Biblio
Using robotic systems in order to determine biomechanical properties of soft tissues. Proc. 2nd Symposium on Applied Biomechanics, Medicine Meets Engineering, BIOMECH.
.
2007. Verringerung der Torsionsdifferenz bei Frakturen des Femurschaftes durch den Einsatz eines neuen auf Flouroskopie basierenden Navigationsmoduls. DGU 2005, 69 Jahrestagung Deutsche Gesellschaft für Unfallchirurgie.
.
2005. Vollautomatische Reposition von Femurschaftfrakturen durch ein Robotersystem. 72. Jahrestagung Deutsche Gesellschaft für Unfallchirurgie.
.
2008. X-ray based compensation of relative motions for non-invasive robotic reduction of femoral shaft fractures. 18th European Conference on Orthopaedics, the conference of the European Orthopaedic Research Society.
.
2010. X-ray based compensation of relative motions for non-invasive surgical navigation (Poster). CARS 2010.
.
2010. X-ray based drill guidance to support intramedullary nailing. CURAC 2006, 5. Jahrestagung der Gesellschaft für Computer- und Roboterassistierte Chirurgie.
.
2006. .
2012. 3D Visualized Robot Assisted Reduction of Femoral Shaft Fractures. Technol Health Care. 17(4):337–343.
.
2009. Analysis of Manual Segmentation in Paranasal CT Images. European Archives of Oto-Rhino-Laryngology.
.
2008. Assessment of the accuracy of infrared and electromagnetic navigation using an industrial robot: Which factors are influencing the accuracy of navigation? J Orthop Res. 2011. :1476–1483.
.
2011. Development of a fixation device for robot assisted fracture reduction of femoral shaft fractures: a biomechanical study. Technol Health Care. 18:207–216.
.
2010. Ex Vivo evaluation of force data and tissue elasticity for robot-assisted FESS. Eur Arch Otorhinolaryngol.
.
2008. Forces and torques during fracture reduction: Intraoperative measurements in the femur. J Orthop Res. 24:333–338.
.
2006. Hands-on robotic distal interlocking in intramedullary nail fixation of femoral shaft fractures. Technol Health Care. 18
.
2010. Overdistraction of the fracture eases reduction in delayed femoral nailing: results of intraoperative force measurements. J Trauma. 61:900–904.
.
2006. A rat model for evaluating physiological responses to femoral shaft fracture reduction using a surgical robot. Journal of Orthopaedic Research. 26:1656–1659.
.
2008. Robot Assisted Long Bone Fracture Reduction. Int. Journal of Robotics Research - Special Issue: Medical Robotics, Part II. 28:1259–1278.
.
2009. Robot-assisted fracture reduction: A preliminary study in the femur shaft. Med Biol Eng Comput. 43:115–120.
.
2005. Robot-assisted fracture reduction using three-dimensional intraoperative fracture visualization: An experimental study on human cadaver femora. Journal of Orthopaedic Research. :1240–1244.
.
2010. Robotized access to the medullary cavity for intramedullary nailing of the femur. Technol Health Care. 18:173–180.
.
2010. A standardized fracture reduction model for long bones - Implication and evaluation in the femur. Technol Health Care. 18:387–391.
.
2010. A Surgical Telemanipulator for Femur Shaft Fracture Reduction. Int. J. of of Medical Robotics and Computer Assisted Surgery. 2:238–250.
.
2006. Workspace and Pivot Point for Robot assisted Endoscope Guidance in Functional Endonasal Sinus Surgery (FESS). Int. J. of of Medical Robotics and Computer Assisted Surgery. 11:30–37.
.
2015. .
2013. .
2015.