From additive manufacturing to 3d/4d printing 3 : breakthrough innovations: programmable material, 4d printing and bio-printing / Jean-Claude Andre.

By: André, Jean-Claude [ author]
Language: English Publisher: Hoboken, NJ : ISTE Ltd/John Wiley and Sons Inc, 2017Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9781119451501Subject(s): Three-dimensional printing | Smart materialsGenre/Form: Electronic booksDDC classification: 621.988 Online resources: Full text available at Wiley Online Library Click here to view
Contents:
Acknowledgments ix Foreword xi Preface xv Introduction xxix Part 1 Programmable Smart/Intelligent Matter and 4D Printing 1 Introduction to Part 1 3 Chapter 1 Programmable Matter or Smart Matter, Stimulated Organization and 4D Printing 15 1.1 Introduction 16 1.2 Natural (spontaneous) self-organization 17 1.2.1 Nonlinearities 18 1.2.2 Achieving the desired form? 21 1.3 "Smart" matter 25 1.3.1 Active polymers: photochemical muscles 26 1.3.2 Physical alterations 37 1.3.3 Distortion of metal parts 39 1.3.4 Conclusion 41 1.4 A transition to 4D printing: swimming robots 41 1.5 4D Printing 46 1.5.1 Automation and robots48 1.5.2 Origami 53 1.5.3 Octobot 57 1.5.4 Massive objects 57 1.6 Conclusion 60 1.7 Bibliography 63 Part 2 Live "Smart" Matter and (Bio-printing) 79 Introduction to Part 2 81 Chapter 2 Bio-printing Technologies 103 2.1 Introduction 104 2.2 Tissue complexity 108 2.3 Bio-printing technologies 116 2.3.1 Cell preparation 120 2.3.2 Generic bio-printing technologies 122 2.3.3 Materials 133 2.3.4 Process-material couplings 138 2.3.5 Subsequent cell growth 140 2.4 Comment: 4D bio-printing 142 2.5 Other applications 142 2.5.1 Biological applications 142 2.5.2 Is it possible to feed ourselves thanks to bio-printing? 144 2.5.3 Bioluminescence and electronics 144 2.5.4 Bio-printed Bio-bots or "soft robots" produced by additive manufacturing 144 2.6 Conclusion 147 2.7 Appendix: 3D printing for biological applications 149 2.8 Bibliography 151 Chapter 3 Some Examples of 3D Bio-printed Tissues 169 3.1 Introduction 170 3.2 Work on cartilage 172 3.2.1 General remarks on cartilage 173 3.2.2 Cartilaginous defects and treatments 177 3.2.3 Cartilage bio-printing 178 3.2.4 Primary results 183 3.3 Skin bio-printing 187 3.3.1 General remarks on skin 188 3.3.2 Bio-printing skin 190 3.3.3 Conclusion 195 3.4 Bone 195 3.4.1 General remarks on the composition of bone 196 3.4.2 Bone bio-printing 198 3.4.3 Conclusion 200 3.5 Bio-printing and cancer 200 3.5.1 Examples 201 3.5.2 Conclusion and perspectives 203 3.6 General Conclusion 204 3.7 Bibliography 206 Chapter 4 Ethical Issues and Responsible Parties 217 4.1 Introduction 218 4.2 Reflection on the acceptance of bio-printing 219 4.2.1 Raw survey data 221 4.2.2 General discussion: whom to trust? 239 4.2.3 Preliminary conclusion 240 4.3 Ethics and bio-printing 246 4.3.1 Framing elements 250 4.3.2 Return on the concept of ethics 254 4.3.3 What can be foreseen? 261 4.3.4 Conclusion 275 4.4 Governing bio-printing research: mastering convergence 279 4.4.1 Return to 3D printing 280 4.4.2 Promises of NBIC convergence and bio-printing 283 4.4.3 Convergence 286 4.4.4 Comparisons 287 4.4.5 Epistemological questions 292 4.5 Conclusion 297 4.6 Bibliography 300 Chapter 5 Questions of Epistemology and Modeling 315 5.1 Introduction 316 5.2 The PE approach (seen by a possible divergent, somewhat of an HE) 324 5.3 The HE approach 329 5.4 Complexity and bio-printing 333 5.4.1 Complexity? 334 5.4.2 Initial reflection for action 340 5.5 Return to complexity 345 5.5.1 Complexity and system approach 350 5.6 Bases of reflection on modeling 359 5.6.1 Shooting or Monte-Carlo methods 359 5.6.2 Analogy with David Bohm's works? 363 5.6.3 Cellular differentiation 363 5.6.4 Scale change(s) 366 5.6.5 Questions for realistic modeling 366 5.6.6 Provision of an operatory reference 367 5.6.7 Organizational methodology 369 5.7 Conclusion 375 5.8 Bibliography 378 Conclusion 393 Postface 397 Index 419
Summary: In 1984, additive manufacturing represented a new methodology for manipulating matter, consisting of harnessing materials and/or energy to create three-dimensional physical objects. Today, additive manufacturing technologies represent a market of around 5 billion euros per year, with an annual growth between 20 and 30%. Different processes, materials and dimensions (from nanometer to decameter) within additive manufacturing techniques have led to 70,000 publications on this topic and to several thousand patents with applications as wide-ranging as domestic uses. Volume 1 of this series of books presents these different technologies with illustrative industrial examples. In addition to the strengths of 3D methods, this book also covers their weaknesses and the developments envisaged in terms of incremental innovations to overcome them.
Tags from this library: No tags from this library for this title. Log in to add tags.
    Average rating: 0.0 (0 votes)

