Medicine Meets Virtual Reality 11
by Westwood, James D.Edition: 1st
Format: Hardcover
Pub. Date: 2003-01-01
Publisher(s): IOS PRESS INC
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Summary
The Proceedings of the 11th annual. Medicine Meets Virtual Reality conference provides current research on many data-centered applications for clinical care and medical education. It is a reference source for IT researchers working in a biomedical context, medical educators, physicians interested in emerging clinical tools, and medical device developers. A major focus is on surgical simulation and supporting technologies: haptics, tissue modeling, and virtual environments. Assessment and validation studies are represented, as well as papers on simulator design and didactics. Another core area is information-guided therapy, from diagnosis through surgery. Discussion of imaging techniques is complemented by papers on visualization, data fusion, and augmented reality. Advances in robotic surgery are also presented.
Table of Contents
| Preface | p. v |
| Special Visual Effects for Surgical Simulation: Cauterization, Irrigation and Suction | p. 1 |
| A Haptic Model of a Bone-cutting Burr | p. 4 |
| Mixed Reality for Neurosurgery: A Novel Prototype | p. 11 |
| GeRTiSS: Generic Real Time Surgery Simulation | p. 16 |
| Simulating Needle Insertion and Radioactive Seed Implantation for Prostate Brachytherapy | p. 19 |
| In-Vivo and In-Situ Compressive Properties of Porcine Abdominal Soft Tissues | p. 26 |
| A VR-System Supporting Symmetry Related Cranio-Maxillofacial Surgery | p. 33 |
| Analyzing the MMVR Research Space: Past Emphases, Future Directions | p. 36 |
| Online Training Evaluation in VR Simulators using Gaussian Mixture Models | p. 42 |
| Quantifying Expert vs. Novice Skill In Vivo for Development of a Laryngoscopy Simulator | p. 45 |
| Modelling Human Burn Injuries in a Three-dimensional Virtual Environment | p. 52 |
| Novel Algorithms for Polarization Imaging Resulting in Improved Quantification of Retinal Blood Vessels | p. 59 |
| 3D Tooth Shape from Radiographs using Thin-plate Splines | p. 62 |
| The Virtual Craniofacial Patient: 3D Jaw Modeling and Animation | p. 65 |
| Dynamic MR-mammography in Virtual Reality | p. 72 |
| Development of an Interactive Teaching System based on Motion Synchrony between Physical and Virtual Models | p. 79 |
| 3D Visualization Methods to Guide Surgery for Parkinson's Disease | p. 86 |
| Realistic Virtual Endoscopy of the Ventricle System and Haptic-based Surgical Simulator of Hydrocefalus Treatment | p. 93 |
| Cybercare: Virtual Reality Technologies for Homeland Defense | p. 96 |
| Trauma Team Training in a Distributed Virtual Emergency Room | p. 100 |
| Comparing a Simplified FEM Approach with the Mass-Spring Model for Surgery Simulation | p. 103 |
| A Robotic Surgery System (da Vinci) with Image Guided Function--System Architecture and Cholecystectomy Application | p. 110 |
| Real-time 3D Deformation Imaging of Abdominal Organs in Laparoscopy | p. 117 |
| Metrics and Motion Analysis for Assessment of Surgical Skills | p. 124 |
| Lessons Learned in Modeling Virtual Pediatric Patients | p. 127 |
| Surface Transparency Makes Stereo Overlays Unpredictable: The Implications for Augmented Reality | p. 131 |
| Independent Testing of Soft Tissue Visco-elasticity using Indentation and Rotary Shear Deformations | p. 137 |
| A Haptic Sensor-Actor-System based on Ultrasound Elastography and Electrorheological Fluids for Virtual Reality Applications in Medicine | p. 144 |
| An Augmented Reality System for MRI-guided Needle Biopsies | p. 151 |
| Physically Based Hybrid Approach in Real Time Surgical Simulation with Force Feedback | p. 158 |
| Virtual Simulated Patients for Bioterrorism Preparedness Training | p. 165 |
| Development of New Three-dimensional Endoscopic Ultrasound System through Endoscope Shape Monitoring | p. 168 |
| Automatic Segmentation of the Liver for Preoperative Planning of Resections | p. 171 |
| Training Brain Retraction in a Virtual Reality Environment | p. 174 |
| The Wireless and Paperless E.R.: An Economical and Ergonomic Approach | p. 181 |
| Eye Trackers in a Virtual Laparoscopic Training Environment | p. 184 |
| A Haptic Needle Manipulation Simulator for Chinese Acupuncture | p. 187 |
| Real-time Web-based Telerehabilitation Monitoring | p. 190 |
| Development and Evaluation of a Simulator of Invasive Procedures in Pediatric Bone Marrow Transplant | p. 193 |
| Validation of Medical Modeling and Simulation Training Devices and Systems | p. 196 |
