| Nome |
# |
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A Microsoft HoloLens Mixed Reality Surgical Simulator for Patient-Specific Hip Arthroplasty Training, file e0d6c92b-0b8a-fcf8-e053-d805fe0aa794
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1.289
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Hybrid Video/Optical See-Through HMD, file e0d6c92a-b783-fcf8-e053-d805fe0aa794
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927
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Proof of Concept: Wearable Augmented Reality Video See-Through Display for Neuro-Endoscopy, file e0d6c92a-d689-fcf8-e053-d805fe0aa794
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690
|
|
Perceptual Limits of Optical See-Through Visors for Augmented Reality Guidance of Manual Tasks, file e0d6c930-bc82-fcf8-e053-d805fe0aa794
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567
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Augmented reality in open surgery, file e0d6c931-208f-fcf8-e053-d805fe0aa794
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558
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Patient-specific ultrasound liver phantom: materials and fabrication method, file e0d6c931-18ce-fcf8-e053-d805fe0aa794
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479
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A new head-mounted display-based augmented reality system in neurosurgical oncology: a study on phantom, file e0d6c92a-d2cc-fcf8-e053-d805fe0aa794
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467
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A Systematic Review of Virtual Reality Simulators for Robot-assisted Surgery, file e0d6c931-1cb5-fcf8-e053-d805fe0aa794
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396
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Augmented Reality to Improve Surgical Simulation. Lessons Learned Towards the Design of a Hybrid Laparoscopic Simulator for Cholecystectomy, file e0d6c930-f764-fcf8-e053-d805fe0aa794
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395
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Towards a Wearable Augmented Reality Visor for High-Precision Manual Tasks, file e0d6c92f-5bb8-fcf8-e053-d805fe0aa794
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275
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Application of a new wearable augmented reality video see-through display to aid percutaneous procedures in spine surgery, file e0d6c928-0552-fcf8-e053-d805fe0aa794
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249
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Toed-in vs Parallel Displays in Video See-Through Head-Mounted Displays for Close-Up View, file e0d6c92d-f998-fcf8-e053-d805fe0aa794
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247
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null, file e0d6c92a-b77d-fcf8-e053-d805fe0aa794
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233
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In-situ laser fenestration of endovascular stent-graft in abdominal aortic aneurysm repair (EVAR), file e0d6c92b-1375-fcf8-e053-d805fe0aa794
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207
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Laparoscopic treatment of splenic artery aneurysms, file e0d6c927-9054-fcf8-e053-d805fe0aa794
|
177
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Augmented reality as an aid in maxillofacial surgery: Validation of a wearable system allowing maxillary repositioning, file e0d6c931-5614-fcf8-e053-d805fe0aa794
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176
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Design of a sensorized guiding catheter for in situ laser fenestration of endovascular stent, file e0d6c92a-f31a-fcf8-e053-d805fe0aa794
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163
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Towards the Development of a Quasi-Orthoscopic Hybrid Video/Optical See-Through HMD for Manual Tasks, file e0d6c92d-7243-fcf8-e053-d805fe0aa794
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154
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Projected Augmented Reality to Drive Osteotomy Surgery: Implementation and Comparison With Video See-Through Technology, file e0d6c92f-5463-fcf8-e053-d805fe0aa794
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144
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Novel EM Guided Endovascular Instrumentation for In Situ Endograft Fenestration, file e0d6c92e-bb08-fcf8-e053-d805fe0aa794
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137
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A preliminary quantitative EEG study on Augmented Reality Guidance of Manual Tasks, file e0d6c931-dc38-fcf8-e053-d805fe0aa794
