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Stefan Wörz
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2010 – 2019
- 2018
- [j14]Sharib Ali
, Stefan Wörz, Katrin Amunts
Rigid and non-rigid registration of polarized light imaging data for 3D reconstruction of the temporal lobe of the human brain at micrometer resolution. NeuroImage 181: 235-251 (2018) - [j13]Wei Liao
Progressive Minimal Path Method for Segmentation of 2D and 3D Line Structures. IEEE Trans. Pattern Anal. Mach. Intell. 40(3): 696-709 (2018) - 2017
- [c64]Sharib Ali
Spline-Based Multimodal Image Registration of 3D PLI Data of the Human Brain. Bildverarbeitung für die Medizin 2017: 268-273 - [c63]Sharib Ali
Registration of ultra-high resolution 3D PLI data of human brain sections to their corresponding high-resolution counterpart. ISBI 2017: 415-419 - [c62]Sharib Ali
Elastic registration of high-resolution 3D PLI data of the human brain. ISBI 2017: 1151-1155 - 2016
- [j12]Simon Eck, Stefan Wörz, Katharina Müller-Ott, Matthias Hahn, Andreas Biesdorf
A spherical harmonics intensity model for 3D segmentation and 3D shape analysis of heterochromatin foci. Medical Image Anal. 32: 18-31 (2016) - [j11]Wei Liao, Karl Rohr, Chang-Ki Kang, Zang-Hee Cho, Stefan Wörz:
Automatic 3D Segmentation and Quantification of Lenticulostriate Arteries from High-Resolution 7 Tesla MRA Images. IEEE Trans. Image Process. 25(1): 400-413 (2016) - [c61]Stefan Wörz, Philipp Hoegen, Wei Liao, Matthias Müller-Eschner, Hans-Ulrich Kauczor, Hendrik von Tengg-Kobligk
Framework for quantitative evaluation of 3D vessel segmentation approaches using vascular phantoms in conjunction with 3D landmark localization and registration. Image Processing 2016: 978419 - 2015
- [c60]Andreas Biesdorf
3D segmentation of vessels by incremental implicit polynomial fitting and convex optimization. ISBI 2015: 1540-1543 - [c59]Stefan Wörz, Hendrik von Tengg-Kobligk
3D statistical models of the aorta and the supra-aortic branches. ISBI 2015: 1572-1575 - 2014
- [j10]Stefan Wörz, Karl Rohr:
Spline-Based Hybrid Image Registration using Landmark and Intensity Information based on Matrix-Valued Non-radial Basis Functions. Int. J. Comput. Vis. 106(1): 76-92 (2014) - [c58]Stefan Wörz, Abdulsattar Alrajab, Raoul Arnold, Joachim Eichhorn, Hendrik von Tengg-Kobligk
Quantification of the Aortic Morphology in Follow-Up 3D-MRA Images of Children. Bildverarbeitung für die Medizin 2014: 192-197 - [c57]Julian Hennies, Jan-Philip Bergeest, Simon Eck, Karl Rohr, Stefan Wörz:
Cell Segmentation and Cell Splitting Based on Gradient Flow Tracking in Microscopic Images. Bildverarbeitung für die Medizin 2014: 409-414 - [c56]Stefan Wörz:
3D Model-Based Segmentation of 3D Biomedical Images. MEMICS 2014: 40-46 - [c55]Simon Eck, Stefan Wörz, Katharina Müller-Ott, Matthias Hahn, Gunnar Schotta, Karsten Rippe, Karl Rohr:
3D shape analysis of heterochromatin foci based on a 3D spherical harmonics intensity model. Image Processing 2014: 90340X - [c54]Stefan Wörz, Abdulsattar Alrajab, Raoul Arnold, Joachim Eichhorn, Hendrik von Tengg-Kobligk
3D geometric analysis of the aorta in 3D MRA follow-up pediatric image data. Image Processing 2014: 90340K - 2013
- [c53]Simon Eck, Stefan Wörz, Andreas Biesdorf
Segmentation of Heterochromatin Foci Using a 3D Spherical Harmonics Intensity Model. Bildverarbeitung für die Medizin 2013: 308-313 - [c52]Simon Eck, Karl Rohr, Andreas Biesdorf
A 3D intensity model based on spherical harmonics for automatic 3D segmentation of heterochromatin foci. ISBI 2013: 1484-1487 - [c51]Wei Liao, Karl Rohr, Stefan Wörz:
Globally Optimal Curvature-Regularized Fast Marching for Vessel Segmentation. MICCAI (1) 2013: 550-557 - 2012
