T Ozel
John Wiley & Sons
e druk, 2016
9781118478929
Biomedical Devices – Design, Prototyping, and Manufacturing
Design, Prototyping, and Manufacturing
Specificaties
Gebonden, 208 blz.
|
Engels
John Wiley & Sons |
e druk, 2016
ISBN13: 9781118478929
Rubricering
Levertijd ongeveer 8 werkdagen
Samenvatting
Biomedical Devices: Design, Prototyping, and Manufacturing features fundamental discussions of all facets of materials processing and manufacturing processes across a wide range of medical devices and artificial tissues.
Represents the first compilation of information on the design, prototyping, and manufacture of medical devices into one volume
Offers in–depth coverage of medical devices, beginning with an introductory overview through to the design, manufacture, and applications
Features examples of a variety of medical applications of devices, including biopsy micro forceps, micro–needle arrays, wrist implants, spinal spacers, and fixtures
Provides students, doctors, scientists, and technicians interested in the development and applications of medical devices the ideal reference source
Specificaties
Inhoudsopgave
<p>CONTRIBUTORS ix</p>
<p>FOREWORD xi</p>
<p>1 Overview 1<br />Joaquim De Ciurana Gay, Tu¢grul Özel, and Lidia Serenó</p>
<p>1.1 Introduction, 1</p>
<p>1.2 Need for Medical Devices, 7</p>
<p>1.3 Technology Contribution to Medical Devices, 12</p>
<p>1.3.1 Subtractive Technologies, 13</p>
<p>1.3.2 Net–Shape Technologies, 13</p>
<p>1.3.3 Additive Technologies, 14</p>
<p>1.4 Challenges in the Medical Device Industry, 16</p>
<p>References, 17</p>
<p>2 Design Issues in Medical Devices 23<br />Inés Ferrer, Jordi Grabalosa, Alex Elias–Zuñiga, and Ciro Angel Rodriguez</p>
<p>2.1 Medical Device Development (MDD), 23</p>
<p>2.1.1 Biomedical Product Life Cycle, 24</p>
<p>2.1.2 Medical Device Development Process, 27</p>
<p>2.1.3 Medical Devices Design Process, 28</p>
<p>2.2 Case Study, 30</p>
<p>2.2.1 Scapholunate Interosseous Ligament, 30</p>
<p>2.2.2 Conceptual Design, 32</p>
<p>2.2.3 Embodiment Design, 35</p>
<p>2.2.4 Detailed Design, 36</p>
<p>2.2.5 Manufacturing a Prototype, 36</p>
<p>2.2.6 Tracheal Stent, 38</p>
<p>2.2.7 Conceptual Design, 39</p>
<p>2.2.8 Embodiment Design and Detail Design, 43</p>
<p>2.2.9 Manufacturing a Prototype, 45</p>
<p>2.3 Conclusions, 45</p>
<p>References, 46</p>
<p>3 Forming Applications 49<br />Karen Baylón, Elisabetta Ceretti, Claudio Giardini, and Maria Luisa Garcia–Romeu</p>
<p>3.1 Forming, 49</p>
<p>3.2 Typical Process Parameters, 52</p>
<p>3.2.1 Temperature, 52</p>
<p>3.2.2 Flow Stress, 53</p>
<p>3.2.3 Strain, 53</p>
<p>3.2.4 Strain Rate, 54</p>
<p>3.2.5 Tribology and Micro–Tribology, 54</p>
<p>3.3 Manufacturing Process Chain, 55</p>
<p>3.3.1 Manufacture of Alloys and Raw Materials, 55</p>
<p>3.3.2 Forming, 56</p>
<p>3.3.3 Machining and Finishing, 56</p>
<p>3.3.4 Coating, 56</p>
<p>3.3.5 Packaging and Sterilization, 56</p>
<p>3.4 Implantable Devices, 56</p>
