Case reports of the use of AR inĬONTACT Kai 2017 Informa UK Limited, trading as Taylor & Francis Group In modern patient-centred healthcare is a relatively The development and use of AR and 3D printing Layer until the objects are created (Chua and LeongĢ014). Physical objects from digital design, usually layer upon Polylactic acid (PLA) (Chua and Leong 2014) and acrylonitrile–butadiene–styrene (Lee et al. It is an additive manufacturing process of laying down successive materials such as Overlaying computer-generated virtual enhancements In contrast, augmented reality (AR) enhances viewer’s perception by Virtual reality (VR) immerses viewer through computergenerated simulation of the real world. Photographic experts group MRI: magnetic resonance imaging PLA: polylactic acid ROI: region Reality CAD: computer-aided design CT: computed tomography DICOM: Digital Imaging andĬommunication in Medicine FBX: Filmbox FDM: fused deposition modelling JPEG: joint Powerful medium in specialties where difficult anatomical challenges are encountered.Ībbreviations: ABS: acrylonitrile–butadiene–styrene AM: additive manufacturing AR: augmented Technologies can be used as an invaluable patient education and counselling tool offering a Medical data visualisation feasible and tangible on a mobile device and in hand.
TheĪdvancement of AR and 3D printing technologies are making complex and patient-specific 3D Understanding complex skull base anatomy and progressive disease such as cholesteatoma.
AR and 3D printing allow patient-specific clinical information andĬomplexities to be made readily available to the patient and doctor at low cost, and aid in Patient’s temporal bone was alsoįabricated through a fused deposition modelling 3D printer using polylactic acid filament for Which was then published to the Hyperspaces cloud server to build an AR application for freeĪccess using a predefined keyword on an iOS mobile device. BothģD and 2D assets were uploaded, linked in an AR development platform called Hyperspaces A two-dimensional (2D) image was created as an AR recognition marker.
#HYPERSPACES AUGMENTED REALITY SOFTWARE#
Tomography (CT) scans using CAD (computer-aided design) software to display theĬholesteatoma affected temporal bone and related structures.
#HYPERSPACES AUGMENTED REALITY SERIES#
Series of 3D models were constructed from a patient’s petrous temporal bone computed We wish to demonstrate theĭevelopment and use of augmented reality (AR) technology and three-dimensional (3D) printing toĪssist in preoperative patient consultation in the case of a complex skull base cholesteatoma. Of disease and anatomy, perceived risks, and complications of surgery. Temporal bone and skull base anatomy is complex and can pose difficulties in patient’s perception Vestibular Research Laboratory, School of Psychology, The University of Sydney, Sydney, Australia bInstitute of Academic Surgery Royal Prince Kai Chenga, Payal Mukherjeeb and Ian Curthoysa
Virtual and Physical Prototyping, DOI: 10.1080/17452759.2017.1310050įull Terms & Conditions of access and use can be found atĭevelopment and use of augmented reality and 3D printing in consulting patient Of augmented reality and 3D printing in consulting patient with complex skull base cholesteatoma, To cite this article: Kai Cheng, Payal Mukherjee & Ian Curthoys (2017): Development and use Kai Cheng, Payal Mukherjee & Ian Curthoys ISSN: 1745-2759 (Print) 1745-2767 (Online) Journal homepage: ĭevelopment and use of augmented reality andģD printing in consulting patient with complex
0 kommentar(er)
