Table of Contents

Paper

Year:
Primary Author:
Topic:

WithTeeth: Denture Preview in Augmented Reality
Amirkhanov Aleksandr, Amirkhanov Artem, Bernhard Matthias, Toth Zsolt, Stiller Sabine, Geier Andreas, Gröller Eduard, Mistelbauer Gabriel
Vision Modeling and Visualization, pp. 29-338, 2018
BIBTeX
@InProceedings{v.20181250,
author = {Amirkhanov, Aleksandr and Amirkhanov, Artem and Bernhard, Matthias and Toth, Zsolt and Stiller, Sabine and Geier, Andreas and Gröller, Eduard and Mistelbauer, Gabriel},
title = {{WithTeeth: Denture Preview in Augmented Reality}},
booktitle = {Vision, Modeling and Visualization},
year = {2018},
editor = {Beck, Fabian and Dachsbacher, Carsten and Sadlo, Filip},
pages = {29-338},
publisher = {The Eurographics Association},
doi = {10.2312/vmv.20181250},
isbn = {978-3-03868-072-7},
}
Real-World Variability in the Prediction of Intracranial Aneurysm Wall Shear Stress: The 2015 International Aneurysm CFD Challenge
Valen-Sendstad Kristian, Bergersen Aslak W., Shimogonya Yuji, Goubergrits Leonid, Bruening Jan, Pallares Jordi, Cito Salvatore, Piskin Senol, Pekkan Kerem, Geers Arjan J., Larrabide Ignacio, Rapaka Saikiran, Mihalef Viorel, Fu Wenyu, Qiao Aike, Jain Kartik, Roller Sabine, Mardal Kent-Andre, Kamakoti Ramji, Spirka Thomas, Ashton Neil, Revell Alistair, Aristokleous Nicolas, Houston J. Graeme, Tsuji Masanori, Ishida Fujimaro, Menon Prahlad G., Browne Leonard D., Broderick Stephen, Shojima Masaaki, Koizumi Satoshi, Barbour Michael, Aliseda Alberto, Morales Hern\ an G., Lef\ evre Thierry, Hodis Simona, Al-Smadi Yahia M., Tran Justin S., Marsden Alison L., Vaippummadhom Sreeja, Einstein G. Albert, Brown Alistair G., Debus Kristian, Niizuma Kuniyasu, Rashad Sherif, Sugiyama Shin-ichiro, Owais Khan M., Updegrove Adam R., Shadden Shawn C., Cornelissen Bart M. W., Majoie Charles B. L. M., Berg Philipp, Saalfield Sylvia, Kono Kenichi, Steinman David A.
Cardiovascular Engineering and Technology, 9, pp. 544-564, 2018
BIBTeX
@Article{Valen-Sendstad_2018_Real,
author = {Valen-Sendstad, Kristian and Bergersen, Aslak W. and Shimogonya, Yuji and Goubergrits, Leonid and Bruening, Jan and Pallares, Jordi and Cito, Salvatore and Piskin, Senol and Pekkan, Kerem and Geers, Arjan J. and Larrabide, Ignacio and Rapaka, Saikiran and Mihalef, Viorel and Fu, Wenyu and Qiao, Aike and Jain, Kartik and Roller, Sabine and Mardal, Kent-Andre and Kamakoti, Ramji and Spirka, Thomas and Ashton, Neil and Revell, Alistair and Aristokleous, Nicolas and Houston, J. Graeme and Tsuji, Masanori and Ishida, Fujimaro and Menon, Prahlad G. and Browne, Leonard D. and Broderick, Stephen and Shojima, Masaaki and Koizumi, Satoshi and Barbour, Michael and Aliseda, Alberto and Morales, Hern{\`a}n G. and Lef{\`e}vre, Thierry and Hodis, Simona and Al-Smadi, Yahia M. and Tran, Justin S. and Marsden, Alison L. and Vaippummadhom, Sreeja and Einstein, G. Albert and Brown, Alistair G. and Debus, Kristian and Niizuma, Kuniyasu and Rashad, Sherif and Sugiyama, Shin-ichiro and Owais Khan, M. and Updegrove, Adam R. and Shadden, Shawn C. and Cornelissen, Bart M. W. and Majoie, Charles B. L. M. and Berg, Philipp and Saalfield, Sylvia and Kono, Kenichi and Steinman, David A.},
title = {{Real-World Variability in the Prediction of Intracranial Aneurysm Wall Shear Stress: The 2015 International Aneurysm CFD Challenge}},
journal = {Cardiovascular Engineering and Technology},
year = {2018},
volume = {9},
number = {4},
pages = {544--564},
month = {Dec},
issn = {1869-4098},
abstract = {Image-based computational fluid dynamics (CFD) is widely used to predict intracranial aneurysm wall shear stress (WSS), particularly with the goal of improving rupture risk assessment. Nevertheless, concern has been expressed over the variability of predicted WSS and inconsistent associations with rupture. Previous challenges, and studies from individual groups, have focused on individual aspects of the image-based CFD pipeline. The aim of this Challenge was to quantify the total variability of the whole pipeline.},
day = {01},
doi = {10.1007/s13239-018-00374-2},
url = {https://doi.org/10.1007/s13239-018-00374-2},
}