<p>3.5 Bone Implants, 57</p>
<p>3.5.1 External Fracture Fixation, 57</p>
<p>3.5.2 Artificial Joint Replacement, 58</p>
<p>3.5.3 Spinal Implants, 68</p>
<p>3.5.4 Craniomandibular Implants, 68</p>
<p>3.5.5 Dental Implants, 71</p>
<p>3.6 Other Biomedical Applications, 73</p>
<p>References, 74</p>
<p>4 Laser Processing Applications 79<br />Tu¢grul Özel, Joaquim De Ciurana Gay, Daniel Teixidor Ezpeleta, and Luis Criales</p>
<p>4.1 Introduction, 79</p>
<p>4.2 Microscale Medical Device Applications, 80</p>
<p>4.3 Processing Methods for Medical Device Fabrication, 82</p>
<p>4.4 Biomaterials Used in Medical Devices, 86</p>
<p>4.5 Microjoining of Similar and Dissimilar Materials, 86</p>
<p>4.6 Laser Micromachining for Microfluidics, 89</p>
<p>4.7 Laser Micromachining for Metallic Coronary Stents, 92</p>
<p>References, 94</p>
<p>5 Machining Applications 99<br />Tu¢grul Özel, Elisabetta Ceretti, Thanongsak Thepsonthi, and Aldo Attanasio</p>
<p>5.1 Introduction, 99</p>
<p>5.2 Machinability of Biocompatible Metal Alloys, 102</p>
<p>5.3 Surfaces Engineering of Metal Implants, 104</p>
<p>5.4 Wear and Failure of Metal Implants, 105</p>
<p>5.5 Micromilling–Based Fabrication of Metallic Microchannels for Medical Devices, 106</p>
<p>5.6 Machining–Based Fabrication of Polymeric Microneedle Devices, 109</p>
<p>5.7 A Case Study: Milling–Based Fabrication of Spinal Spacer Cage, 110</p>
<p>5.7.1 Degenerative Disc Disease, 112</p>
<p>5.7.2 Intervertebral Spinal Spacers, 113</p>
<p>5.7.3 Prototype Fabrication Using Milling Process, 115</p>
<p>References, 118</p>
<p>6 Inkjet– and Extrusion–Based Technologies 121<br />Karla Monroy, Lidia Serenó, Joaquim De Ciurana Gay, Paulo Jorge Bártolo, Jorge Vicente Lopes Da Silva, and Marco Domingos</p>
<p>6.1 Introduction, 121</p>
<p>6.2 Inkjet Technology, 124</p>
<p>6.2.1 Inkjet 3D Printing Technology, 125</p>
<p>6.2.2 Materials in Inkjet–Based Technologies, 128</p>
<p>6.2.3 Inkjet Printing Methods, 130</p>
<p>6.2.4 Inkjet Printing Systems: Processes and Machines, 131</p>
<p>6.2.5 Medical Applications of Inkjet Technology, 135</p>
<p>6.3 Material Extrusion Technology, 139</p>
<p>6.3.1 Material Extrusion General Principles, 139</p>
<p>6.3.2 Extrusion–Based Technologies, 144</p>
<p>6.3.3 Medical Applications of Extrusion–Based Systems, 153</p>
<p>References, 156</p>
<p>7 Certification for Medical Devices 161<br />Corrado Paganelli, Marino Bindi, Laura Laffranchi, Domenico Dalessandri, Stefano Salgarello, Antonio Fiorentino, Giuseppe Vatri, and Arne Hensten</p>
<p>7.1 Introduction, 161</p>
<p>7.2 The Medical Devices Approval, Registration, or Certification, 163</p>
<p>7.3 The Premarket Key Activity: The Demonstration of the Conformity to the Safety and Performance Requirements, 163</p>
<p>7.4 The Postmarket Key Activity: The Surveillance, 165</p>
<p>7.5 The Role of the Quality Management Systems, 165</p>
<p>7.6 The Verification and the Auditing, 166</p>
<p>7.7 The Role of the Standards, 167</p>
