Your search keyword '"Felix Bourier"' showing total 5 results

1. Real-time guidewire tracking and segmentation in intraoperative x-ray

Author

Baochang Zhang, Mai Bui, Cheng Wang, Felix Bourier, Heribert Schunkert, and Nassir Navab

Published

2022

2. Reconstruction method for curvilinear structures from two views

Author

Matthias Hoffmann, Martin Koch, Carolin Jakob, Felix Bourier, Joachim Hornegger, Norbert Strobel, Alexander Brost, and Klaus Kurzidim

Subjects

Ground truth, medicine.diagnostic_test, Computer science, business.industry, medicine.medical_treatment, Epipolar geometry, 3D reconstruction, Ablation, computer.software_genre, Imaging phantom, Voxel, medicine, Fluoroscopy, Computer vision, Artificial intelligence, business, Focus (optics), computer

Abstract

Minimally invasive interventions often involve tools of curvilinear shape like catheters and guide-wires. If the camera parameters of a fluoroscopic system or a stereoscopic endoscope are known, a 3-D reconstruction of corresponding points can be computed by triangulation. Manual identification of point correspondences is time consuming, but there exist methods that automatically select corresponding points along curvilinear structures. The focus here is on the evaluation of a recent published method for catheter reconstruction from two views. A previous evaluation of this method using clinical data yielded promising results. For that evaluation, however, no 3-D ground truth data was available such that the error could only be estimated using the forward-projection of the reconstruction. In this paper, we present a more extensive evaluation of this method based on both clinical and phantom data. For the evaluation using clinical images, 36 data sets and two different catheters were available. The mean error found when reconstructing both catheters was 0.1mm ± 0.1mm. To evaluate the error in 3-D, images of a phantom were acquired from 13 different angulations. For the phantom, A 3D C-arm CT voxel data set of the phantom was also available. A reconstruction error was calculated by comparing the triangulated 3D reconstruction result to the 3D voxel data set. The evaluation yielded an average error of 1.2mm ± 1.2mm for the circumferential mapping catheter and 1.3mm ± 1.0mm for the ablation catheter.

Published

2013

3. Cryo-balloon catheter localization in fluoroscopic images

Author

Philip Mewes, Felix Bourier, Joachim Hornegger, Tanja Kurzendorfer, Klaus Kurzidim, Carolin Jakob, Alexander Brost, Norbert Strobel, and Martin Koch

Subjects

Catheter, Computer science, medicine.medical_treatment, medicine, Balloon catheter, Treatment options, Catheter ablation, Landmark point, Blob detection, Ablation, Biomedical engineering

Abstract

Minimally invasive catheter ablation has become the preferred treatment option for atrial fibrillation. Although the standard ablation procedure involves ablation points set by radio-frequency catheters, cryo-balloon catheters have even been reported to be more advantageous in certain cases. As electro-anatomical mapping systems do not support cryo-balloon ablation procedures, X-ray guidance is needed. However, current methods to provide support for cryo-balloon catheters in fluoroscopically guided ablation procedures rely heavily on manual user interaction. To improve this, we propose a first method for automatic cryo-balloon catheter localization in fluoroscopic images based on a blob detection algorithm. Our method is evaluated on 24 clinical images from 17 patients. The method successfully detected the cryoballoon in 22 out of 24 images, yielding a success rate of 91.6 %. The successful localization achieved an accuracy of 1.00 mm ± 0.44 mm. Even though our methods currently fails in 8.4 % of the images available, it still offers a significant improvement over manual methods. Furthermore, detecting a landmark point along the cryo-balloon catheter can be a very important step for additional post-processing operations.

Published

2013

4. Real-time circumferential mapping catheter tracking for motion compensation in atrial fibrillation ablation procedures

Author

Andreas Wimmer, Klaus Kurzidim, Atilla Peter Kiraly, Felix Bourier, Martin Koch, Joachim Hornegger, Alexander Brost, Rui Liao, and Norbert Strobel

Subjects

Motion compensation, medicine.diagnostic_test, Computer science, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Frame rate, medicine.disease, Catheter, Radiofrequency catheter ablation, medicine, Fluoroscopy, Segmentation, Computer vision, Artificial intelligence, business, Distance transform, Stroke

Abstract

Atrial fibrillation (AFib) has been identified as a major cause of stroke. Radiofrequency catheter ablation has become an increasingly important treatment option, especially when drug therapy fails. Navigation under X-ray can be enhanced by using augmented fluoroscopy. It renders overlay images from pre-operative 3-D data sets which are then fused with X-ray images to provide more details about the underlying soft-tissue anatomy. Unfortunately, these fluoroscopic overlay images are compromised by respiratory and cardiac motion. Various methods to deal with motion have been proposed. To meet clinical demands, they have to be fast. Methods providing a processing frame rate of 3 frames-per-second (fps) are considered suitable for interventional electrophysiology catheter procedures if an acquisition frame rate of 2 fps is used. Unfortunately, when working at a processing rate of 3 fps, the delay until the actual motion compensated image can be displayed is about 300 ms. More recent algorithms can achieve frame rates of up to 20 fps, which reduces the lag to 50 ms. By using a novel approach involving a 3-D catheter model, catheter segmentation and a distance transform, we can speed up motion compensation to 25 fps which results in a display delay of only 40 ms on a standard workstation for medical applications. Our method uses a constrained 2-D/3-D registration to perform catheter tracking, and it obtained a 2-D tracking error of 0.61 mm.

Published

2012

5. First steps towards initial registration for electrophysiology procedures

Author

Joachim Hornegger, Alexander Brost, Norbert Strobel, Liron Yatziv, Klaus Kurzidim, Felix Bourier, and Martin Koch

Subjects

medicine.medical_specialty, medicine.diagnostic_test, business.industry, medicine.medical_treatment, Catheter ablation, Atrial fibrillation, Magnetic resonance imaging, medicine.disease, Ablation, Biplane, Catheter, Heart arrhythmia, medicine, Radiology, business, Coronary sinus

Abstract

Atrial fibrillation is the most common heart arrhythmia and a leading cause of stroke. The treatment option of choice is radio-frequency catheter ablation, which is performed in electrophysiology labs using C-Arm X-ray systems for navigation and guidance. The goal is to electrically isolate the pulmonary vein-left atrial junction thereby rendering myocardial fibers responsible for induction and maintenance of AF inactive. The use of overlay images for fluoroscopic guidance may improve the quality of the ablation procedure, and can reduce procedure time. Overlay images, acquired using CT, MRI, or C-arm CT, can add soft-tissue information, otherwise not visible under X-ray. MRI can be used to image a wide variety of anatomical details without ionizing radiation. In this paper, we present a method to register a 3-D MRI volume to 2-D biplane X-ray images using the coronary sinus. Current approaches require registration of the overlay images to the fluoroscopic images to be performed after the trans-septal puncture, when contast agent can be administered. We present a new approach for registration to align overlay images before the trans-septal puncture. To this end, we manually extract the coronary sinus from pre-operative MRI and register it to a multi-electorde catheter placed in the coronary sinus.

Published

2011