| Inclusion of 3-D Computed Tomography Rendering and Immersive VR in a Third Year Medical Student Surgery Curriculum | p. 199 |
| A Surgical Simulator for Cleft Lip Planning and Repair | p. 204 |
| Virtual Instruments: A Generalized Implementation | p. 210 |
| A Part-task Approach to Haptic Knee Arthroscopy Training | p. 216 |
| Validation of a Web-based Training Tool for Lumbar Puncture | p. 219 |
| The Operating Room of the Future: White Paper Summation | p. 226 |
| Real-time PC Based X-ray Simulation for Interventional Radiology Training | p. 233 |
| Evaluation of a Novel Electronic Fetal Monitor Simulator | p. 240 |
| Virtual Reality Therapy in Aid of Senior Citizens' Psychological Disorders | p. 245 |
| Use of an Augmented Reality Display of Patient Monitoring Data to Enhance Anesthesiologists' Response to Abnormal Clinical Events | p. 248 |
| 4-Dimensional Computer-based Motion Simulation after Total Hip Arthroplasty | p. 251 |
| Stereo Visualization of 3D Trabecular Bone Structures Produced by Bone Remodelling Simulation | p. 258 |
| The Augmented-feedback Rehabilitation Technique Facilitates the Arm Motor Recovery in Patients after a Recent Stroke | p. 265 |
| Interrogative Visualization: Embedding Deformation and Constructive Solid Geometry into Volume Visualization | p. 268 |
| Visible Human 2.0--The Next Generation | p. 275 |
| Force-Torque Input Enhances Medical VR Applications | p. 282 |
| The Joy Stick: A New Force-Input-Device for a Multi-modal Desktop Simulator | p. 285 |
| Development of a Training Tool for Endotracheal Intubation: Distributed Augmented Reality | p. 288 |
| Minimally Invasive Surgery Task Decomposition--Etymology of Endoscopic Suturing | p. 295 |
| Virtual Visit: Improving Communication for Those Who Need It Most | p. 302 |
| Evaluation of INPRES--Intraoperative Presentation of Surgical Planning and Simulation Results | p. 309 |
| Medarpa--A Medical Augmented Reality System for Minimal-invasive Interventions | p. 312 |
| Four-dimensional Analysis of Mandibular Movements with Optical Position Measuring and Real-time Imaging | p. 315 |
| Wireless Virtual Instrument Measurement of Surgeons' Physical and Mental Workloads for Robotic versus Manual Minimally Invasive Surgery | p. 318 |
| Stereo Imagery from the UNC Augmented Reality System for Breast Biopsy Guidance | p. 325 |
| Facilitating Real-time Volume Interaction | p. 329 |
| CELTS: A Clinically-based Computer Enhanced Laparoscopic Training System | p. 336 |
| Simulation of a Preperitoneal Mesh in laparoscopic Herniorrhaphy | p. 343 |
| Development of Dynamic Spatial Video Camera (DSVC) for 4D Observation, Analysis and Modeling of Human Body Locomotion | p. 346 |
| Development of an Endoscopic Robot System with Two Hands for Various Gastric Tube Surgeries | p. 349 |
| Dynamic Deformation of Elastic Organ Model and the VR Cockpit for Virtual Surgery and Tele-surgery | p. 354 |
| Wearable Schizophrenia Treatment with Real-time Affective Context Awareness | p. 357 |
| 3D Reconstruction of Organ Surfaces using Model-based Snakes | p. 360 |
| Development of a Data Fusion System using Color Information for Real-time Intraoperative Liver Surface Measurement | p. 367 |
| Neuro VRAC--A Comprehensive Approach to Virtual Reality-based Neurological Assessment and Treatment Systems | p. 370 |
| Measurements of the Level of Surgical Expertise using Flight Path Analysis from da Vinct Robotic Surgical System | p. 373 |
| Transatlantic Medical Education: Preliminary Data on Distance-based High-fidelity Human Patient Simulation Training | p. 379 |
| Real-time Volumetric Deformation for Surgical Simulation using Force Feedback Device | p. 386 |
| Web-access to a Lung Deposition Model for Radiation Protection and Physiological Modeling | p. 389 |
| Virtual Reality and Interactive 3D as Effective Tools for Medical Training | p. 392 |
| A Mobile and Navigated Image Viewer for Surgery--Evaluation of Precision | p. 395 |
| A Hybrid Condensed Finite Element Model for Interactive 3D Soft Tissue Cutting | p. 401 |
| Medical Biomodelling in Surgical Applications: Results of a Multicentric European Validation of 466 Cases | p. 404 |
| Anatomically Accurate Individual Face Modeling | p. 407 |
| Development of a Computer Assisted Craniofacial Surgery Planning System | p. 410 |
| Engineering Requirements for a Haptic Simulator for Knee Arthroscopy Training | p. 413 |
| Author Index | p. 419 |
| Table of Contents provided by Rittenhouse. All Rights Reserved. |
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