- [j9]Andreas Biesdorf
Segmentation and quantification of the aortic arch using joint 3D model-based segmentation and elastic image registration. Medical Image Anal. 16(6): 1187-1201 (2012) - [c50]Wei Liao, Stefan Wörz, Karl Rohr:
Globally Minimal Path Method Using Dynamic Speed Functions Based on Progressive Wave Propagation. ACCV (2) 2012: 25-37 - [c49]Simon Eck, Karl Rohr, Katharina Müller-Ott, Karsten Rippe, Stefan Wörz:
Combined Model-Based and Region-Adaptive 3D Segmentation and 3D Co-Localization Analysis of Heterochromatin Foci. Bildverarbeitung für die Medizin 2012: 9-14 - [c48]Karl Rohr, Stefan Wörz:
An extension of thin-plate splines for image registration with radial basis functions. ISBI 2012: 442-445 - [c47]Wei Liao, Karl Rohr, Chang-Ki Kang, Zang-Hee Cho, Stefan Wörz:
Automatic human brain vessel segmentation from 3D 7 Tesla MRA images using fast marching with anisotropic directional prior. ISBI 2012: 1140-1143 - [c46]Stefan Wörz, Andreas Biesdorf
Elastic registration based on matrix-valued spline functions and direct integration of landmarks and intensities. Image Processing 2012: 83141B - [c45]Wei Liao, Stefan Wörz, Karl Rohr:
Vessel segmentation using an iterative fast marching approach with directional prior. Image Processing 2012: 831426 - 2011
- [c44]Stefan Wörz, Hendrik von Tengg-Kobligk
Model-Based Quantification of Small Tubular Structures in 3D Vascular Images. Bildverarbeitung für die Medizin 2011: 23-27 - [c43]Andreas Biesdorf
Aortic Arch Quantification using Efficient Joint Segmentation and Registration. Bildverarbeitung für die Medizin 2011: 279-283 - [c42]Wei Liao, Karl Rohr, Chang-Ki Kang, Zang-Hee Cho, Stefan Wörz:
A generative MRF approach for automatic 3D segmentation of cerebral vasculature from 7 Tesla MRA images. ISBI 2011: 2041-2044 - [c41]Andreas Biesdorf
Model-Based Segmentation and Motion Analysis of the Thoracic Aorta from 4D ECG-Gated CTA Images. MICCAI (1) 2011: 589-596 - 2010
- [j8]Stefan Wörz, Hendrik von Tengg-Kobligk
3-D Quantification of the Aortic Arch Morphology in 3-D CTA Data for Endovascular Aortic Repair. IEEE Trans. Biomed. Eng. 57(10): 2359-2368 (2010) - [j7]Stefan Wörz, Petra Sander, Martin Pfannmöller
3D Geometry-Based Quantification of Colocalizations in Multichannel 3D Microscopy Images of Human Soft Tissue Tumors. IEEE Trans. Medical Imaging 29(8): 1474-1484 (2010) - [c40]Stefan Wörz, Petra Sander, Martin Pfannmöller, Ralf J. Rieker, Stefan Joos, Gunhild Mechtersheimer, Petra Boukamp, Peter Lichter, Karl Rohr:
Model-Based Segmentation and Colocalization Quantification in 3D Microscopy Images. Bildverarbeitung für die Medizin 2010: 86-91 - [c39]Andreas Biesdorf
Combined Model-Based Segmentation and Elastic Registration for Accurate Quantification of the Aortic Arch. MICCAI (1) 2010: 444-451 - [c38]Stefan Wörz, Hendrik von Tengg-Kobligk
A new 3D tubular intensity model for quantification of thin vessels in 3D tomographic images. Image Processing 2010: 76230P
2000 – 2009
- 2009
- [j6]William J. Godinez
Deterministic and probabilistic approaches for tracking virus particles in time-lapse fluorescence microscopy image sequences. Medical Image Anal. 13(2): 325-342 (2009) - [c37]Stefan Wörz, William J. Godinez, Karl Rohr:
Probabilistic Tracking and Model-Based Segmentation of 3D Tubular Structures. Bildverarbeitung für die Medizin 2009: 41-45 - [c36]Thomas Lange, Stefan Wörz, Karl Rohr, Peter-Michael Schlag:
Landmark-Based 3D Elastic Registration of Pre- and Postoperative Liver CT Data. Bildverarbeitung für die Medizin 2009: 107-111 - [c35]Andreas Biesdorf
