Medical Modelling : The Application of Advanced Design and Rapid Prototyping Techniques in Medicine.

Front Cover -- Front Matter -- Contents -- Woodhead Publishing Series in Biomaterials -- Preface -- Acknowledgements -- 1 - Introduction -- 1.1 Background -- 1.2 The human form -- 1.3 Basic anatomical terminology -- 1.4 Technical terminology -- 2 - Medical imaging -- 2.1 Introduction to medical imaging -- 2.2 Computed tomography (CT) -- 2.3 Cone beam CT (CBCT) -- 2.4 Magnetic resonance (MR) -- 2.5 Noncontact surface scanning -- 2.6 Medical scan data -- 2.7 Point cloud data -- 2.8 Media -- References -- Recommended reading -- 3 - Working with medical scan data -- 3.1 Pixel data operations -- 3.2 Using CT data: a worked example -- 3.3 Point cloud data operations -- 3.4 Two-dimensional formats -- 3.5 Pseudo 3D formats -- 3.6 True 3D formats -- 3.7 File management and exchange -- 4 - Physical reproduction -- 4.1 Background to rapid prototyping -- 4.2 Stereolithography -- 4.3 Digital light processing -- 4.4 Fused deposition modelling -- 4.5 Laser sintering -- 4.6 Powder bed 3D printing -- 4.7 Material jetting technology -- 4.8 Laminated object manufacture -- 4.9 Computer numerical controlled machining -- 4.10 Cleaning and sterilising medical models -- 5 - Case Studies -- Introduction -- Implementation -- Acknowledgements -- 5.1.1 Introduction -- 5.1.2 CT guidelines for medical modelling -- 5.1.3 Conclusion -- Acknowledgements -- References -- 5.2 Implementation case study 2: the development of a collaborative medical modelling service - organisational and technical con... -- Acknowledgements -- 5.2.1 Introduction -- 5.2.2 Aims of medical modelling collaboration -- 5.2.3 Implementation -- 5.2.4 Discussion -- 5.2.5 Conclusions -- 5.2.6 Update -- References -- 5.3 Implementation case study 3: medical rapid prototyping technologies - state of the art and current limitations for applicati... -- Acknowledgements -- 5.3.1 Introduction.

5.3.2 3D image acquisition and processing for MRP -- 5.3.3 RP technologies -- 5.3.4 Medical rapid prototyped model artefacts -- 5.3.5 Conclusion -- 5.3.6 Update -- References -- Surgical applications -- 5.4 Surgical applications case study 1: planning osseointegrated implants using computer-aided design and rapid prototyping -- Acknowledgments -- 5.4.1 Introduction -- 5.4.2 Proposed approach -- 5.4.3 Scanning problems -- 5.4.4 Software problems -- 5.4.5 Illustrative case study -- 5.4.6 Results -- 5.4.7 Benefits and future development -- 5.4.8 Update -- References -- 5.5 Surgical applications case study 2: rapid manufacture of custom-fit surgical guides -- Acknowledgments -- 5.5.1 Introduction -- 5.5.2 Methods -- 5.5.3 Case study -- 5.5.4 Results -- 5.5.5 Discussion -- 5.5.6 Conclusions -- 5.5.7 Update -- References -- 5.6 Surgical applications case study 3: use of a reconstructed three-dimensional solid model from computed tomography to aid in ... -- Acknowledgments -- 5.6.1 Introduction -- 5.6.2 Materials and methods -- 5.6.3 Postoperative management and follow-up -- 5.6.4 Discussion -- References -- 5.7 Surgical applications case study 4: custom-made titanium orbital floor prosthesis in reconstruction for orbital floor fractu... -- Acknowledgments -- 5.7.1 Introduction -- 5.7.2 Technique -- 5.7.3 Case report -- 5.7.4 Conclusion -- References -- 5.8 Surgical applications case study 5: use of three-dimensional technology in the multidisciplinary management of facial dispro... -- Acknowledgments -- 5.8.1 Introduction -- 5.8.2 Materials and methods -- 5.8.3 Results -- 5.8.4 Discussion -- References -- 5.9 Surgical applications case study 6: appropriate approach to computer-aided design and manufacture of reconstructive implants... -- Acknowledgments -- 5.9.1 Introduction -- 5.9.2 Case 1: orbital rim augmentation implant.

