A novel real‐time computational framework for detecting catheters and rigid guidewires in cardiac catheterization procedures

Purpose Catheters and guidewires are used extensively in cardiac catheterization procedures such as heart arrhythmia treatment (ablation), angioplasty, and congenital heart disease treatment. Detecting their positions in fluoroscopic X‐ray images is important for several clinical applications, for example, motion compensation, coregistration between 2D and 3D imaging modalities, and 3D object reconstruction. Methods For the generalized framework, a multiscale vessel enhancement filter is first used to enhance the visibility of wire‐like structures in the X‐ray images. After applying adaptive binarization method, the centerlines of wire‐like objects were extracted. Finally, the catheters and guidewires were detected as a smooth path which is reconstructed from centerlines of target wire‐like objects. In order to classify electrode catheters which are mainly used in electrophysiology procedures, additional steps were proposed. First, a blob detection method, which is embedded in vessel enhancement filter with no additional computational cost, localizes electrode positions on catheters. Then the type of electrode catheters can be recognized by detecting the number of electrodes and also the shape created by a series of electrodes. Furthermore, for detecting guiding catheters or guidewires, a localized machine learning algorithm is added into the framework to distinguish between target wire objects and other wire‐like artifacts. The proposed framework were tested on total 10,624 images which are from 102 image sequences acquired from 63 clinical cases. Results Detection errors for the coronary sinus (CS) catheter, lasso catheter ring and lasso catheter body are 0.56 ± 0.28 mm, 0.64 ± 0.36 mm, and 0.66 ± 0.32 mm, respectively, as well as success rates of 91.4%, 86.3%, and 84.8% were achieved. Detection errors for guidewires and guiding catheters are 0.62 ± 0.48 mm and success rates are 83.5%. Conclusion The proposed computational framework do not require any user interaction or prior models and it can detect multiple catheters or guidewires simultaneously and in real‐time. The accuracy of the proposed framework is sub‐mm and the methods are robust toward low‐dose X‐ray fluoroscopic images, which are mainly used during procedures to maintain low radiation dose.

[1]  Wei Zhang,et al.  Robust guidewire tracking in fluoroscopy , 2009, 2009 IEEE Conference on Computer Vision and Pattern Recognition.

[2]  Li Wang,et al.  Guide-wire detection using region proposal network for X-ray image-guided navigation , 2017, 2017 International Joint Conference on Neural Networks (IJCNN).

[3]  Rui Liao,et al.  Respiratory motion compensation by model-based catheter tracking during EP procedures , 2010, Medical Image Anal..

[4]  Rui Liao,et al.  3-D Respiratory Motion Compensation during EP Procedures by Image-Based 3-D Lasso Catheter Model Generation and Tracking , 2009, MICCAI.

[5]  Max A. Viergever,et al.  Guide Wire Tracking During Endovascular Interventions , 2000, MICCAI.

[6]  Demetri Terzopoulos,et al.  Snakes: Active contour models , 2004, International Journal of Computer Vision.

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

[8]  Marie-Pierre Jolly,et al.  A Planning and Guidance Platform for Cardiac Resynchronization Therapy , 2017, IEEE Transactions on Medical Imaging.

[9]  YingLiang Ma,et al.  Real-Time Respiratory Motion Correction for Cardiac Electrophysiology Procedures Using Image-Based Coronary Sinus Catheter Tracking , 2010, MICCAI.

[10]  S. Knecht,et al.  Computed tomography-fluoroscopy overlay evaluation during catheter ablation of left atrial arrhythmia. , 2008, Europace : European pacing, arrhythmias, and cardiac electrophysiology : journal of the working groups on cardiac pacing, arrhythmias, and cardiac cellular electrophysiology of the European Society of Cardiology.

[11]  G. M. Chaudhry,et al.  Three-dimensional rotational angiography of the left atrium and esophagus--A virtual computed tomography scan in the electrophysiology lab? , 2007, Heart rhythm.