<p>7.8 Examples of Approbation/Certification Roads in Some World Areas, 168</p>
<p>7.8.1 European Union, 168</p>
<p>7.8.2 United States of America, 168</p>
<p>7.8.3 Japan, 168</p>
<p>7.8.4 Australia, 169</p>
<p>7.8.5 Brazil, 169</p>
<p>7.8.6 Canada, 169</p>
<p>7.9 In–Depth Studies, 170</p>
<p>7.9.1 Essentials of Safety and Performance Principles, 170</p>
<p>7.9.2 Essentials of the Risk Management, 174</p>
<p>7.9.3 Essentials of the Nonclinical Evaluation, 175</p>
<p>7.9.4 Essentials of the Clinical Evaluation, 178</p>
<p>References, 181</p>
<p>INDEX 183</p>
<p>FOREWORD xi</p>
<p>1 Overview 1<br />Joaquim De Ciurana Gay, Tu¢grul Özel, and Lidia Serenó</p>
<p>1.1 Introduction, 1</p>
<p>1.2 Need for Medical Devices, 7</p>
<p>1.3 Technology Contribution to Medical Devices, 12</p>
<p>1.3.1 Subtractive Technologies, 13</p>
<p>1.3.2 Net–Shape Technologies, 13</p>
<p>1.3.3 Additive Technologies, 14</p>
<p>1.4 Challenges in the Medical Device Industry, 16</p>
<p>References, 17</p>
<p>2 Design Issues in Medical Devices 23<br />Inés Ferrer, Jordi Grabalosa, Alex Elias–Zuñiga, and Ciro Angel Rodriguez</p>
<p>2.1 Medical Device Development (MDD), 23</p>
<p>2.1.1 Biomedical Product Life Cycle, 24</p>
<p>2.1.2 Medical Device Development Process, 27</p>
<p>2.1.3 Medical Devices Design Process, 28</p>
<p>2.2 Case Study, 30</p>
<p>2.2.1 Scapholunate Interosseous Ligament, 30</p>
<p>2.2.2 Conceptual Design, 32</p>
<p>2.2.3 Embodiment Design, 35</p>
<p>2.2.4 Detailed Design, 36</p>
<p>2.2.5 Manufacturing a Prototype, 36</p>
<p>2.2.6 Tracheal Stent, 38</p>
<p>2.2.7 Conceptual Design, 39</p>
<p>2.2.8 Embodiment Design and Detail Design, 43</p>
<p>2.2.9 Manufacturing a Prototype, 45</p>
<p>2.3 Conclusions, 45</p>
<p>References, 46</p>
<p>3 Forming Applications 49<br />Karen Baylón, Elisabetta Ceretti, Claudio Giardini, and Maria Luisa Garcia–Romeu</p>
<p>3.1 Forming, 49</p>
<p>3.2 Typical Process Parameters, 52</p>
<p>3.2.1 Temperature, 52</p>
<p>3.2.2 Flow Stress, 53</p>
<p>3.2.3 Strain, 53</p>
<p>3.2.4 Strain Rate, 54</p>
<p>3.2.5 Tribology and Micro–Tribology, 54</p>
<p>3.3 Manufacturing Process Chain, 55</p>
<p>3.3.1 Manufacture of Alloys and Raw Materials, 55</p>
<p>3.3.2 Forming, 56</p>
<p>3.3.3 Machining and Finishing, 56</p>
<p>3.3.4 Coating, 56</p>
<p>3.3.5 Packaging and Sterilization, 56</p>
<p>3.4 Implantable Devices, 56</p>
<p>3.5 Bone Implants, 57</p>
<p>3.5.1 External Fracture Fixation, 57</p>
<p>3.5.2 Artificial Joint Replacement, 58</p>
<p>3.5.3 Spinal Implants, 68</p>
<p>3.5.4 Craniomandibular Implants, 68</p>
<p>3.5.5 Dental Implants, 71</p>
<p>3.6 Other Biomedical Applications, 73</p>
<p>References, 74</p>
<p>4 Laser Processing Applications 79<br />Tu¢grul Özel, Joaquim De Ciurana Gay, Daniel Teixidor Ezpeleta, and Luis Criales</p>
<p>4.1 Introduction, 79</p>
<p>4.2 Microscale Medical Device Applications, 80</p>
<p>4.3 Processing Methods for Medical Device Fabrication, 82</p>