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135
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Analytic description of the image to patient torso registration problem in image guided interventions, file e0d6c926-843f-fcf8-e053-d805fe0aa794
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130
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Ex vivo efficacy demonstration of a laser fenestration system for endovascular abdominal aortic aneurysm repair (EVAR), file e0d6c92e-9fb8-fcf8-e053-d805fe0aa794
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126
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How to Build a Patient-Specific Hybrid Simulator for Orthopaedic Open Surgery: Benefits and Limits of Mixed-Reality Using the Microsoft HoloLens, file e0d6c92c-4db8-fcf8-e053-d805fe0aa794
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119
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Monitoring Wound Healing with Contactless Measurements and Augmented Reality, file e0d6c930-3498-fcf8-e053-d805fe0aa794
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119
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Off-Line Camera-Based Calibration for Optical See-Through Head-Mounted Displays, file e0d6c92e-8e1b-fcf8-e053-d805fe0aa794
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113
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Comparative health technology assessment of robotic-assisted, direct manual laparoscopic and open surgery: a prospective study, file e0d6c92b-3235-fcf8-e053-d805fe0aa794
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101
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Video see through AR head-mounted display for medical procedures, file e0d6c92f-e663-fcf8-e053-d805fe0aa794
|
100
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Wearable Augmented Reality Platform for Aiding Complex 3D Trajectory Tracing, file e0d6c92e-e20e-fcf8-e053-d805fe0aa794
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98
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The role of camera convergence in stereoscopic video see-through augmented reality displays, file e0d6c92e-e8f3-fcf8-e053-d805fe0aa794
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96
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Patients Specific Spine Simulators for Surgical Training and Rehearsal in Pedicle Screws Placement: A New Way for Surgical Education, file e0d6c92f-58fd-fcf8-e053-d805fe0aa794
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81
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Assessment of DICOM Viewers Capable of Loading Patient-specific 3D Models Obtained by Different Segmentation Platforms in the Operating Room, file e0d6c931-18d2-fcf8-e053-d805fe0aa794
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80
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Wearable augmented reality application for shoulder rehabilitation, file e0d6c92e-4bf8-fcf8-e053-d805fe0aa794
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77
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Recognizing AR-guided manual tasks through autonomic nervous system correlates: A preliminary study, file e0d6c931-efbb-fcf8-e053-d805fe0aa794
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76
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Low-Computational Cost Stitching Method in a Three-Eyed Endoscope, file e0d6c92e-1a25-fcf8-e053-d805fe0aa794
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62
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Robust and accurate algorithm for wearable stereoscopic augmented reality with three indistinguishable markers, file e0d6c92e-bceb-fcf8-e053-d805fe0aa794
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61
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Computed-tomography image segmentation and 3D-reconstruction of the female pelvis for the preoperative planning of sacrocolpopexy: preliminary data, file e0d6c92d-2eee-fcf8-e053-d805fe0aa794
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58
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Review on Augmented Reality in Oral and Cranio-Maxillofacial Surgery: towards “surgery-specific” head-up displays, file e0d6c92e-bb67-fcf8-e053-d805fe0aa794
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56
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PATIENT-SPECIFIC TEMPLATES FOR PEDICLE SPINE SCREW PLACEMENT: LITERATURE REVIEW AND PROPOSAL OF A NEW DESIGN, file e0d6c928-2b4e-fcf8-e053-d805fe0aa794
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47
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null, file e0d6c92f-58ed-fcf8-e053-d805fe0aa794
|
45