Berg Philipp, Voss Samuel, Saalfeld Sylvia, Janiga Gábor, Bergersen Aslak W., Valen-Sendstad Kristian, Bruening Jan, Goubergrits Leonid, Spuler Andreas, Cancelliere Nicole M., Steinman David A., Pereira Vitor M., Chiu Tin Lok, Tsang Anderson Chun On, Chung Bong Jae, Cebral Juan R., Cito Salvatore, Pallarés Jordi, Copelli Gabriele, Csippa Benjamin, Paál György, Fujimura Soichiro, Takao Hiroyuki, Hodis Simona, Hille Georg, Karmonik Christof, Elias Saba, Kellermann Kerstin, Khan Muhammad Owais, Marsden Alison L., Morales Hernán G., Piskin Senol, Finol Ender A., Pravdivtseva Mariya, Rajabzadeh-Oghaz Hamidreza, Paliwal Nikhil, Meng Hui, Seshadhri Santhosh, Howard Matthew, Shojima Masaaki, Sugiyama Shin-ichiro, Niizuma Kuniyasu, Sindeev Sergey, Frolov Sergey, Wagner Thomas, Brawanski Alexander, Qian Yi, Wu Yu-An, Carlson Kent D., Dragomir-Daescu Dan, Beuing Oliver
Cardiovascular Engineering and Technology, , in print, 2018
BIBTeX
@Article{Berg_2018_MATCH,
author = {Berg, Philipp and Voss, Samuel and Saalfeld, Sylvia and Janiga, Gábor and Bergersen, Aslak W. and Valen-Sendstad, Kristian and Bruening, Jan and Goubergrits, Leonid and Spuler, Andreas and Cancelliere, Nicole M. and Steinman, David A. and Pereira, Vitor M. and Chiu, Tin Lok and Tsang, Anderson Chun On and Chung, Bong Jae and Cebral, Juan R. and Cito, Salvatore and Pallarés, Jordi and Copelli, Gabriele and Csippa, Benjamin and Paál, György and Fujimura, Soichiro and Takao, Hiroyuki and Hodis, Simona and Hille, Georg and Karmonik, Christof and Elias, Saba and Kellermann, Kerstin and Khan, Muhammad Owais and Marsden, Alison L. and Morales, Hernán G. and Piskin, Senol and Finol, Ender A. and Pravdivtseva, Mariya and Rajabzadeh-Oghaz, Hamidreza and Paliwal, Nikhil and Meng, Hui and Seshadhri, Santhosh and Howard, Matthew and Shojima, Masaaki and Sugiyama, Shin-ichiro and Niizuma, Kuniyasu and Sindeev, Sergey and Frolov, Sergey and Wagner, Thomas and Brawanski, Alexander and Qian, Yi and Wu, Yu-An and Carlson, Kent D. and Dragomir-Daescu, Dan and Beuing, Oliver},
title = {{Multiple Aneurysms AnaTomy CHallenge 2018 (MATCH): Phase I: Segmentation}},
journal = {Cardiovascular Engineering and Technology},
year = {2018},
month = {Sep},
issn = {1869-4098},
abstract = {Advanced morphology analysis and image-based hemodynamic simulations are increasingly used to assess the rupture risk of intracranial aneurysms (IAs). However, the accuracy of those results strongly depends on the quality of the vessel wall segmentation.},
day = {06},
doi = {10.1007/s13239-018-00376-0},
url = {https://doi.org/10.1007/s13239-018-00376-0},
}
Fluid-structure interaction in intracranial vessel walls: The role of patient-specific wall thickness
Voß Samuel, Saalfeld Sylvia, Hoffmann Thomas, Beuing Oliver, Janiga Gábor, Berg Philipp
Current Directions in Biomedical Engineering, 4, pp. 587-590, 2018
BIBTeX
@Article{article,
author = {Voß, Samuel and Saalfeld, Sylvia and Hoffmann, Thomas and Beuing, Oliver and Janiga, Gábor and Berg, Philipp},
title = {Fluid-structure interaction in intracranial vessel walls: The role of patient-specific wall thickness},
journal = {Current Directions in Biomedical Engineering},
year = {2018},
volume = {4},
pages = {587-590},
month = {09},
doi = {10.1515/cdbme-2018-0141},
}
Saalfeld Sylvia, Berg Philipp, Niemann Annika, Luz Maria, Preim Bernhard, Beuing Oliver
International Journal of Computer Assisted Radiology and Surgery, 13, pp. 1781-1793, 2018
BIBTeX
@Article{Saalfeld_2018_IJCARS,
author = {Saalfeld, Sylvia and Berg, Philipp and Niemann, Annika and Luz, Maria and Preim, Bernhard and Beuing, Oliver},
title = {{Semiautomatic neck curve reconstruction for intracranial aneurysm rupture risk assessment based on morphological parameters}},
journal = {International Journal of Computer Assisted Radiology and Surgery},
year = {2018},
volume = {13},
number = {11},
pages = {1781--1793},
month = {Nov},
issn = {1861-6429},
abstract = {Morphological parameters of intracranial aneurysms (IAs) are well established for rupture risk assessment. However, a manual measurement is error-prone, not reproducible and cumbersome. For an automatic extraction of morphological parameters, a 3D neck curve reconstruction approach to delineate the aneurysm from the parent vessel is required.},
day = {01},
doi = {10.1007/s11548-018-1848-x},
url = {https://doi.org/10.1007/s11548-018-1848-x},
}
Benjamin Behrendt, Sebastian Ebel, Matthias Gutberlet, Bernhard Preim
Eurographics Workshop on Visual Computing for Biology and Medicine, in print, 2018
BIBTeX
@InProceedings{Behrendt_2018_VCBM,
author = {Benjamin Behrendt and Sebastian Ebel and Matthias Gutberlet and Bernhard Preim},
title = {{A Framework for Visual Comparison of 4D PC-MRI Aortic Blood Flow Data}},
