R_Bibb_Medical_Modelling_The_Application_of_Adv.pdf

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Case studies 275 7. Cheah C M, Chua C K, Tan K H (2003), ‘Integration of laser surface digitizing with CAD/CAM techniques for developing facial prostheses Part 2: Development of molding techniques for casting prosthetic parts’, International Journal of Prosthodontics, 16 (5), 543–8. 8. Verdonck H W D, Poukens J, Overveld H V, Riediger D (2003), ‘Computerassisted maxillofacial prosthodontics: a new treatment protocol’, International Journal of Prosthodontics, 16 (3), 326–8. 9. Reitemeier B, Notni G, Heinze M, Schone C, Schmidt A, Fichtner D (2004), ‘Optical modeling of extraoral defects’, Journal of Prosthetic Dentistry, 91 (1), 80–84. 10. Tsuji M, Noguchi N, Ihara K, Yamashita Y, Shikimori M, Goto M (2004), ‘Fabrication of a maxillofacial prosthesis using a computer-aided design and manufacturing system’, Journal of Prosthodontics, 13 (3), 179–83. 11. Eggbeer D, Evans P, Bibb R (2004), ‘The application of computer aided techniques in facial prosthetics’, Abstract in the Proceedings of the 6 th International Congress on Maxillofacial Rehabilitation, Maastricht, The Netherlands, June, 55. 12. Evans P, Eggbeer D, Bibb R (2004), ‘Orbital prosthesis wax pattern production using computer aided design and rapid prototyping techniques’, Journal of Maxillofacial Prosthetics and Technology, 7, 11–15. 13. Piérard GE, Uhoda I, Piérard-Franchimont C (2003), ‘From skin micro relief to wrinkles: an area ripe for investigation’, Journal of Cosmetic Dermatology, 2 (1), 21–8. 14. Hashimoto K (1974), ‘New methods for surface ultra structure: comparative studies scanning electron microscopy and replica method’, International Journal of Dermatology, 13 (6), 357–81. 15. Lemperle G, Holmes R E, Cohen S R, Lemperle S M (2001), ‘A classifi cation of facial wrinkles’, Plastic Reconstructive Surgery, 108, 1735–50. 16. Holman C D J, Armstrong B K, Evans P R, Lumsden G J, Dallimore K J, Meehan C J, Beagley J, Gibson I M (1984), ‘Relationship of solar keratosis and history of skin cancer to objective measures of actinic skin damage’, British Journal of Dermatology, 110 (2), 129–38. 17. Park S G, Kim Y D, Kim J J, Kang S H (1999), ‘Two possible classifi cations of facial skin type by two parameters in Korean women: sebum excretion rate (SER) and skin surface relief (SSR)’, Skin Research Technology, 5, 189–94. 18. Yean C K, Kai C C, Ong T, Feng L (1998), ‘Creating machinable textures for CAD/CAM systems’, International Journal of Advanced Manufacturing Technologies, 14, 269–79.
7.1 Background 276 7 Future developments Several areas of development combine the advantages of computer-aided design (CAD), rapid prototyping (RP) and medical applications. Materials development is progressing in RP, and this is opening up new opportunities to use objects made by RP techniques directly in medical treatments or to manufacture medical devices. For example, the direct manufacture of hearing aid shells is currently being developed and marketed by more than one medical device company. The ability to process fully dense functional metals in RP machines is also of particular interest in the manufacture of custom-designed implants. Machines are already undergoing research in the application of materials such as stainless steel, and the potential to employ titanium is seen by many researchers as an excellent opportunity. Tissue engineering is a fascinating area of development, and CAD and RP approaches are being actively developed in many research centres to facilitate the direct manufacture of custom fi tting tissue scaffolds or even living tissue constructs. The potential to construct living tissue replacements for damaged or missing organs and bones is challenging but may ultimately reduce our dependence on organ donors and save many lives. As can be seen, by considering the technological development discussed below the future has a great deal of potential for everyone working in this varied and challenging but, ultimately, highly rewarding fi eld. 7.2 Scanning techniques Computed Tomography (CT) scanning continues to develop although this tends to be incremental. More sensitive detectors are allowing X-ray doses to be lowered whilst capturing more data at smaller pixel sizes. The use of multiple arrays of detectors is drastically reducing scanning times. The improving ability to collimate the X-ray beams is allowing much thinner
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Medical modelling
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Medical modelling The application o
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Contents Preface ix Acknowledgement
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Contents vii 6.10 Rehabilitation ap
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x Preface Therefore, it is hoped th
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1.1 Background 1 Introduction The p
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Introduction 3 Whilst this book is
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Long axis 1.1 The anatomical positi
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Introduction 7 1.3 The major refere
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Medical imaging for rapid prototypi
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2.2.3 Anatomical coverage Medical i
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2.6 X-ray scatter artefact in a CT
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2.9 Close up of noise. Medical imag
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2.12 Smooth data. Medical imaging f
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1 Medical imaging for rapid prototy
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Export data format and media 33 (NE
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3.3 Media Export data format and me
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4.1 Pixel data operations 4 Working
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4.3 Effect of a high threshold. 4.4
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Working with medical scan data 41 4
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Working with medical scan data 45 S
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4.4 Two-dimensional formats Working
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Working with medical scan data 51 I
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4.18 Close up view showing facets.
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5.1 Background to rapid prototyping
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Physical reproduction 61 developing
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Physical reproduction 63 will displ
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Physical reproduction 65 As there i
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Physical reproduction 67 However, t
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Data quality Physical reproduction
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Physical reproduction 71 In some ca
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Physical reproduction 73 Overhangin
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Physical reproduction 75 5.10 SL mo
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Physical reproduction 77 5.12 Selec
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5.13 A Perfactory ® model of a man
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5.15 FDM TM model of the mandible.
