Mie Kunio1, Caroline C O'Brien2, Augusto C Lopes2, Lynn Bailey3, Pedro A Lemos4,5, Guillermo J Tearney6, Elazer R Edelman2. 1. Massachusetts Institute of Technology, 77 Massachusetts Avenue, E25-438, Cambridge, MA, 02139, USA. miek@mit.edu. 2. Massachusetts Institute of Technology, 77 Massachusetts Avenue, E25-438, Cambridge, MA, 02139, USA. 3. CBSET, Inc., 500 Shire Way, Lexington, MA, USA. 4. Heart Institute (InCor), University of Sao Paulo Medical School, Sao Paulo, Brazil. 5. Hospital Israelita Albert Einstein, Sao Paulo, Brazil. 6. Massachusetts General Hospital, 55 Fruit Street, Bar 703, Boston, MA, USA.
Abstract
PURPOSE: Three-dimensional reconstruction of a vessel centerline from paired planar coronary angiographic images is critical to reconstruct the complex three-dimensional structure of the coronary artery lumen and the relative positioning of implanted devices. In this study, a new vessel centerline reconstruction method that can utilize non-isocentric and non-orthogonal pairs of angiographic images was developed and tested. METHODS: Our new method was developed in in vitro phantom models of bifurcated coronary artery with and without stent, and then tested in in vivo swine models (twelve coronary arteries). This method was also validated using data from six patients. RESULTS: Our new method demonstrated high accuracy (root mean square error = 0.27 mm or 0.76 pixel), and high reproducibility across a broad imaging angle (20°-130°) and between different cardiac cycles in vitro and in vivo. Use of this method demonstrated that the vessel centerline in the stented segment did not deform significantly over a cardiac cycle in vivo. In addition, the total movement of the isocenter in each image could be accurately estimated in vitro and in vivo. The performance of this new method for patient data was similar to that for in vitro phantom models and in vivo animal models. CONCLUSIONS: We developed a vessel centerline reconstruction method for non-isocentric and non-orthogonal angiographic images. It demonstrated high accuracy and good reproducibility in vitro, in vivo, and in clinical setting, suggesting that our new method is clinically applicable despite the small sample size of clinical data.
PURPOSE: Three-dimensional reconstruction of a vessel centerline from paired planar coronary angiographic images is critical to reconstruct the complex three-dimensional structure of the coronary artery lumen and the relative positioning of implanted devices. In this study, a new vessel centerline reconstruction method that can utilize non-isocentric and non-orthogonal pairs of angiographic images was developed and tested. METHODS: Our new method was developed in in vitro phantom models of bifurcated coronary artery with and without stent, and then tested in in vivo swine models (twelve coronary arteries). This method was also validated using data from six patients. RESULTS: Our new method demonstrated high accuracy (root mean square error = 0.27 mm or 0.76 pixel), and high reproducibility across a broad imaging angle (20°-130°) and between different cardiac cycles in vitro and in vivo. Use of this method demonstrated that the vessel centerline in the stented segment did not deform significantly over a cardiac cycle in vivo. In addition, the total movement of the isocenter in each image could be accurately estimated in vitro and in vivo. The performance of this new method for patient data was similar to that for in vitro phantom models and in vivo animal models. CONCLUSIONS: We developed a vessel centerline reconstruction method for non-isocentric and non-orthogonal angiographic images. It demonstrated high accuracy and good reproducibility in vitro, in vivo, and in clinical setting, suggesting that our new method is clinically applicable despite the small sample size of clinical data.
Entities:
Keywords:
Coronary angiography; Image reconstruction; Reconstruction algorithm; Stereoscopic theory
Authors: Steve Ramcharitar; Joost Daeman; Mark Patterson; Robert Jan van Guens; Eric Boersma; Patrick W Serruys; Willem J van der Giessen Journal: Catheter Cardiovasc Interv Date: 2008-01-01 Impact factor: 2.692
Authors: Shengxian Tu; Niels R Holm; Gerhard Koning; Zheng Huang; Johan H C Reiber Journal: Int J Cardiovasc Imaging Date: 2011-01-25 Impact factor: 2.357