CAOS 2020: Volume InformationCAOS 2020. The 20th Annual Meeting of the International Society for Computer Assisted Orthopaedic Surgery68 articles•315 pages•Published: September 25, 2020 PapersFlorent Baldairon, Noah Davis, Lindsay Palm, Scott Banks and Jean-Yves Jenny 1-7 | Julien Bardou-Jacquet 8-11 | Mehdi Boudissa, Delphine Carmagnac, Gael Kerschbaumer and Jérôme Tonetti 12-16 | Mehdi Boudissa, Matthieu Chabanas, Gaetan Bahl, Hadrien Oliveri and Jérôme Tonetti 17-21 | Angelo Capodici, Paolo Domenico Parchi, Sara Condino, Marina Carbone, Vincenzo Ferrari, Ilenia Pasqua, Mauro Ferrari and Michelangelo Scaglione 22-27 | Teja Cherukuri, Chameka Madurawe, Jim Pierrepont, Jonathan Bare, Stephen McMahon and Andrew Shimmin 28-34 | Kyu-Jin Cho, Gun-Woo Kim, Nam-Hun Lee, Young-Woo Chung, Jongkeun Seon and Eun-Kyoo Song 35-40 | Yifei Dai, Laurent Angibaud, Guillaume Bras, Cyril Hamad and Jefferson Craig Morrison 41-44 | Yifei Dai, Charlotte Bolch, Andrew Jensen and Amaury Jung 45-48 | Yifei Dai, Amaury Jung, Guillaume Bras and Ian Gradisar 49-52 | Kamal Deep 53-55 | Kamal Deep and Frederic Picard 56-58 | Kamal Deep, Frederic Picard and Shoaib Iqbal 59-60 | David Leandro Dejtiar, Laura Bartsoen, Mariska Wesseling, Roel Wirix-Speetjens, Jos Vander Sloten and Maria Angeles Perez 61-64 | Anass Elmoadine, Maxime Pistono, Reda Bellafqira and Gouenou Coatrieux 65-68 | Hooman Esfandiari, Sebastian Andreß, Maternus Herold, Wolfgang Böcker, Simon Weidert and Antony J Hodgson 69-73 | Wen Fan, Yifei Dai and Gérard Giordano 74-77 | Yuan Gao, Le Xie and Guoyan Zheng 78-81 | Charles Garraud, Arnaud Clavé, Jérôme Ogor, Eric Stindel and Guillaume Dardenne 82-85 | Sonja A. G. A. Grothues, Malte Asseln and Klaus Radermacher 86-91 | Aziliz Guezou-Philippe, Guillaume Dardenne, Asma Salhi, Valérie Burdin, Christian Lefevre and Eric Stindel 92-96 | Octave Guinebretiere and J.W. Giles 97-102 | Maxime Guinin, Guillaume Pasquier, Saad El Jaouhari, Patrick Hardy, Julien Waechter, Flavien Bridault, Alexandre Hostettler and Jacques Marescaux 103-107 | Shinya Hayashi, Shingo Hashimoto, Koji Takayama, Tomoyuki Matsumoto, Nao Shibanuma, Kazunari Ishida and Ryosuke Kuroda 108-110 | Jeffrey Hodrick, Thomas Schlierf, Jeffrey Pearson and Mary Stumb 111-116 | Benjamin Hohlmann and Klaus Radermacher 117-121 | Xue Hu, He Liu and Ferdinando M Rodriguez Y Baena 122-125 | Vincent Jaouen, Guillaume Dardenne, Florent Tixier, Éric Stindel and Dimitris Visvikis 126-130 | Jean-Yves Jenny and Geoffrey Ginot 131-134 | Jean-Yves Jenny, Dominique Saragaglia, Thierry Gaillard and Frédéric Châtain 135-137 | Bertrand Kaper 138-143 | Bertrand Kaper 144-150 | Bertrand Kaper 151-154 | Akihiro Kawasaki, Yoshito Otake, Keisuke Uemura, Masaki Takao, Nobuhiko Sugano and Yoshinobu Sato 155-159 | John Keggi, Jeffrey Lawrence, Amber Randall, Jeffrey DeClaire, Corey Ponder, Jan Koenig, Sami Shalhoub, Edgar Wakelin and Christopher Plaskos 160-164 | Edgar Wakelin, Sami Shalhoub, Jan Koenig and Christopher Plaskos 165-168 | Adriaan Lambrechts, Muthu Ganapathi and Roel Wirix-Speetjens 169-173 | Stephen Laws, Spyridon Souipas, Brian Davies and Ferdinando Rodriguez Y Baena 174-178 | Jialong Li, David Liu, Stephen McMahon, Jonathan Baré, Andrew Shimmin, Brad Miles, Qing Li and Joshua Twiggs 179-182 | Nicolas