Acknowledgments ix Foreword xi Preface xv Introduction xxix Part 1 Programmable Smart/Intelligent Matter and 4D Printing 1 Introduction to Part 1 3 Chapter 1 Programmable Matter or Smart Matter, Stimulated Organization and 4D Printing 15 1.1 Introduction 16 1.2 Natural (spontaneous) self-organization 17 1.2.1 Nonlinearities 18 1.2.2 Achieving the desired form? 21 1.3 "Smart" matter 25 1.3.1 Active polymers: photochemical muscles 26 1.3.2 Physical alterations 37 1.3.3 Distortion of metal parts 39 1.3.4 Conclusion 41 1.4 A transition to 4D printing: swimming robots 41 1.5 4D Printing 46 1.5.1 Automation and robots48 1.5.2 Origami 53 1.5.3 Octobot 57 1.5.4 Massive objects 57 1.6 Conclusion 60 1.7 Bibliography 63 Part 2 Live "Smart" Matter and (Bio-printing) 79 Introduction to Part 2 81 Chapter 2 Bio-printing Technologies 103 2.1 Introduction 104 2.2 Tissue complexity 108 2.3 Bio-printing technologies 116 2.3.1 Cell preparation 120 2.3.2 Generic bio-printing technologies 122 2.3.3 Materials 133 2.3.4 Process-material couplings 138 2.3.5 Subsequent cell growth 140 2.4 Comment: 4D bio-printing 142 2.5 Other applications 142 2.5.1 Biological applications 142 2.5.2 Is it possible to feed ourselves thanks to bio-printing? 144 2.5.3 Bioluminescence and electronics 144 2.5.4 Bio-printed Bio-bots or "soft robots" produced by additive manufacturing 144 2.6 Conclusion 147 2.7 Appendix: 3D printing for biological applications 149 2.8 Bibliography 151 Chapter 3 Some Examples of 3D Bio-printed Tissues 169 3.1 Introduction 170 3.2 Work on cartilage 172 3.2.1 General remarks on cartilage 173 3.2.2 Cartilaginous defects and treatments 177 3.2.3 Cartilage bio-printing 178 3.2.4 Primary results 183 3.3 Skin bio-printing 187 3.3.1 General remarks on skin 188 3.3.2 Bio-printing skin 190 3.3.3 Conclusion 195 3.4 Bone 195 3.4.1 General remarks on the composition of bone 196 3.4.2 Bone bio-printing 198 3.4.3 Conclusion 200 3.5 Bio-printing and cancer 200 3.5.1 Examples 201 3.5.2 Conclusion and perspectives 203 3.6 General Conclusion 204 3.7 Bibliography 206 Chapter 4 Ethical Issues and Responsible Parties 217 4.1 Introduction 218 4.2 Reflection on the acceptance of bio-printing 219 4.2.1 Raw survey data 221 4.2.2 General discussion: whom to trust? 239 4.2.3 Preliminary conclusion 240 4.3 Ethics and bio-printing 246 4.3.1 Framing elements 250 4.3.2 Return on the concept of ethics 254 4.3.3 What can be foreseen? 261 4.3.4 Conclusion 275 4.4 Governing bio-printing research: mastering convergence 279 4.4.1 Return to 3D printing 280 4.4.2 Promises of NBIC convergence and bio-printing 283 4.4.3 Convergence 286 4.4.4 Comparisons 287 4.4.5 Epistemological questions 292 4.5 Conclusion 297 4.6 Bibliography 300 Chapter 5 Questions of Epistemology and Modeling 315 5.1 Introduction 316 5.2 The PE approach (seen by a possible divergent, somewhat of an HE) 324 5.3 The HE approach 329 5.4 Complexity and bio-printing 333 5.4.1 Complexity? 334 5.4.2 Initial reflection for action 340 5.5 Return to complexity 345 5.5.1 Complexity and system approach 350 5.6 Bases of reflection on modeling 359 5.6.1 Shooting or Monte-Carlo methods 359 5.6.2 Analogy with David Bohm's works? 363 5.6.3 Cellular differentiation 363 5.6.4 Scale change(s) 366 5.6.5 Questions for realistic modeling 366 5.6.6 Provision of an operatory reference 367 5.6.7 Organizational methodology 369 5.7 Conclusion 375 5.8 Bibliography 378 Conclusion 393 Postface 397 Index 419

In 1984, additive manufacturing represented a new methodology for manipulating matter, consisting of harnessing materials and/or energy to create three-dimensional physical objects. Today, additive manufacturing technologies represent a market of around 5 billion euros per year, with an annual growth between 20 and 30%. Different processes, materials and dimensions (from nanometer to decameter) within additive manufacturing techniques have led to 70,000 publications on this topic and to several thousand patents with applications as wide-ranging as domestic uses.

Volume 1 of this series of books presents these different technologies with illustrative industrial examples. In addition to the strengths of 3D methods, this book also covers their weaknesses and the developments envisaged in terms of incremental innovations to overcome them.

There are no comments for this item.

to post a comment.