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Table 5.3 Advantages and disadvanta
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Physical reproduction 85 In medical
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Table 5.5 Advantages and disadvanta
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5.7 Jetting head technology 5.7.1 P
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5.23 ThermoJet ® model of the mand
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5.24 LOM TM model of the mandible.
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5.26 LOM TM model of a partial face
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6 Case studies The following case s
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IMPLEMENTATION 6.1 Implementation c
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Post model Hospital department Pati
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Case studies 103 When using this so
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Case studies 105 (Mimics). Image ma
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Case studies 107 full co-operation
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Case studies 109 communication and
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• to achieve patient’s agreemen
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6.2.4 Rapid prototyping technologie
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Case studies 115 not be suitable. A
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Case studies 117 scale of the data
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6.7 SL model with signifi cant stai
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Case studies 121 6.9a Smooth surfac
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Case studies 123 slice editing of t
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Case studies 125 6.12 Removal of bo
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Case studies 127 18. Williams R J,
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Case studies 129 and passing throug
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Case studies 131 6.14 The effect of
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Case studies 133 6.18 The block ove
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Case studies 135 create template (3
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6.4.3 Materials and methods Case st
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6.22 Resected bone compared to SLA
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Case studies 141 9. Robinson R P, C
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Case studies 143 multi-plane reform
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Case studies 145 6.25 The custom ti
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Case studies 147 6.28 Plain radiogr
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Case studies 149 reproduction of ex
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Case studies 151 manner. The softwa
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Case studies 153 surface on which t
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6.33 The guide being fi tted to the
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Case studies 157 The more fundament
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Case studies 159 25. Sarment D P, A
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6.37 Stereolithography models. 6.38
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Case studies 163 6.41 Merged pre- a
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REHABILITATION APPLICATIONS 6.8 Reh
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6.8.3 Methods Preliminary trial of
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Case studies 169 prototyping system
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Case studies 171 The aperture for t
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Case studies 173 7. Manners C R (19
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Case studies 175 during the acquisi
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6.46 Smoothing the data (exaggerate
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6.49 Plaster fi lled SL mould. Case
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Case studies 181 diffi cult for hos
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Case studies 183 extremely diffi cu
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Case studies 185 back as shown in F
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6.54 The result of the Boolean subt
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6.56 The SLA model of the plate. Ca
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6.59 SLA implant on SLA model of de
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Case studies 193 In the near future
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Case studies 195 anatomical forms a
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Case studies 197 Establishing the c
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Case studies 199 6.63 The rough (a)
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Case studies 201 The fi nal prosthe
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Case studies 203 grating the techno
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Case studies 205 6.12 Rehabilitatio
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Case studies 207 • Data capture N
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Case studies 209 placement of two i
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Case studies 211 technique that has
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Case studies 213 6.72 The bar locat
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Case studies 215 Stereolithography
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Case studies 217 authors intend to
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Case studies 219 17. Kau C H, Zhuro
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Case studies 221 310, Sainte-Foy, Q
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6.77a The physically surveyed cast.
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Page 240 and 241: 6.81 Construction curves. Case stud
Page 242 and 243: 6.83 The support structure in 3D Li
Page 244 and 245: Finishing Case studies 231 The cast
Page 246 and 247: Case studies 233 6.14 Rehabilitatio
Page 248 and 249: 6.86 The RPD framework designed in
Page 250 and 251: Second experiment Case studies 237
Page 252 and 253: Case studies 239 6.90 Close up view
Page 254 and 255: Table 6.2 Process steps and associa
Page 256 and 257: Case studies 243 9. Budtz-Jorgensen
Page 258 and 259: Case studies 245 micro-computed tom
Page 260 and 261: Case studies 247 supports became av
Page 262 and 263: Case studies 249 However, the probl
Page 264 and 265: 6.96 Model of one of the samples su
Page 266 and 267: 6.15.9 Reference Case studies 253 1
Page 268 and 269: Case studies 255 mummies. Mimics so
Page 270 and 271: Case studies 257 6.101 3D reconstru
Page 272 and 273: Case studies 259 6.103 The stages o
Page 274 and 275: 6.16.5 Conclusions Case studies 261
Page 276 and 277: Case studies 263 the patient’s de
Page 278 and 279: Case studies 265 and sharp radii re
Page 280 and 281: Suitable technologies identifi ed C
Page 282 and 283: Case studies 269 6.107 A close-up p
Page 284 and 285: 6.110 The selected region of facial
Page 286 and 287: Case studies 273 patterns were buil
Page 290 and 291: Future developments 277 slices to b
Page 292 and 293: Future developments 279 ments that
Page 294 and 295: Glossary and explanatory notes 281
Page 296 and 297: Glossary and explanatory notes 283
Page 298 and 299: Further reading on anatomy Last’s
Page 300 and 301: Fundamentals of Facial Prosthetics
Page 302 and 303: Rapid Prototyping and Tooling Resea
Page 304 and 305: Contacts 3D Systems 26081 Avenue Ha
Page 306 and 307: Marcam Engineering GmbH Fahrenheits
Page 308 and 309: 3D Lightyear TM 229, 247, 249-51, 2
Page 310: Removable Partial Denture 219-20, 2
Page 313 and 314: 4.10 A three-dimensional shaded ima
Page 315: 6.41 Merged pre- and post-operative
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