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Augmented reality in neurosurgery: a systematic review, file e0d6c931-18d0-fcf8-e053-d805fe0aa794
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44
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Hybrid Simulation and Planning Platform for Cryosurgery with Microsoft HoloLens, file e0d6c931-3129-fcf8-e053-d805fe0aa794
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43
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APPLICATION OF A NEW WEARABLE VIDEO SEE- THROUGH AUGMENTED REALITY SYSTEM BASED ON HEAD MOUNTED DISPLAYS TO AID PERCUTANEOUS PROCEDURE IN SPINE SURGERY, file e0d6c928-0c49-fcf8-e053-d805fe0aa794
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31
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Use of Knee Fractures Physical Replicas for Surgical Training and Rehearsal: Proof of Concept Study, file e0d6c930-6052-fcf8-e053-d805fe0aa794
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19
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Augmented Reality to Improve Surgical Simulation: Lessons Learned Towards the Design of a Hybrid Laparoscopic Simulator for Cholecystectomy, file e0d6c931-2248-fcf8-e053-d805fe0aa794
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19
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The Wearable VOSTARS System for Augmented Reality-Guided Surgery: Preclinical Phantom Evaluation for High-Precision Maxillofacial Tasks, file e0d6c931-a04f-fcf8-e053-d805fe0aa794
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17
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Drilling mask for implanting a transpedicular screw, file e0d6c931-0509-fcf8-e053-d805fe0aa794
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13
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null, file e0d6c927-88f0-fcf8-e053-d805fe0aa794
|
10
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A Rendering Engine for Integral Imaging in Augmented Reality Guided Surgery, file 0a7776b8-180b-4f28-b9e8-13f4e9749de5
|
7
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Face, content, and construct validity of a simulator for training in endovascular procedures, file 42bf3112-6748-4dfc-a5bb-69c4704366b3
|
7
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Simultaneous tracking of catheters and guidewires: Comparison to standard fluoroscopic guidance for arterial cannulation, file e0d6c926-fe20-fcf8-e053-d805fe0aa794
|
6
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null, file e0d6c927-8230-fcf8-e053-d805fe0aa794
|
6
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Total Hip Replacement Simulators with Virtual Planning and Physical Replica for Surgical Training and Reharsal, file e0d6c928-0818-fcf8-e053-d805fe0aa794
|
6
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|
A tele-ultrasonographic platform to collect specialist second opinion in less specialized hospitals, file e0d6c92d-10a4-fcf8-e053-d805fe0aa794
|
6
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Registration Sanity Check for AR-guided Surgical Interventions: Experience from Head and Face Surgery, file c216cc33-0d21-461c-904e-796992eb70f4
|
5
|
|
null, file e0d6c927-9a6e-fcf8-e053-d805fe0aa794
|
5
|
|
In situ diode laser fenestration: An ex-vivo evaluation of irradiation effects on human aortic tissue, file e0d6c92d-499d-fcf8-e053-d805fe0aa794
|
5
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|
Are augmented reality headsets in surgery a dead end?, file e0d6c92e-26f6-fcf8-e053-d805fe0aa794
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5
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3D ultrasound centerline tracking of abdominal vessels for endovascular navigation, file e0d6c926-49f4-fcf8-e053-d805fe0aa794
|
4
|
|
null, file e0d6c92d-7557-fcf8-e053-d805fe0aa794
|
4
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|
Augmented reality in neurosurgery: a systematic review, file e0d6c92e-83de-fcf8-e053-d805fe0aa794
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4
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Software Framework for Customized Augmented Reality Headsets in Medicine, file e0d6c92e-be1a-fcf8-e053-d805fe0aa794
|
4
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A Systematic Review on Methods and Tools for the In Situ Fenestration of Aortic Stent-Graft, file e0d6c931-13da-fcf8-e053-d805fe0aa794
|
4
|
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Architecture of a Hybrid Video/Optical See-through Head-Mounted Display-Based Augmented Reality Surgical Navigation Platform, file e0d6c931-c769-fcf8-e053-d805fe0aa794
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4
|
|
Patient specific surgical simulator for the evaluation of the movability of bimanual robotic arms, file e0d6c926-319e-fcf8-e053-d805fe0aa794
|
3
|
|