booktitle = {Eurographics Workshop on Visual Computing for Biology and Medicine},
year = {2018},
editor = {Puig Puig, Anna and Schultz, Thomas and Vilanova, Anna and Hotz, Ingrid and Kozlikova, Barbora and Vázquez, Pere-Pau},
publisher = {The Eurographics Association},
doi = {10.2312/vcbm.20181236},
isbn = {978-3-03868-056-7},
issn = {2070-5786},
}
Benjamin Behrendt, Philipp Berg, Oliver Beuing, Bernhard Preim, Sylvia Saalfeld
Computer Graphics Forum, 37, pp. 183-194, 2018
BIBTeX
Media
@Article{Behrendt_2018_EuroVIS,
Title = {{Explorative Blood Flow Visualization using Dynamic Line Filtering based on Surface Features}},
Author = {Benjamin Behrendt and Philipp Berg and Oliver Beuing and Bernhard Preim and Sylvia Saalfeld},
Journal = {Computer Graphics Forum},
Year = {2018},
Number = {3},
Pages = {183-194},
Volume = {37},
Doi = {10.1111/cgf.13411},
ISSN = {1467-8659},
Publisher = {The Eurographics Association and John Wiley \& Sons Ltd.}
}
Explorative Blood Flow Vis. using Dynamic Surface-based Filtering
Does the DSA reconstruction kernel affect hemodynamic predictions in intracranial aneurysms? An analysis of geometry and blood flow variations
Philipp Berg, Sylvia Saalfeld, Samuel Voß, T. Redel, Bernhard Preim, Gabor Janiga, Oliver Beuing
Journal of NeuroInterventional Surgery, 10, pp. 290-296, 2018
BIBTeX
@Article{Berg_2018_JoNS,
author = {Philipp Berg and Sylvia Saalfeld and Samuel Voß and T. Redel and Bernhard Preim and Gabor Janiga and Oliver Beuing},
title = {Does the DSA reconstruction kernel affect hemodynamic predictions in intracranial aneurysms? An analysis of geometry and blood flow variations},
journal = {Journal of NeuroInterventional Surgery},
year = {2018},
volume = {10},
number = {3},
pages = {290--296},
issn = {1759-8478},
abstract = {Background Computational fluid dynamics (CFD) blood flow predictions in intracranial aneurysms promise great potential to reveal patient-specific flow structures. Since the workflow from image acquisition to the final result includes various processing steps, quantifications of the individual introduced potential error sources are required.Methods Three-dimensional (3D) reconstruction of the acquired imaging data as input to 3D model generation was evaluated. Six different reconstruction modes for 3D digital subtraction angiography (DSA) acquisitions were applied to eight patient-specific aneurysms. Segmentations were extracted to compare the 3D luminal surfaces. Time-dependent CFD simulations were carried out in all 48 configurations to assess the velocity and wall shear stress (WSS) variability due to the choice of reconstruction kernel.Results All kernels yielded good segmentation agreement in the parent artery; deviations of the luminal surface were present at the aneurysm neck (up to 34.18\%) and in distal or perforating arteries. Observations included pseudostenoses as well as noisy surfaces, depending on the selected reconstruction kernel. Consequently, the hemodynamic predictions show a mean SD of 11.09\% for the aneurysm neck inflow rate, 5.07\% for the centerline-based velocity magnitude, and 17.83\%/9.53\% for the mean/max aneurysmal WSS, respectively. In particular, vessel sections distal to the aneurysms yielded stronger variations of the CFD values.Conclusions The choice of reconstruction kernel for DSA data influences the segmentation result, especially for small arteries. Therefore, if precise morphology measurements or blood flow descriptions are desired, a specific reconstruction setting is required. Furthermore, research groups should be encouraged to denominate the kernel types used in future hemodynamic studies.},
doi = {10.1136/neurintsurg-2017-012996},
eprint = {https://jnis.bmj.com/content/10/3/290.full.pdf},
publisher = {British Medical Journal Publishing Group},
url = {https://jnis.bmj.com/content/10/3/290},
}
Philipp Berg, Livia Radtke, Samuel Voß, Steffen Serowy, Gabor Janiga, Bernhard Preim, Oliver Beuing, Sylvia Saalfeld
40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), in print, 2018
BIBTeX
@InProceedings{Berg_2018_EMBC,
Title = {{3DRA Reconstruction of Intracranial Aneurysms - How Does Voxel Size Influences Morphologic and Hemodynamic Parameters}},
Author = {Philipp Berg and Livia Radtke and Samuel Voß and Steffen Serowy and Gabor Janiga and Bernhard Preim and Oliver Beuing and Sylvia Saalfeld},
Booktitle = {{40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)}},
