PURPOSE: To compare the accuracy of a navigation system for oral implantology using either a head-mounted display (HMD) or a monitor as a device for visualization. METHODS: Drilling experiments in plastic mandibles were performed by seven investigators supported by a navigation system using an HMD. A set of drilling experiments was carried out using a traditional monitor setup as standard of reference. Prior to the experiments, CT scans of the mandibles were performed. Positions of the boreholes were determined with the planning software Mimics[Formula: see text]. In order to find the correct positions of the boreholes, individuals had to match two pairs of crosshairs. By an infrared tracking device, the navigation system was able to spot the artificial jaw and the angular piece of the drill allowing for the navigation. After the experiments, a second CT scan was acquired: (i) to identify the beginning and the end of the boreholes, (ii) to compare the positions of the planned implant and the boreholes and (iii) to calculate the deviations. RESULTS: Overall deviation of the starting point of the borehole was 1.24 ± 0.84 mm for the HMD and 1.12 ± 0.68 mm for the monitor, 2.68 ± 1.65 mm of the end point of the borehole for the HMD and 2.46 ± 1.34 mm for the monitor. The mean deviation of the axis was 4.68◦ ± 3.7◦ for the HMD and 4.53◦ ± 4.17◦ for the monitor. CONCLUSIONS: As overall accuracies do not differ significantly, the two methods seem to be equal. Personal skills seem to be crucial as the results show remarkable differences among the test persons. The results of our study demonstrate that the use of an HMD has no major drawbacks compared to the monitor setting. The striking advantage is that the surgeon is no longer obliged to turn his head away from the operation site during navigation, as all data relevant for the procedure are superimposed on the image of the real world in his field of view.
PURPOSE: To compare the accuracy of a navigation system for oral implantology using either a head-mounted display (HMD) or a monitor as a device for visualization. METHODS: Drilling experiments in plastic mandibles were performed by seven investigators supported by a navigation system using an HMD. A set of drilling experiments was carried out using a traditional monitor setup as standard of reference. Prior to the experiments, CT scans of the mandibles were performed. Positions of the boreholes were determined with the planning software Mimics[Formula: see text]. In order to find the correct positions of the boreholes, individuals had to match two pairs of crosshairs. By an infrared tracking device, the navigation system was able to spot the artificial jaw and the angular piece of the drill allowing for the navigation. After the experiments, a second CT scan was acquired: (i) to identify the beginning and the end of the boreholes, (ii) to compare the positions of the planned implant and the boreholes and (iii) to calculate the deviations. RESULTS: Overall deviation of the starting point of the borehole was 1.24 ± 0.84 mm for the HMD and 1.12 ± 0.68 mm for the monitor, 2.68 ± 1.65 mm of the end point of the borehole for the HMD and 2.46 ± 1.34 mm for the monitor. The mean deviation of the axis was 4.68◦ ± 3.7◦ for the HMD and 4.53◦ ± 4.17◦ for the monitor. CONCLUSIONS: As overall accuracies do not differ significantly, the two methods seem to be equal. Personal skills seem to be crucial as the results show remarkable differences among the test persons. The results of our study demonstrate that the use of an HMD has no major drawbacks compared to the monitor setting. The striking advantage is that the surgeon is no longer obliged to turn his head away from the operation site during navigation, as all data relevant for the procedure are superimposed on the image of the real world in his field of view.
Authors: Felix Wanschitz; Wolfgang Birkfellner; Michael Figl; Sanda Patruta; Arne Wagner; Franz Watzinger; Kaan Yerit; Kurt Schicho; Rudolf Hanel; Franz Kainberger; Herwig Imhof; H Bergmann; Rolf Ewers Journal: Clin Oral Implants Res Date: 2002-12 Impact factor: 5.977
Authors: Thomas Wenger; Stephan Nowatschin; Wolfgang Wittmann; Florian Hurka; Gero Strauss; Tim C Lueth Journal: Conf Proc IEEE Eng Med Biol Soc Date: 2011
Authors: M Siessegger; B T Schneider; R A Mischkowski; F Lazar; B Krug; B Klesper; J E Zöller Journal: J Craniomaxillofac Surg Date: 2001-10 Impact factor: 2.078
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