Functional endoscopic sinus surgery training simulator.

OBJECTIVE/HYPOTHESIS: To determine the efficacy of a haptic (force feedback) device and to compare isosurface and volumetric models of a functional endoscopic sinus surgery (FESS) training simulator. STUDY DESIGN: A pilot study involving faculty and residents from the Department of Otolaryngology at The Ohio State University. METHODS: Objective trials evaluated the haptic device's ability to perceive three-dimensional shapes (stereognosis) without the aid of image visualization. Ethmoidectomy tasks were performed with both isosurface and volumetric FESS simulators, and surveys compared the two models. RESULTS: The haptic device was 77% effective for stereognosis tasks. There was a preference toward the isosurface model over the volumetric model in terms of visual representation, comfort, haptic-visual fidelity, and overall performance. CONCLUSIONS: The FESS simulator uses both visual and haptic feedback to create a virtual reality environment to teach paranasal sinus anatomy and basic endoscopic sinus surgery techniques to ear, nose, and throat residents. The results of the current study showed that the haptic device was accurate in and of itself, within its current physical limitations, and that the isosurface-based simulator was preferred.

Success of preoperative imaging and unilateral neck exploration for primary hyperparathyroidism.

The surgical treatment of hyperparathyroidism has become controversial with the recent advent of reliable preoperative imaging modalities. This study examines the efficacy and economy of using preoperative imaging studies to localize the pathology and allow for unilateral neck exploration. From January 1990 to May 1996, a total of 91 patients with primary hyperparathyroidism were treated at Swedish Medical Center in Seattle, WA, by 2 surgeons. Eighty-six nuclear scintigraphy studies were performed, of which 44 were technetium 99m sestamibi (Tc-99m-sestamibi) scans and 42 were thallium 99m technetium (Th-99m-Tc) scans. The overall sensitivity for Tc-99m-sestamibi was 91% (40/44), and that for Th-99m-Tc scans was 81% (34/42). Ultrasound examination revealed a sensitivity of 80% (66/82). There was a statistically significant difference in surgical time between the unilateral and bilateral neck explorations (45 minutes, P < 0.0001). Unilateral neck exploration for hyperparathyroidism has been successful in curing hypercalcemia 93% (85/91) of the time with the use of preoperative imaging studies. Tc-99m-sestamibi is a reliable tool for planning the initial unilateral neck exploration for treatment of primary hyperparathyroidism.

Virtual environments. Surgical simulation in otolaryngology.

Advanced technology in the form of computer-generated surgical simulation has tremendous potential as an adjunctive training aid to residents in training and experienced surgeons. This article explores the state-of-the-art in surgical simulation for otolaryngologists and future directions in this area.

A case of facial diplegia associated with acute bilateral otitis media.

A 32-month-old toddler developed facial diplegia in association with a bout of acute bilateral otitis media. After 28 days of antibiotic therapy and placement of tympanostomy tubes, the patient demonstrated 100% symmetrical recovery. A brief discussion of the pathophysiology is included.

Effects of blast overpressure on the ear: case reports.

The case histories of five patients who experienced blast overpressure in excess of 200-dB peak pressure level are presented. Despite the significance of the sound pressure levels received in a military training accident and the severe injuries that resulted from the blast, these individuals experienced substantial improvement of hearing 1 year later. Undoubtedly, successful surgical intervention and medical management were the primary contributors to the restoration of hearing. Audiometric data are presented documenting hearing status within 2 to 3 weeks postinjury and following final surgical remediation of the resulting middle ear damage. A review of these cases offers insight into the possible prognosis of patients with similar injuries.

Validation of the Madigan ESS simulator.

The Madigan Endoscopic Sinus Surgery (ESS) Simulator, developed by a multi-institution team led by Lockheed Martin, includes force-feedback instrument and virtual endoscope interaction with three-dimensional paranasal anatomy models derived from the Visible Human dataset, supplemented by a variety of graphical and auditory instructional aids embedded in the model. Our formal evaluation of Version 1.2 of the system focused on its validity as an ESS simulator. Run-time and survey data were collected for three groups of subjects on a common protocol progressing through the three basic ESS subtasks: navigation, injection, and dissection. Non-MD subjects performed the tasks on a simplified abstract virtual model with instructional aids (hoops for the navigation path, injection targets, dissection spheres, auditory feedback about task completion, and simulated patient heart rhythm). Non-ENT MDs progressed from this "novice" model to a simulated anterior ethmoidectomy on an "intermediate" model with the aids embedded in the reconstructed and segmented paranasal anatomy. Otolaryngologists ranging from second-year ENT residents through senior staff progressed through both the abstract and intermediate models, and then performed the simulated surgical procedure on an "advanced" model, consisting of the anatomy with no instructional aids. The procedural validity of the simulator is supported by a strong correlation between performance on the simulator and degree of prior ESS experience, by convergent correlation among independent measures of subject task performance, and by subjective evaluations by experienced ESS surgeons.

ENT endoscopic surgical training simulator.

This paper describes work in progress on the design and development of a prototype simulator for minimally invasive otolaryngology surgical training. The anatomy of the paranasal sinuses is geometrically complex and dangerously close to the brain and orbits, making this procedure challenging to practice and difficult to learn. We discuss the potential role of computer simulation to enhance and accelerate acquisition of surgical skills. The design goals of the prototype include high-fidelity simulation of the endoscopic imagery and haptic cues of surgical palpation. The prototype enables endoscopic navigation and limited interactive tissue manipulation and dissection tasks on a virtual patient using realistic replicas of surgical tools. We present an overview of the system architecture with a discussion of the technological challenges, design issues and current status of the efforts.