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Michael Grass 0001
Person information
- affiliation: Philips Technologie GmbH, Hamburg, Germany
- affiliation (PHD): University of Osnabrück, Germany
Other persons with the same name
- Michael Grass (aka: Michael Graß) — disambiguation page
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2020 – today
- 2021
- [c26]Nikolas Schnellbächer, Haissam Ragab, Hannes Nickisch
, Tobias Wissel, Clemens Spink, Gunnar Lund, Michael Grass:
Machine-learning-based clinical plaque detection using a synthetic plaque lesion model for coronary CTA. Medical Imaging: Computer-Aided Diagnosis 2021 - [c25]Lennart Bargsten
Attention via Scattering Transforms for Segmentation of Small Intravascular Ultrasound Data Sets. MIDL 2021: 34-47 - [c24]Tobias Wissel, Katharina A. Riedl
Delineation of coronary stents in intravascular ultrasound pullbacks. Medical Imaging: Image-Guided Procedures 2021 - 2020
- [j18]Tanja Lossau, Hannes Nickisch
Learning metal artifact reduction in cardiac CT images with moving pacemakers. Medical Image Anal. 61: 101655 (2020) - [i3]Ivo M. Baltruschat, Leonhard Steinmeister, Hannes Nickisch, Axel Saalbach, Michael Grass, Gerhard Adam, Harald Ittrich, Tobias Knopp:
Intelligent Chest X-ray Worklist Prioritization by CNNs: A Clinical Workflow Simulation. CoRR abs/2001.08625 (2020)
2010 – 2019
- 2019
- [j17]Tanja Lossau, Hannes Nickisch
Motion estimation and correction in cardiac CT angiography images using convolutional neural networks. Comput. Medical Imaging Graph. 76 (2019) - [j16]Tanja Lossau, Hannes Nickisch
Motion artifact recognition and quantification in coronary CT angiography using convolutional neural networks. Medical Image Anal. 52: 68-79 (2019) - [c23]Ivo M. Baltruschat, Leonhard Steinmeister, Harald Ittrich, Gerhard Adam, Hannes Nickisch, Axel Saalbach, Jens von Berg, Michael Grass, Tobias Knopp:
Abstract: Does Bone Suppression and Lung Detection Improve Chest Disease Classification? Bildverarbeitung für die Medizin 2019: 184 - [c22]Ivo M. Baltruschat, Leonhard Steinmeister, Harald Ittrich, Gerhard Adam, Hannes Nickisch
When Does Bone Suppression And Lung Field Segmentation Improve Chest X-Ray Disease Classification? ISBI 2019: 1362-1366 - [c21]Tanja Lossau, Hannes Nickisch, Tobias Wissel, Samer Hakmi, Clemens Spink, Michael M. Morlock, Michael Grass:
Dynamic Pacemaker Artifact Removal (DyPAR) from CT Data using CNNs. MIDL 2019: 347-357 - 2018
- [c20]Tanja Elss, Hannes Nickisch, Tobias Wissel, Holger Schmitt, Mani Vembar, Michael M. Morlock, Michael Grass:
Deep-learning-based CT motion artifact recognition in coronary arteries. Medical Imaging: Image Processing 2018: 1057416 - [i2]Ivo M. Baltruschat, Hannes Nickisch, Michael Grass, Tobias Knopp, Axel Saalbach:
Comparison of Deep Learning Approaches for Multi-Label Chest X-Ray Classification. CoRR abs/1803.02315 (2018) - [i1]Ivo M. Baltruschat, Leonhard Steinmeister, Harald Ittrich, Gerhard Adam, Hannes Nickisch, Axel Saalbach, Jens von Berg, Michael Grass, Tobias Knopp:
When does Bone Suppression and Lung Field Segmentation Improve Chest X-Ray Disease Classification? CoRR abs/1810.07500 (2018) - 2017
- [c19]Christian Buerger, Cristian Lorenz, Drazenko Babic, Jürgen Hoppenbrouwers, Robert Homan, Rami Nachabe, John M. Racadio, Michael Grass:
Spine segmentation from C-arm CT data sets: application to region-of-interest volumes for spinal interventions. Medical Imaging: Image-Guided Procedures 2017: 101351N - 2016
- [j15]Serkan Çimen, Ali Gooya