Year = {2018}
}
Virtual stenting of intracranial aneurysms: A pilot study for the prediction of treatment success based on hemodynamic simulations
Philipp Berg, Sylvia Saalfeld, Gábor Janiga, Olivier Brina, Nicole M Cancelliere, Paolo Machi, Vitor M Pereira
The International Journal of Artificial Organs, 41, pp. 698-705, 2018
BIBTeX
@Article{Berg_2018_VirtualStenting,
author = {Philipp Berg and Sylvia Saalfeld and Gábor Janiga and Olivier Brina and Nicole M Cancelliere and Paolo Machi and Vitor M Pereira},
title = {{Virtual stenting of intracranial aneurysms: A pilot study for the prediction of treatment success based on hemodynamic simulations}},
journal = {The International Journal of Artificial Organs},
year = {2018},
volume = {41},
number = {11},
pages = {698-705},
note = {PMID: 29783867},
abstract = { Endovascular treatment of intracranial aneurysms using flow-diverting devices has revolutionized the treatment of large and complex lesions due to its minimally invasive nature and potential clinical outcomes. However, incomplete or delayed occlusion and persistent intracranial aneurysm growth are still an issue for up to one-third of the patients. We evaluated two patients with intracranial aneurysm located at the internal carotid artery who were treated with flow-diverting devices and had opposite outcomes. Both patients presented with similar aneurysms and were treated with the same device, but after a 1-year follow-up, one case presented with complete occlusion (Case 1) and the other required further treatment (Case 2). To reproduce the interventions, virtual stents were deployed and blood flow simulations were carried out using the respective patient-specific geometries. Afterward, hemodynamic metrics such as aneurysmal inflow reduction, wall shear stresses, oscillatory shear, and inflow concentration indices were quantified. The hemodynamic simulations reveal that for both cases, the neck inflow was clearly reduced due to the therapy (Case 1: 19\%, Case 2: 35\%). In addition, relevant hemodynamic parameters such as time-averaged wall shear stress (Case 1: 35.6\%, Case 2: 57\%) and oscillatory shear (Case 1: 33.1\%, Case 2: 26.7\%) were decreased considerably. However, although stronger relative reductions occurred in the unsuccessful case, the absolute flow values in the successful case were approximately halved. The findings demonstrate that a high relative effect of endovascular devices is not necessarily associated with the desired treatment outcome. Instead, it appears that a successful intracranial aneurysm therapy requires a certain patient-specific inflow threshold. },
doi = {10.1177/0391398818775521},
eprint = {https://doi.org/10.1177/0391398818775521},
url = {
https://doi.org/10.1177/0391398818775521
},
}
Improving Surgical Training Phantoms by Hyperrealism: Deep Unpaired Image-to-Image Translation from Real Surgeries
Sandy Engelhardt, Raffaele De Simone, Peter M. Full, Matthias Karck, Ivo Wolf
International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI), in print, 2018
BIBTeX
@InProceedings{Engelhardt_2018_MICCAI,
Title = {{Improving Surgical Training Phantoms by Hyperrealism: Deep Unpaired Image-to-Image Translation from Real Surgeries}},
Author = {Sandy Engelhardt and Raffaele De Simone and Peter M. Full and Matthias Karck and Ivo Wolf},
Booktitle = {{International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI)}},
Year = {2018}
}
Sandy Engelhardt, Simon Sauerzapf, Sameer Al-Maisary, Matthias Karck, Bernhard Preim, Ivo Wolf, Raffaele De Simone
Bildverarbeitung für die Medizin (BVM), pp. 74-79, 2018
BIBTeX
@InProceedings{Engelhardt_2018_BVM,
Title = {{Elastic Mitral Valve Silicone Replica Made from 3D-Printable Molds Offer Advanced Surgical Training}},
Author = {Sandy Engelhardt and Simon Sauerzapf and Sameer Al-Maisary and Matthias Karck and Bernhard Preim and Ivo Wolf and Raffaele De Simone},
Booktitle = {Bildverarbeitung für die Medizin (BVM)},
Year = {2018},
Address = {Erlangen},
Month = {März},
Pages = {74--79},
Publisher = {Springer Verlag}
}
Wito Engelke, Kai Lawonn, Bernhard Preim, Ingrid Hotz
Computer Graphics Forum, , in print, 2018
BIBTeX
@Article{Engelke_2018_CGF,
Title = {{Autonomous Particles for Interactive Flow Visualization}},
Author = {Wito Engelke and Kai Lawonn and Bernhard Preim and Ingrid Hotz},
Journal = {Computer Graphics Forum},
Year = {2018},
Pages = {to appear}
}