Loy Rodas, Marion Decrouez, Blaise Bleunven and Sophie Cahen 183-187 | Wistan Marchadour, Guillaume Dardenne, Aziliz Guezou-Philippe, Christian Lefèvre and Eric Stindel 188-192 | Jefferson Craig Morrison, Erika Frazier and Mary Denton Stumb 193-196 | Albert Murienne, Boris Labbé and Laurent Launay 197-200 | Seung-Min Na, Gun-Woo Kim, Nam-Hun Lee, Young-Woo Chung, Jongkeun Seon and Eun-Kyoo Song 201-203 | Seung-Min Na, Gun-Woo Kim, Lee Nam-Hun, Young-Woo Chung, Jongkeun Seon and Eun-Kyoo Song 204-210 | Jérôme Ogor, Guillaume Dardenne, Salaheddine Sta, Julien Bert, Hoel Letissier, Eric Stindel and Chafiaa Hamitouche 211-214 | Alexander Orsi, Edgar Wakelin, Sami Shalhoub, Jeffrey Lawrence, Corey Ponder, John Keggi and Christopher Plaskos 215-219 | Prashant Pandey, Pierre Guy, Kelly Lefaivre and Antony J. Hodgson 220-224 | Paolo Domenico Parchi, Sara Condino, Marina Carbone, Sara Stagnari, David Rocchi, Simone Colangeli, Mauro Ferrari, Michelangelo Scaglione and Vincenzo Ferrari 225-230 | Thomas Paszicsnyek, Edoardo Bori and Bernardo Innocenti 231-233 | Thomas Paszicsnyek, Edoardo Bori, Christoph Stiegler and Bernardo Innocenti 234-236 | Jonathan Pitocchi, Katrien Plessers, Mariska Wesseling, G. Harry van Lenthe and Maria Angeles Pérez 237-239 | Christopher Plaskos, Edgar Wakelin, Sami Shalhoub, Jeffrey Lawrence, John Keggi, Jan Koenig, Corey Ponder and Jeffrey DeClaire 240-245 | Benjamin Roberts and Willy Theodore 246-249 | Fabio Tatti, Hisham Iqbal, Branislav Jaramaz and Ferdinando Rodriguez Y Baena 250-253 | Matthew Thompson, Roopa Guttal, Shon Darcy, Akshay Alaghatta, Andrea Marcovigi and Fabio Catani 254-258 | Joshua Twiggs, Justin Roe, Brett Fritsch, David Parker and Brad Miles 259-263 | Joshua Twiggs, David Liu, Justin Roe, David Parker and Brad Miles 264-268 | Keisuke Uemura, Masashi Okamoto, Kunihiko Tokunaga and Andrew Anderson 269-272 | Jonathan Vigdorchik, Abhinav Sharma, Ameer Elbuluk, Kaitlin Carroll, David Mayman and Jay Lieberman 273-277 | Manuel Vossel, Klaus Radermacher and Matias de La Fuente 278-282 | Edgar Wakelin, Sami Shalhoub, Jeffrey Lawrence, John Keggi, Jeffrey DeClaire, Amber Randall, Corey Ponder, Jan Koenig and Christopher Plaskos 283-287 | Edgar Wakelin, Sami Shalhoub, Jeffrey Lawrence, John Keggi, Jeffrey DeClaire, Amber Randall, Corey Ponder, Jan Koenig and Christopher Plaskos 288-292 | Edgar Wakelin, Sami Shalhoub, Jeffrey Lawrence, John Keggi, Amber Randall, Corey Ponder, Jeffrey DeClaire, Jan Koenig and Christopher Plakos 293-296 | Johannes Willkomm, Lucas Jauer, Stephan Ziegler and Johannes Henrich Schleifenbaum 297-300 | Irene Yang, Jonathan D. Gammell, David W. Murray and Stephen J. Mellon 301-305 | Xuxin Zeng, Michael Vives and Ilker Hacihaliloglu 306-311 | Guoyan Zheng 312-315 |
Keyphrases3D alignment, 3D pose estimation, 3D printing2, A-mode ultrasound, Accuracy2, acetabular fracture, Additive Manufacturing, alignment, anatomical landmarks, Anterior Pelvic Plane, Arthroplasty, Artificial Intelligence, Artificial Neural Network, Augmented mechanical instrumentation, Augmented Reality3, Automatic landmarks localization, balance, Biomechanical model, Biomechanics2, bone density, Bone Segmentation, C-arm, caos, CAOS augmentation, Central pivot, Classification, clinical outcomes, Component alignment2, Computed