Background:Augmented reality (AR) technology that can combine computer-generated images with a real scene has been reported in the medical field recently. We devised the AR system for evaluation of improvements of the body surface, which is important for plastic surgery.Methods:We constructed an AR system that is easy to modify by combining existing devices and free software. We superimposed the 3-dimensional images of the body surface and the bone (obtained from VECTRA H1 and CT) onto the actual surgical field by Moverio BT-200 smart glasses and evaluated improvements of the body surface in 8 cases.Results:In all cases, the 3D image was successfully projected on the surgical field. Improvement of the display method of the 3D image made it easier to distinguish the different shapes in the 3D image and surgical field, making comparison easier. In a patient with fibrous dysplasia, the symmetrized body surface image was useful for confirming improvement of the real body surface. In a patient with complex facial fracture, the simulated bone image was useful as a reference for reduction. In a patient with an osteoma of the forehead, simultaneously displayed images of the body surface and the bone made it easier to understand these positional relationships.Conclusions:This study confirmed that AR technology is helpful for evaluation of the body surface in several clinical applications. Our findings are not only useful for body surface evaluation but also for effective utilization of AR technology in the field of plastic surgery.
Background:
The positioning of the auricle is a key factor in successful ear reconstruction. However, the position of the ear is usually determined by transferring the auricle image of the nonaffected side to the affected side using a transparent film. Augmented reality (AR) is becoming useful in the surgical field allowing computer-generated images to be superimposed on patients. In this report, we would like to introduce an application of AR technology in ear reconstruction.
Methods:
AR technology was used to determine the position of the reconstructed ear of a 10-year-old male with right microtia. Preoperative 3-dimensional photographs of the nonaffected side were taken using VECTRAH1. Then, the image was horizontally inverted and superimposed on the three-dimensional image of the affected side with reference to the anatomical landmarks of the patient’s face. These images were projected onto the patient in the operation room using Microsoft’s HoloLens. The design and positioning of the auricle was done with reference to the AR image. To confirm the accuracy of the AR technique, we compared it to the original transparent film technique. After the insertion of the cartilage framework into the skin pocket, the position and shape of the reconstructed ear was confirmed using the AR technology.
Results:
The positioning of the reconstructed ear was successfully performed. The deviation between the 2 designated positions using the AR and the transparent film was within 2 mm.
Conclusion:
The AR technology is a promising option in the surgical treatment of microtia.
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