[12]  N. Otsu A threshold selection method from gray level histograms , 1979 .

[13]  Alejandro F. Frangi,et al.  Muliscale Vessel Enhancement Filtering , 1998, MICCAI.

[14]  YingLiang Ma,et al.  Clinical Evaluation of Respiratory Motion Compensation for Anatomical Roadmap Guided Cardiac Electrophysiology Procedures , 2012, IEEE Transactions on Biomedical Engineering.

[15]  R. Beyar,et al.  Identifying and tracking a guide wire in the coronary arteries during angioplasty from X-ray images , 1997, IEEE Transactions on Biomedical Engineering.

[16]  Guillermo Sapiro,et al.  Toward Multiple Catheters Detection in Fluoroscopic Image Guided Interventions , 2012, IEEE Transactions on Information Technology in Biomedicine.

[17]  Nader Karimi,et al.  Vessel region detection in coronary X-ray angiograms , 2015, 2015 IEEE International Conference on Image Processing (ICIP).

[18]  Klaus C. J. Dietmayer,et al.  Catheter tracking in asynchronous biplane fluoroscopy images by 3D B-snakes , 2010, Medical Imaging.

[19]  Günter Lauritsch,et al.  Time-resolved three-dimensional imaging of the left atrium and pulmonary veins in the interventional suite--a comparison between multisweep gated rotational three-dimensional reconstructed fluoroscopy and multislice computed tomography. , 2008, Heart rhythm.

[20]  Richard James Housden,et al.  Novel Looped-Catheter-Based 2D-3D Registration Algorithm for MR, 3DRx and X-Ray Images: Validation Study in an Ex-vivo Heart , 2016, STACOM@MICCAI.

[21]  Nassir Navab,et al.  A Machine Learning Approach for Deformable Guide-Wire Tracking in Fluoroscopic Sequences , 2010, MICCAI.

[22]  Dorin Comaniciu,et al.  Learning-based hypothesis fusion for robust catheter tracking in 2D X-ray fluoroscopy , 2011, CVPR 2011.

[23]  Ching Y. Suen,et al.  A fast parallel algorithm for thinning digital patterns , 1984, CACM.

[24]  YingLiang Ma,et al.  A machine learning framework for context specific collimation and workflow phase detection , 2018 .

[25]  K. Rhode,et al.  Real-time x-ray fluoroscopy-based catheter detection and tracking for cardiac electrophysiology interventions. , 2013, Medical physics.

[26]  D. Krum,et al.  Computed Tomography‐Fluoroscopy Image Integration‐Guided Catheter Ablation of Atrial Fibrillation , 2007, Journal of cardiovascular electrophysiology.

[27]  Ziyan Wu,et al.  Guidewire tracking using a novel sequential segment optimization method in interventional X-ray videos , 2016, 2016 IEEE 13th International Symposium on Biomedical Imaging (ISBI).

[28]  Alan L. Yuille,et al.  FORMS: A flexible object recognition and modelling system , 1996, International Journal of Computer Vision.

[29]  Nassir Marrouche,et al.  Three-dimensional left atrial and esophagus reconstruction using cardiac C-arm computed tomography with image integration into fluoroscopic views for ablation of atrial fibrillation: accuracy of a novel modality in comparison with multislice computed tomography. , 2008, Heart rhythm.

[30]  C A Rinaldi,et al.  A statistical model of catheter motion from interventional x-ray images: application to image-based gating , 2013, Physics in medicine and biology.

[31]  Dorin Comaniciu,et al.  Hierarchical Learning of Curves Application to Guidewire Localization in Fluoroscopy , 2007, 2007 IEEE Conference on Computer Vision and Pattern Recognition.

[32]  F. Maes,et al.  Biplane three-dimensional augmented fluoroscopy as single navigation tool for ablation of atrial fibrillation: accuracy and clinical value. , 2008, Heart rhythm.