Mickaël Francisco Sereno, Benjamin Köhler, Bernhard Preim
Bildverarbeitung für die Medizin (BVM), pp. 139-144, 2018
BIBTeX
@InProceedings{Sereno_2018_BVM,
Title = {{Comparison of Divergence-Free Filters for Cardiac 4D PC-MRI Data}},
Author = {Mickaël Francisco Sereno and Benjamin Köhler and Bernhard Preim},
Booktitle = {Bildverarbeitung für die Medizin (BVM)},
Year = {2018},
Address = {Erlangen},
Month = {März},
Pages = {139--144},
Publisher = {Springer Verlag}
}
Tommy Hielscher, Uli Niemann, Bernhard Preim, Henry Völzke, Till Ittermann, Myra Spiliopoulou
Expert Systems with Applications, 113, pp. 147-160, 2018
BIBTeX
@Article{HIELSCHER2018147,
Title = {A framework for expert-driven subpopulation discovery and evaluation using subspace clustering for epidemiological data},
Author = {Tommy Hielscher and Uli Niemann and Bernhard Preim and Henry Völzke and Till Ittermann and Myra Spiliopoulou},
Journal = {Expert Systems with Applications},
Year = {2018},
Pages = {147 - 160},
Volume = {113},
Doi = {https://doi.org/10.1016/j.eswa.2018.07.003},
ISSN = {0957-4174},
Keywords = {Subpopulation discovery framework, Constraint-based subspace clustering, Cohort study data, Hepatic steatosis, Goiter},
Url = {http://www.sciencedirect.com/science/article/pii/S0957417418304202}
}
Computer-aided Detection of the Most Suitable MRI Sequences for Subsequent Spinal Metastasis Delineation
Georg Hille, Steffen Serowy, Klaus-Dietz Tönnies, Sylvia Saalfeld
Bildverarbeitung für die Medizin (BVM), pp. 275-279, 2018
BIBTeX
@InProceedings{Hille_2018_BVM,
author = {Georg Hille and Steffen Serowy and Klaus-Dietz Tönnies and Sylvia Saalfeld},
title = {{Computer-aided Detection of the Most Suitable MRI Sequences for Subsequent Spinal Metastasis Delineation}},
booktitle = {Bildverarbeitung für die Medizin (BVM)},
year = {2018},
pages = {275--279},
address = {Erlangen},
month = {März},
publisher = {Springer Verlag},
}
Multi-segmental spine image registration supporting image-guided interventions of spinal metastases
Georg Hille, Sylvia Saalfeld, Steffen Serowy, Klaus Tönnies
Computers in Biology and Medicine, 102, pp. 16-20, 2018
BIBTeX
@Article{hille_2018_CBM,
author = {Georg Hille and Sylvia Saalfeld and Steffen Serowy and Klaus Tönnies},
title = {Multi-segmental spine image registration supporting image-guided interventions of spinal metastases},
journal = {Computers in Biology and Medicine},
year = {2018},
volume = {102},
pages = {16--20},
issn = {0010-4825},
abstract = {Background
Radiofrequency ablation was introduced recently to treat spinal metastases, which are among the most common metastases. These minimally-invasive interventions are most often image-guided by flat-panel CT scans, withholding soft tissue contrast like MR imaging. Image fusion of diagnostic MR and operative CT images could provide important and useful information during interventions.
Method
Diagnostic MR and interventional flat-panel CT scans of 19 patients, who underwent radiofrequency ablations of spinal metastases were obtained. Our presented approach piecewise rigidly registers single vertebrae using normalized gradient fields and embeds them within a fused image. Registration accuracy was determined via Euclidean distances between corresponding landmark pairs of ground truth data.
Results
Our method resulted in an average registration error of 2.35mm. An optimal image fusion performed by landmark registrations achieved an average registration error of 1.70mm. Additionally, intra- and inter-reader variability was determined, resulting in mean distances of corresponding landmark pairs of 1.05mm (MRI) and 1.03mm (flat-panel CT) for the intra-reader variability and 1.36mm and 1.28mm for the inter-reader variability, respectively.
Conclusions
Our multi-segmental approach with normalized gradient fields as image similarity measure can handle spine deformations due to patient positioning and avoid time-consuming manually performed registration. Thus, our method can provide practical and applicable intervention support without significantly delaying the clinical workflow or additional workload.},
doi = {https://doi.org/10.1016/j.compbiomed.2018.09.003},
keywords = {Multi-segmental image fusion, Spine intervention, Interventional imaging, Normalized gradient fields, Automatic image registration},
url = {http://www.sciencedirect.com/science/article/pii/S0010482518302592},
}
Georg Hille, Sylvia Saalfeld, Steffen Serowy, Klaus Tönnies