Reconstruction of coronary arteries from X-ray angiography: A review. Medical Image Anal. 32: 46-68 (2016) - 2014
- [j14]Christian Haase, Dirk Schäfer, Olaf Dössel
Model based 3D CS-catheter tracking from 2D X-ray projections: Binary versus attenuation models. Comput. Medical Imaging Graph. 38(3): 224-231 (2014) - 2013
- [c18]Eberhard Hansis, Alessandro Radaelli, Niels J. Noordhoek, Cristian Lorenz, Michael Grass:
Automatic bone removal for 3D liver tace planning with C-arm CT. ISBI 2013: 1408-1411 - 2012
- [j13]Alfonso A. Isola, Coert Metz, Michiel Schaap, Stefan Klein
Cardiac motion-corrected iterative cone-beam CT reconstruction using a semi-automatic minimum cost path-based coronary centerline extraction. Comput. Medical Imaging Graph. 36(3): 215-226 (2012) - [c17]Cyril Mory, Bo Zhang, Vincent Auvray, Michael Grass, Dirk Schäfer, Françoise Peyrin, Simon Rit, Philippe Douek, Loïc Boussel:
ECG-gated C-arm computed tomography using L1 regularization. EUSIPCO 2012: 2728-2732 - [c16]Cristian Lorenz, Dirk Schäfer, Peter Eshuis, John D. Carroll, Michael Grass:
Automated volume of interest delineation and rendering of cone beam CT images in interventional cardiology. Medical Imaging: Image-Guided Procedures 2012: 831606 - 2010
- [j12]Jingying Bi, Michael Grass, Dirk Schäfer:
Optimization of acquisition trajectories for 3D rotational coronary venography. Int. J. Comput. Assist. Radiol. Surg. 5(1): 19-28 (2010) - [j11]Alfonso A. Isola, A. Ziegler, Dirk Schäfer, Thomas Köhler, Wiro J. Niessen
Motion compensated iterative reconstruction of a region of interest in cardiac cone-beam CT. Comput. Medical Imaging Graph. 34(2): 149-159 (2010) - [c15]Anne M. Neubauer, Eberhard Hansis, John D. Carroll, Michael Grass:
Artifact reduction method for improved visualization of 3D coronary artery reconstructions from rotational angiography acquisitions. Medical Imaging: Image-Guided Procedures 2010: 76250A
2000 – 2009
- 2009
- [j10]Carsten Oliver Schirra, Claas Bontus, Udo van Stevendaal, Olaf Dössel
Improvement of cardiac CT reconstruction using local motion vector fields. Comput. Medical Imaging Graph. 33(2): 122-130 (2009) - [j9]Uwe Jandt, Dirk Schäfer, Michael Grass, Volker Rasche
Automatic generation of 3D coronary artery centerlines using rotational X-ray angiography. Medical Image Anal. 13(6): 846-858 (2009) - [c14]Jochen Peters, Olivier Ecabert, Holger Schmitt, Michael Grass, Jürgen Weese:
Local Cardiac Wall Motion Estimation from Retrospectively Gated CT Images. FIMH 2009: 191-200 - 2008
- [j8]Eberhard Hansis, Dirk Schäfer, Olaf Dössel
Automatic optimum phase point selection based on centerline consistency for 3D rotational coronary angiography. Int. J. Comput. Assist. Radiol. Surg. 3(3-4): 355-361 (2008) - [j7]Eberhard Hansis, Dirk Schäfer, Olaf Dössel
Evaluation of Iterative Sparse Object Reconstruction From Few Projections for 3-D Rotational Coronary Angiography. IEEE Trans. Medical Imaging 27(11): 1548-1555 (2008) - 2007
- [c13]Babak Movassaghi, Michael Grass, Dirk Schäfer, Volker Rasche
4D coronary artery reconstruction based on retrospectively gated rotational angiography: first in-human results. Medical Imaging: Image-Guided Procedures 2007: 65090P - [c12]Dirk Schäfer, Babak Movassaghi, Michael Grass, Gert Schoonenberg, Raoul Florent, Onno Wink, Andrew J. P. Klein, James Y. Chen, Joel A. Garcia, John C. Messenger, John D. Carroll:
Three-dimensional reconstruction of coronary stents in vivo based on motion compensated x-ray angiography. Medical Imaging: Image-Guided Procedures 2007: 65091M - 2006
