Author:Klaus RadermacherPublications |
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| | | | | | | | | | | | | | | Prashant Pandey, Benjamin Hohlmann, Peter Brößner, Ilker Hacihaliloglu, Keiran Barr, Tamas Ungi, Oliver Zettinig, Raphael Prevost, Guillaume Dardenne, Zian Fanti, Wolfgang Wein, Eric Stindel, Fernando Arambula Cosio, Pierre Guy, Gabor Fichtinger, Klaus Radermacher and Antony J. Hodgson | | | | | | | | | | | | | | | | | | | | | | | | | | |
Keyphrases2D-3D Reconstruction, 3D ultrasound, Accuracy, Active kinematics, Additive Manufacturing, automatic contact gel application, Biomechanical Modelling, Biomechanics6, Bone, bone–implant interface, bony impingement, challenge, closed loop control, CNN2, communication standard, completion, Component alignment, Computer-assisted orthopaedic surgery, computer assisted surgery, Convolutional Neural Network2, CT to EOS matching, cup orientation, Digital Operating Rooms, dislocation3, endoprothetis, EtherCAT, extrapolation, functional anatomy, gender, Geometric Parameter Analysis, handheld device, Healthcare, HIP3, hip score, HMI, human-machine interaction2, Human Risk Management, IEC 62366-1, IEEE 11073 Communication Standard, IEEE 11073 SDC2, iliopsoas, image-based planning, image segmentation, Impingement, Implant Design2, Instrument guidance, Instrument guide, Integrated Operating Room2, interbone parameters, Interoperability, Intraoperative Workflow Optimization, ISO 14971, ISO IEEE 11073 SDC Standard, J-curve, J-Curves, kinematics, knee9, knee alignment, knee morphology2, Knee Testing Rig, laminectomy, machine learning, mathematical models, medical robotics, modelling, modular medical device, Modularisation, morpho-functional correlation, morphology3, motion analysis, multi-view segmentation, Navigated Control2, networked operating room, Open Integrated OR Systems, Open Standards, operating room network, optical tracking, OR.NET initiative, OR.NET RT, Orthopaedic robot, Orthopaedics, over-/underhag, Patella, patellofemoral morphology, patient-specific4, Patient Specific Implants2, patient-specific THA, pedicle screw, pelvic tilt3, pneumatic muscle, position control, Pre-operative planning2, preoperative planning4, Preoperative Templating, Principal Component Analysis, proximal femur, psoas syndrome, quality assurance, range of motion3, real-time communication, real-time control, registration2, resulting hip force, risk management, robotic ultrasound, robotic ultrasound system, Robotics, Safe Zone2, Scaphoid, SDC, Segmentation5, semi-active, semi-automatic, Semiactive, sensor integrated, Service Oriented Architecture2, Service Oriented Device Connectivity3, shoulder joint simulator, side-to-side asymmetry, Smart Instruments, Smart Screwdriver, sonography, Spine surgery, SpinePilot, standing position, statistical analysis, Statistical Shape Model2, statistical shape models, stem orientation, Surgical Checklist, Surgical Cockpit, surgical monitoring, surgical navigation, target zone3, THA4, THA planning2, Tibial tuberosity-trochlear groove distance, tibiofemoral morphology, TKA, Tool guidance, Tool guide, total hip arthroplasty3, Total knee arthroplasty8, Tracking2, tracking system, Transfomer, Trochlear Groove, Tuberositas tibiae, UI Profile, Ultrasound6, Ultrasound imaging, ultrasound scanning automation, Unicompartmental Knee Arthroplasty, Universal Foot Switch, Universal footswitch, Usability Engineering, User Interface Profiles, Weight bearing, workflow management. |
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