Computer Methods and Programs in Biomedicine, 155, pp. 93-99, 2018
BIBTeX
@Article{HILLE201893,
Title = {Vertebral body segmentation in wide range clinical routine spine MRI data},
Author = {Georg Hille and Sylvia Saalfeld and Steffen Serowy and Klaus Tönnies},
Journal = {Computer Methods and Programs in Biomedicine},
Year = {2018},
Pages = {93 - 99},
Volume = {155},
Doi = {https://doi.org/10.1016/j.cmpb.2017.12.013},
ISSN = {0169-2607},
Keywords = {Clinical spine MRI, Vertebral body, Segmentation, Hybrid level-sets, Various MRI sequences},
Url = {http://www.sciencedirect.com/science/article/pii/S0169260717308271}
}
A Survey of Flattening Based Medical Visualization Techniques
J. Kreiser, M. Meuschke, G. Mistelbauer, B. Preim, T. Ropinski
Computer Graphics Forum, 37 (3), pp. 597-624, 2018
BIBTeX
@Article{Kreiser_2018_CGF,
author = {J. Kreiser and M. Meuschke and G. Mistelbauer and B. Preim and T. Ropinski},
title = {{A Survey of Flattening Based Medical Visualization Techniques}},
journal = {Computer Graphics Forum},
year = {2018},
volume = {37 (3)},
pages = {597--624},
}
Benjamin Köhler, Matthias Grothoff, Matthias Gutberlet, Bernhard Preim
EuroVis 2018: Eurographics / IEEE VGTC Conference on Visualization 2018, in print, 2018
BIBTeX
@InProceedings{Koehler_2018_EuroVIS,
Title = {{Pressure-based vortex extraction in cardiac 4D PC-MRI blood flow data}},
Author = {Benjamin Köhler and Matthias Grothoff and Matthias Gutberlet and Bernhard Preim},
Booktitle = {{EuroVis 2018: Eurographics / IEEE VGTC Conference on Visualization 2018}},
Year = {2018},
Pages = {to appear}
}
Benjamin Köhler, Matthias Grothoff, Matthias Gutberlet, Bernhard Preim
Computer Graphics Forum, 37, pp. 195-204, 2018
BIBTeX
Media
@Article{Koehler_2018_CGF,
Title = {{Visual and Quantitative Analysis of Great Arteries` Blood Flow Jets in Cardiac 4D PC-MRI Data}},
Author = {Benjamin Köhler and Matthias Grothoff and Matthias Gutberlet and Bernhard Preim},
Journal = {Computer Graphics Forum},
Year = {2018},
Number = {3},
Pages = {195-204},
Volume = {37},
Doi = {10.1111/cgf.13412}
}
Blood flow jets in great arteries
Kai Lawonn, Ivan Viola, Bernhard Preim, Tobias Isenberg
Computer Graphics Forum, 37(6), pp. 205-234, 2018
BIBTeX
@Article{Lawonn_2018_CGF,
Title = {{A Survey of Surface-Based Illustrative Rendering for Visualization}},
Author = {Kai Lawonn and Ivan Viola and Bernhard Preim and Tobias Isenberg},
Journal = {Computer Graphics Forum},
Year = {2018},
Pages = {205--234},
Volume = {37(6)}
}
Nico Merten, Kai Lawonn, Philipp Gensecke, Oliver Großer, Bernhard Preim
Bildverarbeitung für die Medizin (BVM), pp. 347-352, 2018
BIBTeX
@InProceedings{Merten_2018_BVM1,
Title = {{Lung Vessel Enhancement in Low-Dose CT Scans - The LANCELOT Method}},
Author = {Nico Merten and Kai Lawonn and Philipp Gensecke and Oliver Großer and Bernhard Preim},
Booktitle = {Bildverarbeitung für die Medizin (BVM)},
Year = {2018},
Address = {Erlangen},
Month = {März},
Pages = {347--352},
Publisher = {Springer Verlag}
}
Nico Merten, Simon Adler, Magnus Hanses, Sylvia Saalfeld, Mathias Becker, Bernhard Preim
Bildverarbeitung für die Medizin (BVM), pp. 55-60, 2018
BIBTeX
@InProceedings{Merten_2018_BVM2,
Title = {{Two-Step Trajectory Visualization for Robot-Assisted Spine Radiofrequency Ablations}},
Author = {Nico Merten and Simon Adler and Magnus Hanses and Sylvia Saalfeld and Mathias Becker and Bernhard Preim},
Booktitle = {Bildverarbeitung für die Medizin (BVM)},
Year = {2018},
Address = {Erlangen},
Month = {März},
Pages = {55--60},
Publisher = {Springer Verlag}
}
Monique Meuschke, Tobias Günther, Ralph Wickenhöfer, Markus Gross, Bernhard Preim, Kai Lawonn
IEEE Computer Graphics and Applications, 38, pp. 58-72, 2018
BIBTeX
Media
@Article{Meuschke2018_CGA,
Title = {{Management of Cerebral Aneurysm Descriptors based on an Automatic Ostium Extraction}},
Author = {Monique Meuschke and Tobias Günther and Ralph Wickenhöfer and Markus Gross and Bernhard Preim and Kai Lawonn},
Journal = {IEEE Computer Graphics and Applications},
Year = {2018},
Number = {3},
Pages = {58--72},
Volume = {38},
Publisher = {IEEE}
}
Management of Cerebral Aneurysm Descriptors based on an Automatic Ostium Detection
Monique Meuschke, Steffen Oeltze-Jafra, Oliver Beuing, Bernhard Preim, Kai Lawonn
IEEE Transactions on Visualization and Computer Graphics, , in print, 2018
BIBTeX
Media
@Article{Meuschke2018_TVCG,