- [j6]Dirk Schäfer, Jörn Borgert, Volker Rasche
Motion-Compensated and Gated Cone Beam Filtered Back-Projection for 3-D Rotational X-Ray Angiography. IEEE Trans. Medical Imaging 25(7): 898-906 (2006) - [c11]Babak Movassaghi, Dirk Schäfer, Michael Grass, Volker Rasche, Onno Wink, Joel A. Garcia, James Y. Chen, John C. Messenger, John D. Carroll:
3D Reconstruction of Coronary Stents in Vivo Based on Motion Compensated X-Ray Angiograms. MICCAI (2) 2006: 177-184 - 2004
- [j5]Robert Manzke, Michael Grass, David J. Hawkes:
Artifact analysis and reconstruction improvement in helical cardiac cone beam CT. IEEE Trans. Medical Imaging 23(9): 1150-1164 (2004) - [j4]Babak Movassaghi, Volker Rasche
A quantitative analysis of 3-D coronary modeling from two or more projection images. IEEE Trans. Medical Imaging 23(12): 1517-1531 (2004) - [c10]Volker Rasche, Babak Movassaghi, Michael Grass:
Automatic gating window selection for gated three-dimensional coronary X-ray angiography. CARS 2004: 1050-1054 - [c9]Holger Schmitt, Michael Grass, Thomas Köhler, R. Suurmond, Volker Rasche, S. Hähnel, S. Heiland:
A linear programming framework for blood flow reconstruction in cerebral vessel trees. CARS 2004: 1061-1066 - [c8]Robert Manzke, Michael Grass, Tim Nielsen, Thomas Köhler, David J. Hawkes:
Automatic phase point determination for cardiac CT imaging. Medical Imaging: Image Processing 2004 - [c7]Tim Nielsen, Robert Manzke, Thomas Köhler, Michael Grass, Roland Proksa:
Iterative cardiac cone-beam CT reconstruction. Medical Imaging: Image Processing 2004 - [c6]Udo van Stevendaal, Philipp G. C. Begemann, Jörn Borgert, Rüdiger Grewer, Sascha Krüger, Holger Timinger
Determination of the temporal and spatial resolution in retrospectively gated cardiac cone-beam CT. Medical Imaging: Image Processing 2004 - 2003
- [j3]Tobias Schaeffter
Real-Time Adaptive Filtering for Projection Reconstruction MR-Fluoroscopy. IEEE Trans. Medical Imaging 22(1): 75-81 (2003) - [c5]Volker Rasche, B. Schreiber, C. Graeff, Thomas Istel, Hermann Schomberg, Michael Grass, Reiner Koppe, Erhard Klotz, Georg Rose:
Perfomance of image-intensifier equipped X-ray systems for-three-dimensional imaging. CARS 2003: 187-192 - [c4]Gilad Shechter, Galit Naveh, Ami Altman, Roland M. Proksa, Michael Grass:
Cardiac image reconstruction on a 16-slice CT scanner using a retrospectively ECG-gated multicycle 3D back-projection algorithm. Medical Imaging: Image Processing 2003 - [c3]Udo van Stevendaal, Jens-Peter Schlomka, Michael Grass:
Filtered back-projection reconstruction technique for coherent-scatter computer tomography. Medical Imaging: Image Processing 2003 - 2002
- [j2]Holger Schmitt, Michael Grass, Volker Rasche
An x-ray based method for the determination of the contrast agent propagation in 3D vessel structures. IEEE Trans. Medical Imaging 21(3): 251-262 (2002) - [c2]Joern Luetjens, Reiner Koppe, Erhard Klotz, Michael Grass, Volker Rasche
Three-dimensional imaging using low-end C-arm systems. Medical Imaging: Image Processing 2002 - 2001
- [c1]Michael Graß, Holger Schmitt, Volker Rasche, S. Hähnel, Oliver Schramm, M. Hartmann, K. Sartor:
A method for 3D flow determination based on X-ray rotational angiography. CARS 2001: 408-414 - 2000
- [j1]Roland Proksa, Thomas Köhler, Michael Grass, J. Timmer:
The n-PI method for helical cone-beam CT. IEEE Trans. Medical Imaging 19(9): 848-863 (2000)
Coauthor Index
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