Hybrid Spline-Based Multimodal Registration Using a Local Measure for Mutual Information. Bildverarbeitung für die Medizin 2009: 127-131 - [c34]Stefan Wörz, Hendrik von Tengg-Kobligk, Verena Henninger, Dittmar Böckler, Hans-Ulrich Kauczor, Karl Rohr:
3D Segmentation and Quantification of the Aortic Arch for Endovascular Aortic Repair. Bildverarbeitung für die Medizin 2009: 162-166 - [c33]William J. Godinez, Marko Lampe
Evaluation of Approaches for Tracking Virus Particles in Fluorescence Microscopy Images. Bildverarbeitung für die Medizin 2009: 207-211 - [c32]Andreas Biesdorf
Automatic Detection of Supraaortic Branches and Model-Based Segmentation of the Aortic Arch from 3D CTA Images. ISBI 2009: 486-489 - [c31]William J. Godinez, Marko Lampe
Identifying Fusion Events in Fluorescence Microscopy Images. ISBI 2009: 1167-1170 - [c30]Andreas Biesdorf
Hybrid Spline-Based Multimodal Registration Using Local Measures for Joint Entropy and Mutual Information. MICCAI (1) 2009: 607-615 - [c29]Thomas Lange, Stefan Wörz, Karl Rohr, Peter M. Schlag:
Experimental comparison of landmark-based methods for 3D elastic registration of pre- and postoperative liver CT data. Image-Guided Procedures 2009: 72610M - [c28]Stefan Wörz, William J. Godinez, Karl Rohr:
Segmentation of 3D tubular structures based on 3D intensity models and particle filter tracking. Image Processing 2009: 72591P - 2008
- [j5]Stefan Wörz, Karl Rohr:
Physics-based elastic registration using non-radial basis functions and including landmark localization uncertainties. Comput. Vis. Image Underst. 111(3): 263-274 (2008) - [j4]Stefan Wörz, Karl Rohr:
Cramér-Rao Bounds for Estimating the Position and Width of 3D Tubular Structures and Analysis of Thin Structures with Application to Vascular Images. J. Math. Imaging Vis. 30(2): 167-180 (2008) - [c27]Stefan Wörz, Marie-Luise Winz
Geometric Alignment of 2D Gel Electrophoresis Images. Bildverarbeitung für die Medizin 2008: 97-101 - [c26]William J. Godinez, Marko Lampe
Probabilistic Tracking of Virus Particles in Fluorescence Microscopy Image Sequences. Bildverarbeitung für die Medizin 2008: 448-452 - [c25]William J. Godinez, Marko Lampe
Probabilistic tracking of virus particles in fluorescence microscopy images. ISBI 2008: 272-275 - [c24]Stefan Wörz, Marie-Luise Winz
Geometric alignment of 2D gel electrophoresis images using physics-based elastic registration. ISBI 2008: 1135-1138 - [c23]Stefan Wörz, Hendrik von Tengg-Kobligk
Quantification of the aortic arch morphology in 3D CTA images for endovascular aortic repair (EVAR). Image-Guided Procedures 2008: 69181H - [c22]Stefan Wörz, Karl Rohr:
Hybrid physics-based elastic image registration using approximating splines. Image Processing 2008: 69140V - 2007
- [j3]Stefan Wörz, Karl Rohr:
Segmentation and Quantification of Human Vessels Using a 3-D Cylindrical Intensity Model. IEEE Trans. Image Process. 16(8): 1994-2004 (2007) - [c21]William J. Godinez, Marko Lampe
Tracking of Virus Particles in Time-Lapse Fluorescence Microscopy Image Sequences. Bildverarbeitung für die Medizin 2007: 6-10 - [c20]Stefan Wörz, Karl Rohr:
Hybrid Spline-Based Elastic Image Registration Using Analytic Solutions of the Navier Equation. Bildverarbeitung für die Medizin 2007: 151-155 - [c19]Stefan Wörz, Karl Rohr:
Spline-Based Elastic Image Registration with Matrix-Valued Basis Functions Using Landmark and Intensity Information. DAGM-Symposium 2007: 537-546 - [c18]William J. Godinez, Marko Lampe
Tracking of Virus Particles in Time-Lapse Fluorescence Microscopy Image Sequences. ISBI 2007: 256-259 - [c17]Stefan Wörz, Karl Rohr:
Spline-based elastic image registration using solutions of the Navier equation. Image Processing 2007: 651204 - [c16]Stefan Wörz, Constantin Kappel, Roland Eils
