CAOS 2019. The 19th Annual Meeting of the International Society for Computer Assisted Orthopaedic Surgery100 articles•465 pages•Published: October 26, 2019 PapersPages 1-5 | Pages 6-10 | Pages 11-16 | Pages 17-20 | Pages 21-25 | Pages 26-30 | Pages 31-35 | Pages 36-39 | Pages 40-45 | Pages 46-48 | Pages 49-52 | Pages 53-56 | Zlatan Cizmic, Kaitlin Carroll, Seth Jerabek, Wayne Paprosky, Peter Sculco, Alejandro Gonzalez Della Valle, Patrick Meere, Alexander McLawhorn, Ran Schwarzkopf, Friedrich Boettner, David Mayman and Jonathan Vigdorchik Pages 57-61 | Pages 62-71 | Pages 72-75 | Pages 76-79 | Pages 80-83 | Pages 84-89 | Pages 90-93 | Pages 94-97 | Pages 98-101 | Pages 102-105 | Pages 106-109 | Pages 110-114 | Pages 115-118 | Pages 119-121 | Pages 122-126 | Pages 127-132 | Pages 133-138 | Pages 139-142 | Pages 143-146 | Pages 147-151 | Pages 152-156 | Pages 157-160 | Pages 161-165 | Pages 166-168 | Pages 169-172 | Pages 173-176 | Pages 177-180 | Pages 181-183 | Pages 184-188 | Pages 189-192 | Pages 193-196 | Pages 197-201 | Pages 202-205 | Pages 206-209 | Pages 210-214 | Pages 215-222 | Pages 223-227 | Pages 228-233 | Pages 234-240 | Pages 241-245 | Pages 246-250 | Pages 251-256 | Pages 257-261 | Pages 262-270 | Pages 271-274 | Pages 275-277 | Pages 278-281 | Pages 282-288 | Pages 289-292 | Pages 293-296 | Pages 297-300 | Pages 301-305 | Pages 306-310 | Pages 311-314 | Pages 315-318 | Pages 319-321 | Pages 322-324 | Pages 325-327 | Pages 328-330 | Pages 331-333 | Pages 334-337 | Pages 338-343 | Pages 344-350 | Pages 351-353 | Pages 354-358 | Pages 359-361 | Pages 362-365 | Pages 366-369 | Pages 370-375 | Pages 376-379 | Pages 380-383 | Pages 384-387 | Pages 388-391 | Pages 392-397 | Pages 398-401 | Pages 402-408 | Pages 409-414 | Pages 415-417 | Pages 418-421 | Pages 422-427 | Pages 428-431 | Pages 432-435 | Pages 436-439 | Pages 440-443 | Pages 444-447 | Pages 448-452 | Pages 453-459 | Pages 460-465 |
Keyphrases3D pose estimation, 3D printing2, 3D registration, 3D ultrasound, absolute error, accelerometer-based computer navigation system, Accuracy2, acetabular bone stock, acetabular fractures, Achilles, Active kinematics, Additive Manufacturing3, adoption of new technology, Alignment outliers, All polyethylene tibia, Amis, Anatomic Total Shoulder Arthroplasty2, anatomical tibial cut2, anatomy, Ankle, Anterior Minimal Invasive Surgery, AP radiograph, Arthoplasty, Arthroplasty8, Arthroplsaty, Augmented Glenoid2, Augmented Reality, Autografting, Bicompartmental knee arthroplasty, Big Data Analysis2, biofeedback, Biomechanics2, Bone mineral density, Bone recuts, Bone Segmentation3, bone shadow, bone tumor, bone-cup coverage, Bony preservation, Brown-Sequard syndrome, Cadaver Trial, Cartilage, CAS, Cement technique, Cervical disc herniation, complex total hip arthroplasty, Complications, Component alignment, Component position, Computed tomography-based navigation system, computer assisted surgery7, Computer assisted TKA, computer navigation, computer simulation, computer-assisted2, Computer-assisted orthopaedic surgery2, Computer-assisted orthopedic surgery4, computer-assisted technology, Computer-assisted total knee arthroplasty, Conservative Alignment, Conventional instrumentation, Conventional tibial cut, Convolutional Neural Network, Coordinate Transformation Calibration, cost analysis2, CT2, CT analytics, CT-based navigation2, CT-fluoro matching, curved periacetabular osteotomy, Cutting time, Decaf, deep learning2, depth camera2, developmental dysplasia of the hip2, Difficult Cases, Direct anterior approach2, dislocation2, Dynamic radiographs, dysplasia acetabulum, dysplastic acetabulum, EOS biplanar radiographic imaging, Euthanasia, Extended field-of-view, extr-articular deformities, Extramedullary method, Femoral component, Femoral component accuracy, femoral stem, fixation, Functional Movement, Functional radiographs, Fusion, Fuzzy Logic, Gap balance, Gaps