APPLICATION OF WEARABLE AUGMENTED REALITY TO AID PERCUTANEOUS PROCEDURES IN SPINE SURGERY, file e0d6c928-646f-fcf8-e053-d805fe0aa794
|
3
|
|
Electromagnetic guided in-situ laser fenestration of endovascular stent-graft: Endovascular tools sensorization strategy and preliminary laser testing, file e0d6c92a-0bf2-fcf8-e053-d805fe0aa794
|
3
|
|
null, file e0d6c92a-a387-fcf8-e053-d805fe0aa794
|
3
|
|
null, file e0d6c92a-a55a-fcf8-e053-d805fe0aa794
|
3
|
|
Laparoscopic treatment of splenic artery aneurysms, file e0d6c92c-d0d8-fcf8-e053-d805fe0aa794
|
3
|
|
Wearable tactile interfaces Using SMA Wires, file e0d6c92e-d15b-fcf8-e053-d805fe0aa794
|
3
|
|
Augmented Reality-Assisted Craniotomy for Parasagittal and Convexity En Plaque Meningiomas and Custom-Made Cranio-Plasty: A Preliminary Laboratory Report, file e0d6c931-72db-fcf8-e053-d805fe0aa794
|
3
|
|
Augmented reality, mixed reality, and hybrid approach in healthcare simulation: A systematic review, file e0d6c931-7ec5-fcf8-e053-d805fe0aa794
|
3
|
|
Brain Tumor and Augmented Reality: New Technologies for the Future, file 0a3dffb3-c660-4b19-b010-bdee02a67787
|
2
|
|
Electromagnetic navigation platform for endovascular surgery: how to develop sensorized catheters and guidewires, file e0d6c926-31d5-fcf8-e053-d805fe0aa794
|
2
|
|
Segmentation procedure for the generation of a 3D model and solid replica of a human skull, file e0d6c926-3c3a-fcf8-e053-d805fe0aa794
|
2
|
|
null, file e0d6c927-fb78-fcf8-e053-d805fe0aa794
|
2
|
|
UTILIZZO DI MODELLI TRIDIMENSIONALI VIRTURALI E REALI, OTTENUTI MEDIANTE PROTOTIPAZIONE RAPIDA, PER IL TRAINING CHIRURGICO IN CHIRURGIA PROTESICA DELL’ANCA, file e0d6c928-081d-fcf8-e053-d805fe0aa794
|
2
|
|
Full Robotic Colorectal Resections for Cancer Combined With Other Major Surgical Procedures: Early Experience With the da Vinci Xi, file e0d6c92a-adce-fcf8-e053-d805fe0aa794
|
2
|
|
Augmented reality in healthcare, file e0d6c92e-2f30-fcf8-e053-d805fe0aa794
|
2
|
|
A Systematic Review of Virtual Reality Simulators for Robot-assisted Surgery, file e0d6c92e-81cb-fcf8-e053-d805fe0aa794
|
2
|
|
Augmented reality as an aid in maxillofacial surgery: Validation of a wearable system allowing maxillary repositioning, file e0d6c92e-c204-fcf8-e053-d805fe0aa794
|
2
|
|
Ambiguity-Free Optical–Inertial Tracking for Augmented Reality Headsets, file e0d6c92e-d5d8-fcf8-e053-d805fe0aa794
|
2
|
|
Optical See-Through Head-Mounted Displays With Short Focal Distance: Conditions for Mitigating Parallax-Related Registration Error, file e0d6c92f-ed65-fcf8-e053-d805fe0aa794
|
2
|
|
Bioreactor With Electrically Deformable Curved Membranes for Mechanical Stimulation of Cell Cultures, file e0d6c92f-ef32-fcf8-e053-d805fe0aa794
|
2
|
|
Hybrid Spine Simulator Prototype for X-ray Free Pedicle Screws Fixation Training, file e0d6c930-114a-fcf8-e053-d805fe0aa794
|
2
|
|
null, file e0d6c930-ebfb-fcf8-e053-d805fe0aa794
|
2
|
|
Can Liquid Lenses Increase Depth of Field in Head Mounted Video See-Through Devices?, file e0d6c931-8fc6-fcf8-e053-d805fe0aa794
|
2
|
|
In situ visualization for 3d ultrasound-guided interventions with augmented reality headset, file e0d6c931-ad05-fcf8-e053-d805fe0aa794
|
2
|
|
Wearable AR and 3D Ultrasound: Towards a Novel Way to Guide Surgical Dissections, file e0d6c931-b32b-fcf8-e053-d805fe0aa794
|
2
|
|
AR Interaction paradigm for closed reduction of long-bone fractures via external fixation, file 9bfbbcf9-9347-4324-a7dd-19412ba35aac
|
1
|
|
Value of multidetector computed tomography image segmentation for preoperative planning in general surgery., file e0d6c926-0d9f-fcf8-e053-d805fe0aa794
|
1
|
|
Application of segmentation and 3D rendering techniques in the mummies of Cangrande della Scala (1291-1329) and S. Giacomo della Marca (1391-1476), file e0d6c926-1b4d-fcf8-e053-d805fe0aa794
|
1
|
|
An optimal design for patient-specific templates for pedicle spine
screws placement., file e0d6c926-3adb-fcf8-e053-d805fe0aa794
|
1
|
|
PATIENT-SPECIFIC TEMPLATES FOR PLACEMENT OF PEDICLE SPINE SCREWS: PROPOSAL OF A NEW DESIGN, file e0d6c928-6a51-fcf8-e053-d805fe0aa794
|
1
|
|
null, file e0d6c92d-a1a3-fcf8-e053-d805fe0aa794
|
1
|
|
Proficiency-based training of medical students using virtual simulators for laparoscopy and robot-assisted surgery: results of a pilot study, file e0d6c92e-6e18-fcf8-e053-d805fe0aa794
|
1
|
|
Hybrid simulation using mixed reality for interventional ultrasound imaging training, file e0d6c92e-7b00-fcf8-e053-d805fe0aa794
|
1
|
|
Distribution of innate psychomotor skills recognized as important for surgical specialization in unconditioned medical undergraduates, file e0d6c92e-9287-fcf8-e053-d805fe0aa794
|
1
|
|
Towards electromagnetic tracking of J-tip guidewire: precision assessment of sensors during bending tests, file e0d6c92e-caab-fcf8-e053-d805fe0aa794
|
1
|
| Totale |
10.059 |