Simultaneous 3D-2D image registration and C-arm calibration: Application to endovascular image-guided interventions.

PURPOSE Three-dimensional to two-dimensional (3D-2D) image registration is a key to fusion and simultaneous visualization of valuable information contained in 3D pre-interventional and 2D intra-interventional images with the final goal of image guidance of a procedure. In this paper, the authors focus on 3D-2D image registration within the context of intracranial endovascular image-guided interventions (EIGIs), where the 3D and 2D images are generally acquired with the same C-arm system. The accuracy and robustness of any 3D-2D registration method, to be used in a clinical setting, is influenced by (1) the method itself, (2) uncertainty of initial pose of the 3D image from which registration starts, (3) uncertainty of C-arm's geometry and pose, and (4) the number of 2D intra-interventional images used for registration, which is generally one and at most two. The study of these influences requires rigorous and objective validation of any 3D-2D registration method against a highly accurate reference or "gold standard" registration, performed on clinical image datasets acquired in the context of the intervention. METHODS The registration process is split into two sequential, i.e., initial and final, registration stages. The initial stage is either machine-based or template matching. The latter aims to reduce possibly large in-plane translation errors by matching a projection of the 3D vessel model and 2D image. In the final registration stage, four state-of-the-art intrinsic image-based 3D-2D registration methods, which involve simultaneous refinement of rigid-body and C-arm parameters, are evaluated. For objective validation, the authors acquired an image database of 15 patients undergoing cerebral EIGI, for which accurate gold standard registrations were established by fiducial marker coregistration. RESULTS Based on target registration error, the obtained success rates of 3D to a single 2D image registration after initial machine-based and template matching and final registration involving C-arm calibration were 36%, 73%, and 93%, respectively, while registration accuracy of 0.59 mm was the best after final registration. By compensating in-plane translation errors by initial template matching, the success rates achieved after the final stage improved consistently for all methods, especially if C-arm calibration was performed simultaneously with the 3D-2D image registration. CONCLUSIONS Because the tested methods perform simultaneous C-arm calibration and 3D-2D registration based solely on anatomical information, they have a high potential for automation and thus for an immediate integration into current interventional workflow. One of the authors' main contributions is also comprehensive and representative validation performed under realistic conditions as encountered during cerebral EIGI.

[1]  Rafael Beyar,et al.  Prospective motion correction of X-ray images for coronary interventions , 2005, IEEE Transactions on Medical Imaging.

[2]  Kawal S. Rhode,et al.  A system for real-time XMR guided cardiovascular intervention , 2005, IEEE Transactions on Medical Imaging.

[3]  A. G. Osborn,et al.  3D Rotational Angiography: The New Gold Standard in the Detection of Additional Intracranial Aneurysms , 2009 .

[4]  M Ginks,et al.  2D–3D registration of cardiac images using catheter constraints , 2009, 2009 36th Annual Computers in Cardiology Conference (CinC).

[5]  Graeme P. Penney,et al.  Increasing the Automation of a 2D-3D Registration System , 2013, IEEE Transactions on Medical Imaging.

[6]  David J. Hawkes,et al.  A comparison of a similarity-based and a feature-based 2-D-3-D registration method for neurointerventional use , 2005, IEEE Transactions on Medical Imaging.

[7]  Michael Söderman,et al.  3D roadmap in neuroangiography: technique and clinical interest , 2005, Neuroradiology.

[8]  M. J. D. Powell,et al.  An efficient method for finding the minimum of a function of several variables without calculating derivatives , 1964, Comput. J..

[9]  J H Siewerdsen,et al.  Automatic image-to-world registration based on x-ray projections in cone-beam CT-guided interventions. , 2009, Medical physics.

[10]  Uros Mitrovic,et al.  3D-2D Registration of Cerebral Angiograms: A Method and Evaluation on Clinical Images , 2013, IEEE Transactions on Medical Imaging.

[11]  Uros Mitrovic,et al.  Evaluation of 3D-2D registration methods for registration of 3D-DSA and 2D-DSA cerebral images , 2013, Medical Imaging.

[12]  Graeme P. Penney,et al.  Standardized evaluation methodology for 2-D-3-D registration , 2005, IEEE Transactions on Medical Imaging.

[13]  M. Figl,et al.  Validation for 2D/3D registration. I: A new gold standard data set. , 2011, Medical physics.

[14]  S Rossitti,et al.  3D Road-Mapping in the Endovascular Treatment of Cerebral Aneurysms and Arteriovenous Malformations , 2009, Interventional neuroradiology : journal of peritherapeutic neuroradiology, surgical procedures and related neurosciences.

[15]  Clemens M. Hentschke,et al.  Automatic 2D/3D-Registration of Cerebral DSA Data Sets , 2010, Bildverarbeitung für die Medizin.

[16]  Yoshito Otake,et al.  Robust 3D–2D image registration: application to spine interventions and vertebral labeling in the presence of anatomical deformation , 2013, Physics in medicine and biology.

[17]  Bostjan Likar,et al.  Standardized evaluation methodology for 3D/2D registration based on the Visible Human data set. , 2010, Medical physics.

[18]  J. Siewerdsen,et al.  3D–2D registration for surgical guidance: effect of projection view angles on registration accuracy , 2014, Physics in medicine and biology.

[19]  M. Viergever,et al.  Robust initialization of 2D-3D image registration using the projection-slice theorem and phase correlation. , 2010, Medical physics.

[20]  Boštjan Likar,et al.  “Gold standard” data for evaluation and comparison of 3D/2D registration methods , 2004, Computer aided surgery : official journal of the International Society for Computer Aided Surgery.

[21]  Marie-Odile Berger,et al.  3D Augmented Fluoroscopy in Interventional Neuroradiology: Precision Assessment and First Evaluation on Clinical Cases , 2006 .