balancing, Handheld Robot, Haptic, healing, Healthcare costs, Healthcare economics2, Hip Arthroplasty2, Hip Center, hip flexion, hip replacement, IEEE 11073 SDC, image free handheld robot in TKA, image stitching, image transformation, Implant placement accuracy, implant position optimization, integrated navigation, Integrated Operating Room, Interesting cases, Intra-operative, intra-operative 2D/3D imaging, intraoperative CBCT, J-Curves, joint replacement2, Kinematic Alignment, kinematics2, knee10, Laxity, learning curve2, Lewinnek safe zone, ligament balance knee arthroplasty, ligament balancing2, ligament elongations, Limb Alignment, load, local phase, Long term survival3, manual total knee arthroplasty, markerless, Mechanical alignment2, mechanical axis, Mechatronics, medical app, medical application, Medical Imaging, Methods of balancing, morphology2, morphology analysis, Mosaicplasty, motion analysis, multilevel modeling, musculoskeletal modeling, Navigated Control, Navigation10, navigation system, Neuromonitoring, new technologies, Open Database, Open Standards, OpenSim simulation, operative technologies2, Orthopaedics, Orthopedic & Trauma Surgery, orthopedic trauma, Osteoarthritis, Osteonecrosis of the femoral head, osteotomy, outcome5, outcomes2, Partial knee arthroplasty, Patella, Patient risks, patient satisfaction, Patient Specific Guides, Patient Specific Instrumentation, Patient specific instruments, patient specific surgical guide, patient-reported outcome, patient-reported outcomes, patient-specific3, PCL, Pelvic parameters, pelvic tilt3, pelvis, pKa, planning, porous, pre-operative navigation, Pre-operative planning2, Precision, prediction, Preoperative Templating, ProM, propensity score analysis, proximal femur, Proximal tibial cutting, Pseudarthrosis, PSI2, radiography, range of motion, Rapid Prototyping, Ratio for center of the ankle, registration3, Rehabilitation, resulting hip force, results mechanical limb alignment and balacing, retrospective analysis, Retrospective Data Analysis, revision, Revision total hip arthroplasty, revisions, Robotic2, robotic arm-assisted total knee arthroplasty2, Robotic assisted knee arthroplasty, Robotic assisted TKA3, robotic surgery, Robotic Technology, robotic total hip arthroplasty, Robotic Total Knee Arthroplasty, Robotic-Arm Assisted2, Robotic-arm assisted TKA7, Robotic-Assisted4, Robotic-assisted surgery, Robotics4, rTHA, Safe Zone2, Segmentation, Sensor assisted knee arthroplasty, sensor technology, Service Oriented Architecture, Service Oriented Device Connectivity, Short-term outcomes, shoulder, side-to-side asymmetry, simulation, smart mechanical navigation, soft tissue, Soft Tissue Damage, Soft Tissue Release, Soft Tissue Releases, software, spinal cord injury, Spinal deformity, spinal fusion surgery, spine2, Spine surgery2, spontaneous, stability, Statistical Shape Model, SterEOS, Subject Specific Modeling, surface meshes, Surgeon ergonomics3, Surgeon experience, Surgeon experiences, Surgeon safety, Surgical experience, surgical planning, Surgical profiles, surgical robot, Surgical technology, Surgical Workflows, Talar tilt chnage after CAS TKA, target zone, Technology, Tele-rehabilitation, Telos, THA4, three-dimensional, three-dimensional printing, Tibial cutting alignment, Tibial tuberosity-trochlear groove distance, Time Saving, TKA11, total hip arthroplasty15, total hip arthroplasty (THA), Total hip arthroplasy, total hip replacement, total joint arthroplasty, Total knee arthroplasty19, total knee replacement2, Tracking, transplantation, Trochlear Groove, Tuberositas tibiae, UKA2, Ultrasound7, Unicompartmental Knee Arthroplasty, unified technologies, Valgus knee, verification, vertebroplasty, Video - X-ray Overlay, Video Augmented C-arm Flouroscopy, wearable sensors, Weight bearing, X-ray, X-Ray Vision, xray templating, Young patients |
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