Title = {{Classification of Blood Flow Patterns in Cerebral Aneurysms}},
Author = {Monique Meuschke and Steffen Oeltze-Jafra and Oliver Beuing and Bernhard Preim and Kai Lawonn},
Journal = {IEEE Transactions on Visualization and Computer Graphics},
Year = {2018},
Publisher = {IEEE}
}
Classification of Blood Flow Patterns in Cerebral Aneurysms
Monique Meuschke, Tobias Günther, Ralph Wickenhöfer, Bernhard Preim, Kai Lawonn
IEEE Transactions on Visualization and Computer Graphics (Proceedings of the Scientific Visualization 2018), in print, 2018
BIBTeX
Media
@InProceedings{Meuschke2018_TVCG_VIS,
Title = {{Visual Analysis of Aneurysm Data using Statistical Graphics}},
Author = {Monique Meuschke and Tobias Günther and Ralph Wickenhöfer and Bernhard Preim and Kai Lawonn},
Booktitle = {{IEEE Transactions on Visualization and Computer Graphics (Proceedings of the Scientific Visualization 2018)}},
Year = {2018},
Journal = {IEEE Transactions on Visualization and Computer Graphics (Proceedings of the Scientific Visualization 2018)},
Keywords = {TVCG,d},
Owner = {meuschke},
Timestamp = {2018.08.20}
}
Visual Analysis of Aneurysm Data using Statistical Graphics
Monique Meuschke, Samuel Voß, Bernhard Preim, Kai Lawonn
Computers \& Graphics, 72, pp. 12-25, 2018
BIBTeX
Media
@Article{Meuschke_2018_CG,
Title = {{Exploration of Blood Flow Patterns in Cerebral Aneurysms during the Cardiac Cycle}},
Author = {Monique Meuschke and Samuel Voß and Bernhard Preim and Kai Lawonn},
Journal = {{Computers \& Graphics}},
Year = {2018},
Pages = {12--25},
Volume = {72}
}
Exploration of Blood Flow Patterns in Cerebral Aneurysms during the Cardiac Cycle
Monique Meuschke, Noeska N. Smit, Nils Lichtenberg, Bernhard Preim, Kai Lawonn
Eurographics Workshop on Visual Computing for Biology and Medicine, in print, 2018
BIBTeX
Media
@InProceedings{Meuschke_2018_VCBM,
author = {Monique Meuschke and Noeska N. Smit and Nils Lichtenberg and Bernhard Preim and Kai Lawonn},
title = {{Automatic Generation of Web-Based User Studies to Evaluate Depth Perception in Vascular Surface Visualizations}},
booktitle = {Eurographics Workshop on Visual Computing for Biology and Medicine},
year = {2018},
editor = {Puig Puig, Anna and Schultz, Thomas and Vilanova, Anna and Hotz, Ingrid and Kozlikova, Barbora and Vázquez, Pere-Pau},
publisher = {The Eurographics Association},
doi = {10.2312/vcbm.20181227},
isbn = {978-3-03868-056-7},
issn = {2070-5786},
}
Automatic Generation of Web-Based User Studies to Evaluate Depth Perception in Vascular Surface Visualizations
Gabriel Mistelbauer, Martin Zettwitz, Rüdiger Schernthaner, Dominik Fleischmann, Christian Teutsch, Bernhard Preim
Eurographics Workshop on Visual Computing for Biology and Medicine, in print, 2018
BIBTeX
@InProceedings{Mistelbauer_2018_VCBM,
author = {Gabriel Mistelbauer and Martin Zettwitz and Rüdiger Schernthaner and Dominik Fleischmann and Christian Teutsch and Bernhard Preim},
title = {{Visual Assessment of Vascular Torsion using Ellipse Fitting}},
booktitle = {Eurographics Workshop on Visual Computing for Biology and Medicine},
year = {2018},
editor = {Puig Puig, Anna and Schultz, Thomas and Vilanova, Anna and Hotz, Ingrid and Kozlikova, Barbora and Vázquez, Pere-Pau},
publisher = {The Eurographics Association},
doi = {10.2312/vcbm.20181238},
isbn = {978-3-03868-056-7},
issn = {2070-5786},
}
Classification of Lobular and Ductal Breast Carcinomas by Texture Analysis in DCE-MRI Data
Kai Nie, Gabriel Mistelbauer, Bernhard Preim
Bildverarbeitung für die Medizin (BVM), pp. 67-72, 2018
BIBTeX
@InProceedings{Nie_2018_BVM,
author = {Kai Nie and Gabriel Mistelbauer and Bernhard Preim},
title = {{Classification of Lobular and Ductal Breast Carcinomas by Texture Analysis in DCE-MRI Data}},
booktitle = {Bildverarbeitung für die Medizin (BVM)},
year = {2018},
pages = {67--72},
address = {Erlangen},
month = {März},
publisher = {Springer Verlag},
}
Uli Niemann, Philipp Berg, Annika Niemann, Oliver Beuing, Bernhard Preim, Mira Spiliopoulou, Sylvia Saalfeld
Proc. of the 31th IEEE Int. Symposium on Computer-Based Medical Systems (CBMS18), pp. 48-53, 2018
BIBTeX
@InProceedings{Niemann_2018_CBMS,
Title = {{Rupture Status Classification of Intracranial Aneurysms Using Morphological Parameters}},
Author = {Uli Niemann and Philipp Berg and Annika Niemann and Oliver Beuing and Bernhard Preim and Mira Spiliopoulou and Sylvia Saalfeld},
Booktitle = {Proc. of the 31th IEEE Int. Symposium on Computer-Based Medical Systems (CBMS18)},
