprecise definitions. By conveying this information in the
               visualization, a fast visual analysis of the centerline
               stability is feasible. ",
  month =      nov,
  address =    "Favoritenstrasse 9-11/E193-02, A-1040 Vienna, Austria",
  school =     "Institute of Computer Graphics and Algorithms, Vienna
               University of Technology ",
  URL =        "https://www.cg.tuwien.ac.at/research/publications/2013/mistelbauer_2013_SIV/",
}