Tomography, Computer-assisted orthopaedic surgery4, Computer-assisted orthopedic surgery3, computer assisted surgery4, computer vision, Consultation, conventional TKA, Convolutional Neural Network2, cruciate-retaining, CT2, custom implant, data confidentiality, DDH, deep learning5, deformable registration, depth camera, depth sensor, DICOM-RTV, digital sensors, dislocation, display, femoral head coverage, Femoral roll back, fixation, Fluoroscopy, functional stability2, Gap balance, Generative Adversarial Networks, Geometric Parameter Analysis, HIP2, hip-spine, iliosacral screw insertion, Iliosacral screwing, image processing, imaging, IMD, Impingement2, implant, Implant fixation, in vivo validation, Intraoperative guidance, Intraoperative laxity curve, J-curve, Joint Balance3, joint replacement2, kinematic analysis, kinematics2, knee2, knee function, Knee MRI, knee replacement, knee surgery, landmarking, Laser Powder Bed Fusion, Lateral Decubitus Position, lateral knee., Lattice structures, learning curve, Lewinnek, ligament balancing4, ligament characterization, Ligament Laxity, Ligament tension2, load sensors, long term survivalship, Loosening, Low cost Navigation, Mako3, markerless, Markerless tracking, Measured-resection, Measured Resection technique, Medial pivot, medical robotics, Mid-flexion Instability, Midflexion Balance, Mobile bearing, mobile bearing dislocation, motion capture, Multicenter Trials, Muscle elongation, musculoskeletal model, Navigation6, Navigational TKA, numerical simulation, offset, Opioids, Orthosensor2, Osteochondral Defect Repair, outcome, outcomes2, Patient Specific Implants, Patient Specific Instrument, Patient Specific Instrumentation, Patient Specific Surgical Planning, pedicular screws, pelvic tilt2, pelvis2, Performance, periacetabular osteotomy, point cloud registration, pose estimation2, position control, Pre-operative planning, preferred surgical philosophy, preoperative planning4, Primary implants, Principal Component Analysis, Principle Component Analysis, projector, PROMS3, range of motion2, real-time control, registration4, resection accuracy, Robot assisted TKA, Robotic3, Robotic-Assisted, Robotic-assisted surgery3, Robotic-assisted total hip arthroplasty, Robotic-assisted total knee arthroplasty, robotic knee arthroplasty, robotic surgery, Robotic TKA, Robotics, robotics path planning, RRT algorithm, Safe Zone, Scapula, Secure processing, Segmentation5, sensor, Shoulder Arthroplasty, simulation, size, Soft-tissue balance, Soft Tissue Release, Spinal deformity, Spine surgery, statistical atlas generation, Statistical Shape Model4, stiff spine, subsidence, Surgery Planning Assistance, surgical instruments, surgical navigation, surgical simulation, surgical targeting, surgical training2, THA2, THR, three-dimensional, Tibia first gap balancing, Tibial fracture, tibiofemoral kinematics, time2, Time Synchronization, TKA4, total hip arthroplasty5, Total knee arthropalsty, Total knee arthroplasty23, Total knee arthroplasty (TKA), total knee replacement, Total knee revision, Tracking3, Transfer Learning, two-dimensional, Ultrasound2, Unicompartmental Knee Arthroplasty, User Authentication, Validation, variability, virtual planning. |
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