Model-based segmentation and quantification of fluorescent bacteria in 3D microscopy live cell images. Image Processing 2007: 651234 - 2006
- [b1]Stefan Wörz:
3D parametric intensity models for the localization of 3D anatomical point landmarks and 3D segmentation of human vessels. University of Hamburg, 2006, ISBN 978-3-89838-299-1, pp. 1-321 - [j2]Stefan Wörz, Karl Rohr:
Localization of anatomical point landmarks in 3D medical images by fitting 3D parametric intensity models. Medical Image Anal. 10(1): 41-58 (2006) - [c15]Stefan Wörz, Karl Rohr:
Limits on Estimating the Width of Thin Vessels in 3D Medical Images. Bildverarbeitung für die Medizin 2006: 186-190 - [c14]Stefan Wörz, Karl Rohr:
New Approximating Gaussian Elastic Body Splines for Landmark-Based Registration of Medical Images. Bildverarbeitung für die Medizin 2006: 206-210 - [c13]Karl Rohr, Stefan Wörz:
High-precision localization and quantification of 3D tubular structures. ISBI 2006: 1160-1163 - [c12]Stefan Wörz, Karl Rohr:
Limits on Estimating the Width of Thin Tubular Structures in 3D Images. MICCAI (1) 2006: 215-222 - [c11]Stefan Wörz, Karl Rohr:
Physics-Based Elastic Image Registration Using Splines and Including Landmark Localization Uncertainties. MICCAI (2) 2006: 678-685 - 2005
- [c10]Stefan Wörz, Karl Rohr:
Adaptive Model-Based Segmentation of Human Vessels from 3D MRA and CTA Data. Bildverarbeitung für die Medizin 2005: 103-107 - 2004
- [j1]Karl Rohr, Pascal Cathier, Stefan Wörz:
Elastic registration of electrophoresis images using intensity information and point landmarks. Pattern Recognit. 37(5): 1035-1048 (2004) - [c9]Stefan Wörz, Karl Rohr:
3D Parametric Intensity Models for Accurate Segmentation and Quantification of Human Arteries. Bildverarbeitung für die Medizin 2004: 85-89 - [c8]Stefan Wörz, Karl Rohr:
Automatic ROI Size Selection and Parameter Initialization for Model-Based Localization of 3D Anatomical Point Landmarks. Bildverarbeitung für die Medizin 2004: 333-337 - [c7]Stefan Wörz, Karl Rohr:
3D Segmentation and Quantification of Human Vessels Based on a New 3D Parametric Intensity Model. DAGM-Symposium 2004: 111-119 - [c6]Pascal Cathier, Stefan Wörz, Karl Rohr:
Elastic Registration of Gel Electrophoresis Images Based on Landmarks and Intensities. ISBI 2004: 1451-1454 - [c5]Stefan Wörz, Karl Rohr:
A New 3D Parametric Intensity Model for Accurate Segmentation and Quantification of Human Vessels. MICCAI (1) 2004: 491-499 - 2003
- [c4]Stefan Wörz, Karl Rohr:
Localization of Anatomical Point Landmarks in 3D Medical Images by Fitting 3D Parametric Intensity Models. Bildverarbeitung für die Medizin 2003: 6-10 - [c3]Ren Hui Gong, Stefan Wörz, Karl Rohr:
Segmentation of Coronary Arteries of the Human Heart from 3D Medical Images. Bildverarbeitung für die Medizin 2003: 66-70 - [c2]Stefan Wörz, Karl Rohr:
3D Parametric Intensity Models for the Localization of Different Types of 3D Anatomical Point Landmarks in Tomographic Images. DAGM-Symposium 2003: 220-227 - [c1]Stefan Wörz, Karl Rohr:
Localization of Anatomical Point Landmarks in 3D Medical Images by Fitting 3D Parametric Intensity Models. IPMI 2003: 76-88
Coauthor Index
[j14] [j13] [c64] [c63] [c62] [j12] [j11] [c61] [c60] [c59] [j10] [c58] [c57] [c55] [c54] [c53] [c52] [c51] [j9] [c50] [c49] [c48] [c47] [c46] [c45] [c44] [c43] [c42] [c41] [j8] [j7] [c40] [c39] [c38] [j6] [c37] [c36] [c35] [c34] [c33] [c32] [c31] [c30] [c29] [c28] [j5] [j4] [c27] [c26] [c25] [c24] [c23] [c22] [j3] [c21] [c20] [c19] [c18] [c17] [c16] [j2] [c15] [c14] [c13] [c12] [c11] [c10] [j1] [c9] [c8] [c7] [c6] [c5] [c4] [c3] [c2] [c1]
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