Abstract

Recent developments in Computed Tomography have resulted in the capability to image blood vessels in three dimensions and less invasively than conventional angiography. However, these developments have also resulted in the potential to generate thousands of images per patient study for radiological interpretation. As a result, it has become increasingly difficult to read each image separately and to reach an accurate diagnosis in a reasonable amount of time. Therefore, we propose to develop and validate technology that changes radiological interpretation of volumetric CT vascular image data from visual inspection of individual cross-sections to a paradigm that combines highly efficient, ergonomic, and interactive volumetric visualization and quantitative analysis. To this end, over the first three years of this project, we will develop a system of hardware and software specifically designed for this task. It will consist of a large-area high-resolution display, a set of human-computer interfaces specifically designed for facilitating interaction with large volumetric vascular data sets, and intelligent software capable of guiding the required interactions and generating blood-vessel-specific visualizations and quantitative results with minimal effort. We will conduct a clinical pilot study in the fourth year of the proposed work, during which radiologists will compare the use of a prototype system with conventional image-by-image reading for accuracy and efficiency. We will focus our analyses on (1) aortoiliac aneurysm, and (2) lower extremity occlusive disease, as test cases for the new technology. Upon completion of these studies, we expect that our developments will be easily adaptable to other applications both within and outside of vascular imaging, as well as to other imaging modalities such as MRI. Our overall goal is to change and validate the way crosssectional images are interpreted in general, thus resulting in improved accuracy and efficiency in the assessment of increasingly large volumes of medical image data.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
1R01HL067194-01A1
Application #
6434968
Study Section
Diagnostic Imaging Study Section (DMG)
Program Officer
Buxton, Denis B
Project Start
2001-12-15
Project End
2005-11-30
Budget Start
2001-12-15
Budget End
2002-11-30
Support Year
1
Fiscal Year
2002
Total Cost
$424,353
Indirect Cost

  Institution

Name
Stanford University
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
800771545
City
Stanford
State
CA
Country
United States
Zip Code
94305

  Publications

Won, Joong-Ho; Jeon, Yongkweon; Rosenberg, Jarrett K et al. (2013) Uncluttered Single-Image Visualization of Vascular Structures Using GPU and Integer Programming. IEEE Trans Vis Comput Graph 19:81-93
Raman, Bhargav; Raman, Raghav; Napel, Sandy et al. (2010) Automated quantification of aortoaortic and aortoiliac angulation for computed tomographic angiography of abdominal aortic aneurysms before endovascular repair: preliminary study. J Vasc Interv Radiol 21:1746-50
Roos, Justus E; Rakshe, Tejas; Tran, David N et al. (2009) Lower extremity CT angiography (CTA): initial evaluation of a knowledge-based centerline estimation algorithm for femoro-popliteal artery (FPA) occlusions. Acad Radiol 16:646-53
Won, Joong-Ho; Rosenberg, Jarrett; Rubin, Geoffrey D et al. (2009) Uncluttered single-image visualization of the abdominal aortic vessel tree: method and evaluation. Med Phys 36:5245-60
Tran, David N; Straka, Matus; Roos, Justus E et al. (2009) Dual-energy CT discrimination of iodine and calcium: experimental results and implications for lower extremity CT angiography. Acad Radiol 16:160-71
Raman, Raghav; Raman, Bhargav; Napel, Sandy et al. (2008) Improved speed of bone removal in computed tomographic angiography using automated targeted morphological separation: method and evaluation in computed tomographic angiography of lower extremity occlusive disease. J Comput Assist Tomogr 32:485-91
Rakshe, Tejas; Fleischmann, Dominik; Rosenberg, Jarrett et al. (2008) An improved algorithm for femoropopliteal artery centerline restoration using prior knowledge of shapes and image space data. Med Phys 35:3372-82
Tran, David N; Fleischmann, Dominik; Rakshe, Tejas et al. (2007) Femoropopliteal artery centerline interpolation using contralateral shape. Med Phys 34:3428-35
Zhuge, Feng; Sun, Shaohua; Rubin, Geoffrey et al. (2007) A directional distance aided method for medical image segmentation. Med Phys 34:4962-76
Rakshe, Tejas; Fleischmann, Dominik; Rosenberg, Jarrett et al. (2007) Knowledge-based interpolation of curves: application to femoropopliteal arterial centerline restoration. Med Image Anal 11:157-68

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