Coronary x-ray angiographic reconstruction and image orientation.

We have developed an interactive geometric method for 3D reconstruction of the coronary arteries using multiple single-plane angiographic views with arbitrary orientations. Epipolar planes and epipolar lines are employed to trace corresponding vessel segments on these views. These points are utilized to reconstruct 3D vessel centerlines. The accuracy of the reconstruction is assessed using: (1) near-intersection distances of the rays that connect x-ray sources with projected points, (2) distances between traced and projected centerlines. These same two measures enter into a fitness function for a genetic search algorithm (GA) employed to orient the angiographic image planes automatically in 3D avoiding local minima in the search for optimized parameters. Furthermore, the GA utilizes traced vessel shapes (as opposed to isolated anchor points) to assist the optimization process. Differences between two-view and multiview reconstructions are evaluated. Vessel radii are measured and used to render the coronary tree in 3D as a surface. Reconstruction fidelity is demonstrated via (1) virtual phantom, (2) real phantom, and (3) patient data sets, the latter two of which utilize the GA. These simulated and measured angiograms illustrate that the vessel center-lines are reconstructed in 3D with accuracy below 1 mm. The reconstruction method is thus accurate compared to typical vessel dimensions of 1-3 mm. The methods presented should enable a combined interpretation of the severity of coronary artery stenoses and the hemodynamic impact on myocardial perfusion in patients with coronary artery disease.

[1]  Jack Sklansky,et al.  Reconstructing the cross sections of coronary arteries from biplane angiograms , 1992, IEEE Trans. Medical Imaging.

[2]  John D. Carroll,et al.  Quantitative analysis of reconstructed 3-D coronary arterial tree and intracoronary devices , 2002, IEEE Transactions on Medical Imaging.

[3]  H Wollschläger,et al.  Optimum angiographic visualization of coronary segments using computer-aided 3D-reconstruction from biplane views. , 1994, Computers and biomedical research, an international journal.

[4]  Hanjörg Just,et al.  Fusion imaging: Combined visualization of 3D reconstructed coronary artery tree and 3D myocardial scintigraphic image in coronary artery disease , 1999, The International Journal of Cardiac Imaging.

[5]  Marco Mazzucco,et al.  A system for determination of 3D vessel tree centerlines from biplane images , 2004, The International Journal of Cardiac Imaging.

[6]  D. L. Pope,et al.  Three-dimensional reconstruction of moving arterial beds from digital subtraction angiography. , 1987, Computers and biomedical research, an international journal.

[7]  Andreas Wahle,et al.  Assessment of diffuse coronary artery disease by quantitative analysis of coronary morphology based upon 3-D reconstruction from biplane angiograms , 1995, IEEE Trans. Medical Imaging.

[8]  C. David Cooke,et al.  A quantitative evaluation of the three dimensional reconstruction of patients' coronary arteries , 2004, The International Journal of Cardiac Imaging.

[9]  M. Sonka,et al.  Towards a geometrically correct 3-D reconstruction of tortuous coronary arteries based on biplane angiography and intravascular ultrasound , 1997, The International Journal of Cardiac Imaging.

[10]  Andreas Wahle,et al.  3D heart-vessel reconstruction from biplane angiograms , 1996, IEEE Computer Graphics and Applications.

[11]  N. Magosaki,et al.  Regional myocardial perfusion defects during exercise, as assessed by three dimensional integration of morphology and function, in relation to abnormal endothelium dependent vasoreactivity of the coronary microcirculation , 2003, Heart.

[12]  M. Garreau,et al.  A knowledge-based approach for 3-D reconstruction and labeling of vascular networks from biplane angiographic projections. , 1991, IEEE transactions on medical imaging.

[13]  J. Messenger,et al.  3D coronary reconstruction from routine single-plane coronary angiograms: Clinical validation and quantitative analysis of the right coronary artery in 100 patients , 2000, The International Journal of Cardiac Imaging.

[14]  Russell D Folks,et al.  Three-dimensional fusion of coronary arteries with myocardial perfusion distributions: clinical validation. , 2004, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[15]  Piotr J. Slomka,et al.  Interactive volume rendering of multimodality 4D cardiac data with the use of consumer graphics hardware , 2003, SPIE Medical Imaging.

[16]  Riccardo Poli,et al.  Genetic algorithm-based interactive segmentation of 3D medical images , 1999, Image Vis. Comput..

[17]  D. Berman,et al.  Automatic quantification of ejection fraction from gated myocardial perfusion SPECT. , 1995, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[18]  C J Henri,et al.  Three-dimensional reconstruction of vascular trees. Theory and methodology. , 1996, Medical physics.

[19]  Pieter M. J. van der Zwet,et al.  A new approach for the automated definition of path lines in digitized coronary angiograms , 2005, The International Journal of Cardiac Imaging.

[20]  N. Magosaki,et al.  3D Assessment of myocardial perfusion parameter combined with 3D reconstructed coronary artery tree from digital coronary angiograms , 2000, The International Journal of Cardiac Imaging.

[21]  K R Hoffmann,et al.  Determination of 3D imaging geometry and object configurations from two biplane views: an enhancement of the Metz-Fencil technique. , 1995, Medical physics.

[22]  Martin Kraus,et al.  High-quality pre-integrated volume rendering using hardware-accelerated pixel shading , 2001, HWWS '01.

[23]  J. Sklansky,et al.  Estimating the 3D skeletons and transverse areas of coronary arteries from biplane angiograms. , 1988, IEEE transactions on medical imaging.

[24]  J. Messenger,et al.  Angiographic views used for percutaneous coronary interventions: A three‐dimensional analysis of physician‐determined vs. computer‐generated views , 2005, Catheterization and cardiovascular interventions : official journal of the Society for Cardiac Angiography & Interventions.

[25]  J. Messenger,et al.  Three-Dimensional Analysis of in vivo Coronary Stent – Coronary Artery Interactions , 2004, The International Journal of Cardiovascular Imaging.

[26]  John D. Carroll,et al.  Kinematic and deformation analysis of 4-D coronary arterial trees reconstructed from cine angiograms , 2003, IEEE Transactions on Medical Imaging.

[27]  E. Wellnhofer,et al.  Validation of an accurate method for three-dimensional reconstruction and quantitative assessment of volumes, lengths and diameters of coronary vascular branches and segments from biplane angiographic projections , 1999, The International Journal of Cardiac Imaging.

[28]  James H. Anderson,et al.  Constructive algorithms of vascular network modeling for training of minimally invasive catheterization procedure , 2003 .

[29]  John O. Prior,et al.  Myocardial viability in patients with ischemic cardiomyopathy-evaluation by 3-D integration of myocardial scintigraphic data--and coronary angiographic data. , 2004, Molecular imaging and biology : MIB : the official publication of the Academy of Molecular Imaging.

[30]  C J Henri,et al.  Three-dimensional reconstruction of vascular trees: experimental evaluation. , 1996, Medical physics.

[31]  John D. Carroll,et al.  3-D reconstruction of coronary arterial tree to optimize angiographic visualization , 2000, IEEE Transactions on Medical Imaging.

[32]  David G. Gobbi,et al.  Dynamic three-dimensional model of the coronary circulation , 2001, SPIE Medical Imaging.

[33]  Jack Sklansky,et al.  Reconstructing the 3-D medial axes of coronary arteries in single-view cineangiograms , 1994, IEEE Trans. Medical Imaging.