5.9.3 Case 2: orbital floor implant incorporating placement guide -- 5.9.3.1 Materials and methods -- 5.9.4 Case 3: multipart reconstruction -- 5.9.4.1 Materials and methods -- 5.9.5 Case 4: posttraumatic zygomatic osteotomy and orbital floor reconstruction -- References -- 5.10 Surgical applications case study 7: computer-aided planning and additive manufacture for complex, mid-face osteotomies -- Acknowledgments -- 5.10.1 Introduction -- 5.10.2 Methods -- 5.10.3 Results -- 5.10.4 Discussion -- 5.10.5 Conclusions -- References -- Maxillofacial rehabilitation -- Acknowledgments -- 5.11.1 Introduction -- 5.11.2 Methods -- 5.11.3 Results -- 5.11.4 Update -- References -- 5.12 Maxillofacial rehabilitation case study 2: producing burns therapy conformers using noncontact scanning and rapid prototyp... -- Acknowledgements -- 5.12.1 Introduction -- 5.12.2 Methods -- 5.12.3 Results -- 5.12.4 Discussion -- 5.12.5 Conclusions -- References -- 5.13 Maxillofacial rehabilitation case study 3: an appropriate approach to computer-aided design and manufacture of cranioplas... -- Acknowledgements -- 5.13.1 Introduction -- 5.13.2 Initial case -- 5.13.3 Second case -- 5.13.4 Third case: press tool design -- 5.13.5 Fourth case: implant design for AM fabrication -- 5.13.6 Future development and benefits -- References -- 5.14 Maxillofacial rehabilitation case study 4: evaluation of advanced technologies in the design and manufacture of an implant ... -- Acknowledgements -- 5.14.1 Introduction -- 5.14.2 Existing facial prosthetics technique -- 5.14.3 Review of advanced technologies in facial prosthetics -- 5.14.4 Case 1 -- 5.14.5 Case 2 -- 5.14.6 Results -- 5.14.7 Discussion -- 5.14.8 Conclusions -- References -- 5.15 Maxillofacial rehabilitation case study 5: rapid prototyping technologies in soft-tissue facial prosthetics - current state... -- Acknowledgements.

5.15.1 Introduction -- 5.15.2 Methodology -- 5.15.3 Summary of case studies -- 5.15.4 Discussion -- 5.15.5 RP&amp -- M Specification -- 5.15.6 Conclusions -- References -- 5.16 Maxillofacial rehabilitation case study 6: evaluation of direct and indirect additive manufacture of maxillofacial prosthes... -- Acknowledgements -- 5.16.1 Introduction -- 5.16.2 Methods -- 5.16.3 Results -- 5.16.4 Discussion -- 5.16.5 Conclusions -- References -- 5.17 Maxillofacial rehabilitation case study 7: computer-aided methods in bespoke breast prosthesis design and fabrication -- Acknowledgements -- 5.17.1 Introduction -- 5.17.2 Methods -- 5.17.3 Discussion -- 5.17.4 Conclusions -- References -- Orthotic rehabilitation applications -- Acknowledgements -- 5.18.1 Introduction -- 5.18.2 Data acquisition methods -- 5.18.3 Conclusion and future work -- Acknowledgements -- References -- 5.19 Orthotic rehabilitation applications case study 2: comparison of additive manufacturing systems for the design and fabric... -- Acknowledgements -- 5.19.1 Introduction -- 5.19.2 Aim and objectives -- 5.19.3 Method -- 5.19.4 Results -- 5.19.5 Conclusions and future work -- Acknowledgements -- References -- 5.20 Orthotic rehabilitation applications case study 3: evaluation of a digitised splinting approach with multiple-material func... -- Acknowledgements -- 5.20.1 Introduction -- 5.20.2 Research aim and objectives -- 5.20.3 Methods -- 5.20.4 Results and discussion -- 5.20.5 Future work -- Acknowledgements -- References -- 5.21 Orthotic rehabilitation applications case study 4: digitisation of the splinting process - development of a CAD strategy fo... -- Acknowledgements -- 5.21.1 Introduction -- 5.21.2 Current splinting techniques -- 5.21.3 Experimental procedures -- 5.21.4 Results -- 5.21.5 Conclusion -- Acknowledgements -- References.

5.22 Orthotic rehabilitation applications case study 5: evaluation of a refined 3D CAD workflow for upper extremity splint desig... -- Acknowledgements -- 5.22.1 Introduction -- 5.22.2 Method -- 5.22.3 Results and discussion -- 5.22.4 Conclusions and further work -- Acknowledgements -- References -- Dental applications -- 5.23 Dental applications case study 1: the computer-aided design and rapid prototyping fabrication of removable partial denture ... -- Acknowledgments -- 5.23.1 Introduction -- 5.23.2 Materials and methods -- 5.23.3 Conclusions -- References -- 5.24 Dental applications case study 2: trial fitting of an RDP framework made using CAD and RP techniques -- Acknowledgments -- 5.24.1 Introduction -- 5.24.2 Methods -- 5.24.3 Results -- 5.24.4 Discussion -- 5.24.5 Conclusions -- Acknowledgments -- References -- 5.25 Dental applications case study 3: direct additive manufacture of RPD frameworks -- Acknowledgments -- 5.25.1 Introduction -- 5.25.2 Methodology -- 5.25.3 Results -- 5.25.4 Discussion -- 5.25.5 Conclusions -- References -- 5.26 Dental applications case study 4: a comparison of plaster, digital and reconstructed study model accuracy -- Acknowledgments -- 5.26.1 Introduction -- 5.26.2 Materials and methods -- 5.26.3 Results -- 5.26.4 Discussion -- 5.26.5 Conclusions -- 5.26.6 Future work -- 5.26.7 Contributors -- References -- 5.27 Dental applications case study 5: design and fabrication of a sleep apnoea device using CAD/AM technologies -- Acknowledgments -- 5.27.1 Introduction -- 5.27.2 Methods and materials -- 5.27.3 Results -- 5.27.4 Discussion -- 5.27.5 Conclusion -- References -- 5.28 Dental applications case study 6: computer-aided design, CAM and AM applications in the manufacture of dental appliances -- Acknowledgments -- 5.28.1 Introduction -- 5.28.2 Material and methods -- 5.28.3 Results -- 5.28.4 Discussion.

5.28.5 Conclusion.

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Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.