Year = {2018},
Month = jun,
Pages = {48-53},
Doi = {10.1109/CBMS.2018.00016}
}
S. Oeltze-Jafra, M. Meuschke, M. Neugebauer, S. Saalfeld, K. Lawonn, G. Janiga, H.-C. Hege, S. Zachow, B. Preim
Computer Graphics Forum, , in print, 2018
BIBTeX
@Article{Oeltze_2018_EuroVis,
author = {S. Oeltze-Jafra and M. Meuschke and M. Neugebauer and S. Saalfeld and K. Lawonn and G. Janiga and H.-C. Hege and S. Zachow and B. Preim},
title = {{Generation and Visual Exploration of Medical Flow Data: Survey, Research Trends and Future Challenges}},
journal = {Computer Graphics Forum},
year = {2018},
pages = {to appear},
}
Bernhard Preim, Patrick Saalfeld
Computers \& Graphics, 71, pp. 132-153, 2018
BIBTeX
@Article{Preim_2018_CG,
Title = {{A Survey of Virtual Human Anatomy Education Systems}},
Author = {Bernhard Preim and Patrick Saalfeld},
Journal = {Computers \& Graphics},
Year = {2018},
Pages = {132--153},
Volume = {71},
Owner = {saalfeld}
}
Bernhard Preim, Timo Ropinski, Petra Isenberg
Proc. of Eurographics Workshop on Visual Computing for Biology and Medicine (EG VCBM), in print, 2018
BIBTeX
@InProceedings{Preim_2018_VCBM,
Title = {{A Critical Analysis of the Evaluation Practice in Medical Visualization}},
Author = {Bernhard Preim and Timo Ropinski and Petra Isenberg},
Booktitle = {{Proc. of Eurographics Workshop on Visual Computing for Biology and Medicine (EG VCBM)}},
Year = {2018}
}
Popup-Plots: Warping Temporal Data Visualization
J. Schmidt, D. Fleischmann, B. Preim, N. Brandle, G. Mistelbauer
IEEE Transactions on Visualization and Computer Graphics, , pp. 1-1, 2018
BIBTeX
@Article{Schmidt_2018_TVCG,
author = {J. Schmidt and D. Fleischmann and B. Preim and N. Brandle and G. Mistelbauer},
title = {Popup-Plots: Warping Temporal Data Visualization},
journal = {IEEE Transactions on Visualization and Computer Graphics},
year = {2018},
pages = {1--1},
issn = {1077-2626},
doi = {10.1109/TVCG.2018.2841385},
keywords = {Data visualization;Three-dimensional displays;Two dimensional displays;Temperature measurement;Time measurement;Layout;Temporal data;time-dependent visualization;3D plots;ellipsoidal coordinate system},
}
Samuel Voss, Sylvia Saalfeld, Thomas Hoffmann, Gabor Janiga, Oliver Beuing, Philipp Berg
Current Directions in Biomedical Engineering, 4(1), pp. 587-590, 2018
BIBTeX
@Article{Voss_2018_Biomedical,
author = {Samuel Voss and Sylvia Saalfeld and Thomas Hoffmann and Gabor Janiga and Oliver Beuing and Philipp Berg},
title = {{Fluid-structure interaction in intracranial vessel walls: The role of patient-specific wall thickness}},
journal = {Current Directions in Biomedical Engineering},
year = {2018},
volume = {4(1)},
pages = {587--590},
}
Samuel Voß, Patrick Saalfeld, Sylvia Saalfeld, Oliver Beuing, Gabor Janiga, Bernhard Preim
Bildverarbeitung für die Medizin (BVM), pp. 359-364, 2018
BIBTeX
@InProceedings{Voss_2018_BVM,
Title = {Impact of gradual vascular deformations on the intra-aneurysmal hemodynamics},
Author = {Samuel Voß and Patrick Saalfeld and Sylvia Saalfeld and Oliver Beuing and Gabor Janiga and Bernhard Preim},
Booktitle = {{Bildverarbeitung für die Medizin (BVM)}},
Year = {2018},
Month = {März},
Pages = {359--364},
Publisher = {Springer Verlag}
}

Tutorials

Year:
Primary Author:
Topic:

Steffen Oeltze, Helwig Hauser, Johannes Kehrer
Half Day Tutorial at IEEE VIS Seattle WA U.S., 2013
BIBTeX
@MISC{,
author = {Steffen Oeltze and Helwig Hauser and Johannes Kehrer},
title = {Interactive Visual Analysis of Scientific Data},
year = {2013},
note = {Half Day Tutorial at IEEE VIS, Seattle, WA, U.S.},
owner = {Mathias},
timestamp = {2014.02.28}
}

PhD

Year:
Primary Author:
Topic:

@PhdThesis{Klemm2016,
Title = {{Interactive Visual Analysis of Population Study Data}},
Author = {Paul Klemm},
School = {Otto-von-Guericke University Magdeburg},
Year = {2016},
Owner = {schumann},
Timestamp = {2016.06.24}
}
@PhdThesis{Koehler2016,
Title = {{Guided qualitative and quantitative Analysis of cardiac 4D PC-MRI blood flow data}},
Author = {Benjamin Köhler},
School = {Otto-von-Guericke University Magdeburg},
Year = {2016},
Owner = {schumann},
Timestamp = {2016.09.28}
}
@PhdThesis{Roessling2016,
Title = {{Vermessung von medizinischen Segementierungen für die chirurgische Interventionsplanung und Dokumentation}},
Author = {Ivo Rössling},
School = {Otto-von-Guericke University Magdeburg},
Year = {2016},
Owner = {schumann},
Timestamp = {2016.02.17}
}