<p>4.4 Biomaterials Used in Medical Devices, 86</p>
<p>4.5 Microjoining of Similar and Dissimilar Materials, 86</p>
<p>4.6 Laser Micromachining for Microfluidics, 89</p>
<p>4.7 Laser Micromachining for Metallic Coronary Stents, 92</p>
<p>References, 94</p>
<p>5 Machining Applications 99<br />Tu¢grul Özel, Elisabetta Ceretti, Thanongsak Thepsonthi, and Aldo Attanasio</p>
<p>5.1 Introduction, 99</p>
<p>5.2 Machinability of Biocompatible Metal Alloys, 102</p>
<p>5.3 Surfaces Engineering of Metal Implants, 104</p>
<p>5.4 Wear and Failure of Metal Implants, 105</p>
<p>5.5 Micromilling–Based Fabrication of Metallic Microchannels for Medical Devices, 106</p>
<p>5.6 Machining–Based Fabrication of Polymeric Microneedle Devices, 109</p>
<p>5.7 A Case Study: Milling–Based Fabrication of Spinal Spacer Cage, 110</p>
<p>5.7.1 Degenerative Disc Disease, 112</p>
<p>5.7.2 Intervertebral Spinal Spacers, 113</p>
<p>5.7.3 Prototype Fabrication Using Milling Process, 115</p>
<p>References, 118</p>
<p>6 Inkjet– and Extrusion–Based Technologies 121<br />Karla Monroy, Lidia Serenó, Joaquim De Ciurana Gay, Paulo Jorge Bártolo, Jorge Vicente Lopes Da Silva, and Marco Domingos</p>
<p>6.1 Introduction, 121</p>
<p>6.2 Inkjet Technology, 124</p>
<p>6.2.1 Inkjet 3D Printing Technology, 125</p>
<p>6.2.2 Materials in Inkjet–Based Technologies, 128</p>
<p>6.2.3 Inkjet Printing Methods, 130</p>
<p>6.2.4 Inkjet Printing Systems: Processes and Machines, 131</p>
<p>6.2.5 Medical Applications of Inkjet Technology, 135</p>
<p>6.3 Material Extrusion Technology, 139</p>
<p>6.3.1 Material Extrusion General Principles, 139</p>
<p>6.3.2 Extrusion–Based Technologies, 144</p>
<p>6.3.3 Medical Applications of Extrusion–Based Systems, 153</p>
<p>References, 156</p>
<p>7 Certification for Medical Devices 161<br />Corrado Paganelli, Marino Bindi, Laura Laffranchi, Domenico Dalessandri, Stefano Salgarello, Antonio Fiorentino, Giuseppe Vatri, and Arne Hensten</p>
<p>7.1 Introduction, 161</p>
<p>7.2 The Medical Devices Approval, Registration, or Certification, 163</p>
<p>7.3 The Premarket Key Activity: The Demonstration of the Conformity to the Safety and Performance Requirements, 163</p>
<p>7.4 The Postmarket Key Activity: The Surveillance, 165</p>
<p>7.5 The Role of the Quality Management Systems, 165</p>
<p>7.6 The Verification and the Auditing, 166</p>
<p>7.7 The Role of the Standards, 167</p>
<p>7.8 Examples of Approbation/Certification Roads in Some World Areas, 168</p>
<p>7.8.1 European Union, 168</p>
<p>7.8.2 United States of America, 168</p>
<p>7.8.3 Japan, 168</p>
<p>7.8.4 Australia, 169</p>
<p>7.8.5 Brazil, 169</p>
<p>7.8.6 Canada, 169</p>
<p>7.9 In–Depth Studies, 170</p>
<p>7.9.1 Essentials of Safety and Performance Principles, 170</p>
<p>7.9.2 Essentials of the Risk Management, 174</p>
<p>7.9.3 Essentials of the Nonclinical Evaluation, 175</p>
<p>7.9.4 Essentials of the Clinical Evaluation, 178</p>
<p>References, 181</p>
<p>INDEX 183</p>