The goal of this proposed research is to develop a system for determination of imaging geometries for optimal views via computer display of a calculated three-dimensional (3D) coronary vascular tree and for retrospective determination of imaging geometries used in previous studies so that new acquisitions can be made with those geometries while the patient is still on the table. Specifically, we will develop methods (l) to estimate the imaging geometry from biplane angiograms, (2) to determine bifurcation points in biplane angiographic sequences, (3) to determine corresponding points in biplane image sequences, (4) to facilitate determination of optimal views, and (5) to determine retrospectively imaging geometries used in previous studies. Previously, methods have been proposed for determination of the 3D vasculature from biplane images; however, they involve the use of calibration objects or complex measurement protocols, and they are not easily automated. Because the 3D vasculature is not available, multiple acquisitions must be obtained, measurements in coronary images remain subjective and inaccurate, and the imaging geometry of current studies cannot be aligned with that of previous geometries, which reduces the accuracy and precision of comparisons performed in longitudinal studies. In the proposed research, the 3D coronary vasculature will be reconstructed automatically from biplane acquisitions without calibration objects for immediate evaluation. The accuracies in magnification and imaging geometry will be better than 3% and 2 degrees, respectively. With the 3D vasculature, optimal views can be identified without additional radiation dose or contrast load to the patient, and quantitative measurements become more reliable. In addition, we will develop methods for retrospective alignment of current imaging geometries with those of previous studies so that acquisitions with equivalent projections can be obtained to facilitate quantitative measurements of interval change. The significance of the proposed research is that the 3D vasculature will be determined accurately, automatically, and quickly. computerized visualization will allow identification of optimal view, thereby, reducing patient radiation exposure, contrast load, and risk. Immediate retrospective alignment will facilitate longitudinal studies of progression or regression of coronary disease. These techniques can be implemented on current digital biplane systems.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL052567-02
Application #
2332526
Study Section
Special Emphasis Panel (ZRG7-DMG (01))
Project Start
1996-02-01
Project End
2000-01-31
Budget Start
1997-02-01
Budget End
1998-01-31
Support Year
2
Fiscal Year
1997
Total Cost
Indirect Cost
Name
University of Chicago
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
225410919
City
Chicago
State
IL
Country
United States
Zip Code
60637
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Dmochowski, Jacek; Hoffmann, Kenneth R; Singh, Vikas et al. (2005) Effects of point configuration on the accuracy in 3D reconstruction from biplane images. Med Phys 32:2862-9
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