[22]  Bostjan Likar,et al.  Robust Gradient-Based 3-D/2-D Registration of CT and MR to X-Ray Images , 2008, IEEE Transactions on Medical Imaging.

[23]  Nassir Navab,et al.  Planning and intraoperative visualization of liver catheterizations: new CTA protocol and 2D-3D registration method. , 2007, Academic radiology.

[24]  Kawal S. Rhode,et al.  Intensity-based 2-D - 3-D registration of cerebral angiograms , 2003, IEEE Transactions on Medical Imaging.

[25]  Nicholas Ayache,et al.  3D-2D Projective Registration of Free-Form Curves and Surfaces , 1997, Comput. Vis. Image Underst..

[26]  Brian Winey,et al.  Influence of imaging source and panel position uncertainties on the accuracy of 2D∕3D image registration of cranial images. , 2012, Medical physics.

[27]  Ameet K. Jain,et al.  FTRAC--a robust fluoroscope tracking fiducial. , 2005, Medical physics.

[28]  M. Sluzewski,et al.  3D Rotational Angiography: The New Gold Standard in the Detection of Additional Intracranial Aneurysms , 2008, American Journal of Neuroradiology.

[29]  Nikos Paragios,et al.  Registration of 3D Angiographic and X-Ray Images Using Sequential Monte Carlo Sampling , 2005, CVBIA.

[30]  J A Noble,et al.  Assessment of a technique for 2D-3D registration of cerebral intra-arterial angiography. , 2004, The British journal of radiology.

[31]  Nassir Navab,et al.  Linear intensity-based image registration by Markov random fields and discrete optimization , 2010, Medical Image Anal..

[32]  Hiroki Shirato,et al.  Clinical significance of 3D reconstruction of arteriovenous malformation using digital subtraction angiography and its modification with CT information in stereotactic radiosurgery. , 2003, International journal of radiation oncology, biology, physics.

[33]  Günter Lauritsch,et al.  3D Imaging with Flat-Detector C-Arm Systems , 2009 .

[34]  Tomaz Slivnik,et al.  3-D/2-D registration of CT and MR to X-ray images , 2003, IEEE Transactions on Medical Imaging.

[35]  Frank Deinzer,et al.  Extended Global Optimization Strategy for Rigid 2D/3D Image Registration , 2007, CAIP.

[36]  Marie-Odile Berger,et al.  Fully Automatic 3D/2D Subtracted Angiography Registration , 1999, MICCAI.

[37]  Peter Kazanzides,et al.  Intraoperative Image-based Multiview 2D/3D Registration for Image-Guided Orthopaedic Surgery: Incorporation of Fiducial-Based C-Arm Tracking and GPU-Acceleration , 2012, IEEE Transactions on Medical Imaging.

[38]  B. Wilson,et al.  Volume CT with a flat-panel detector on a mobile, isocentric C-arm: pre-clinical investigation in guidance of minimally invasive surgery. , 2005, Medical physics.

[39]  Caroline Petitjean,et al.  A review of 3 D / 2 D registration methods for image-guided interventions , 2016 .

[40]  Nassir Navab,et al.  Template-based CTA to x-ray angio rigid registration of coronary arteries in frequency domain with automatic x-ray segmentation. , 2013, Medical physics.

[41]  G Fichtinger,et al.  Technical note: unsupervised C-arm pose tracking with radiographic fiducial. , 2011, Medical physics.

[42]  Stephen Rudin,et al.  Endovascular image-guided interventions (EIGIs). , 2007, Medical physics.

[43]  T. Carrell,et al.  Increasing the Automation of a 2 D – 3 D Registration System , 2014 .

[44]  J. Alison Noble,et al.  Real-Time Registration of 3D Cerebral Vessels to X-ray Angiograms , 1998, MICCAI.

[45]  Rangasami L. Kashyap,et al.  Building Skeleton Models via 3-D Medial Surface/Axis Thinning Algorithms , 1994, CVGIP Graph. Model. Image Process..

[46]  Bostjan Likar,et al.  A review of 3D/2D registration methods for image-guided interventions , 2012, Medical Image Anal..

[47]  M. Mokin,et al.  Advances in Endovascular Approaches to Cerebral Aneurysms. , 2014, Neurosurgery.

[48]  S A Wickline,et al.  MR molecular imaging of angiogenesis using targeted perfluorocarbon nanoparticles. , 2010, Medicamundi.

[49]  J H Siewerdsen,et al.  Geometric calibration of a mobile C-arm for intraoperative cone-beam CT. , 2008, Medical physics.

[50]  Daniel Ruijters,et al.  Validation of 3D multimodality roadmapping in interventional neuroradiology , 2011, Physics in medicine and biology.

[51]  D Roadmapping in neuroendovascular procedures – an evaluation , 2010 .

[52]  Nassir Navab,et al.  Dynamic geometrical calibration for 3D cerebral angiography , 1996, Medical Imaging.

[53]  Andrew Copeland,et al.  Spatio-temporal data fusion in cerebral angiography , 2007 .

[54]  Maximilien Vermandel,et al.  Intrinsic 2D/3D registration based on a hybrid approach: use in the radiosurgical imaging process. , 2007, Cellular and molecular biology.

[55]  Jay B. West,et al.  Predicting error in rigid-body point-based registration , 1998, IEEE Transactions on Medical Imaging.

[56]  Nassir Navab,et al.  Recovering the X-ray projection geometry for three-dimensional tomographic reconstruction with additional sensors: Attached camera versus external navigation system , 2003, Medical Image Anal..

[57]  Nassir Navab,et al.  Camera Augmented Mobile C-Arm (CAMC): Calibration, Accuracy Study, and Clinical Applications , 2010, IEEE Transactions on Medical Imaging.