Verfügbarkeit: Biofabrication

Biofabrication: micro- and nano-fabrication, printing, patterning and assemblies

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Bibliographische Detailangaben
Weitere Verfasser:	Forgacs, Gabor (HerausgeberIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Amsterdam [u.a.] William Andrew Elsevier 2013
Schriftenreihe:	Micro & nano technologies series
Schlagworte:	Medizin-Technik 3D-Druck Herstellung Biopolymere Werkstoff Biomaterial Rapid Prototyping > Fertigung Biomedizinische Technik Bioengineering.
Online-Zugang:	Inhaltsverzeichnis Klappentext
Beschreibung:	XVII, 265 S.
ISBN:	9781455728527

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Datensatz im Suchindex

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adam_text	Contents Preface ............................................................................................................xi List of Contributors .....................................................................................xiii CHAPTER 1 In Vitro Biofabrication of Tissues and Organs ............... ι Introduction ..............................................................................................1 1.1 Problems with scaffold-based tissue engineering ............................3 1.1.1 Immune reactions ..................................................................3 1.1.2 Degradation of scaffolds in vivo ..........................................3 1.1.3 Risk of infection ....................................................................4 1.2 Scaffold-free tissue engineering ...................................................5 1.2.1 Classification of present scaffold-free systems ....................6 1.2.2 In vitro self-produced ECM-rich scaffold-free constructs .......................................................10 1.2.3 The rotating wall vessel bioreactor system ........................11 13 Aggregation/spheroid-based approaches .......................................11 1.3.1 Preparation of multicellular spheroids ................................12 1.3.2 Molding MCSs ....................................................................12 1.3.3 Bio-printing .........................................................................12 1.3.4 Alternative approach for MCS assembly technique for biofabrication .................................................................13 Conclusion ..............................................................................................14 References ..............................................................................................16 CHAPTER 2 Biomaterials for Biofabrication of 3D Tissue Scaffolds .........................................................23 Introduction ............................................................................................23 2.1 Materials for 3D tissue scaffolds ...................................................24 2.1.1 Biodegradable synthetic polymers ......................................25 2.1.2 Natural polymers .................................................................26 2.1.3 Biodegradable or resorbable ceramics ................................28 2.2 Fabrication methods for 3D tissue scaffolds .................................29 2.2.1 Conventional techniques for 3D scaffolds ..........................29 2.2.2 Advanced techniques for 3D scaffolds ...............................30 23 Application of 3D tissue scaffolds .................................................33 2.3.1 Decellularized iiving tissues and organs ............................34 2.3.2 Porous scaffolds with irregular pores .................................34 vi Contents 2.3.3 Nanofibrous scaffolds ..........................................................35 2.3.4 Solid free-form (sff) scaffolds ............................................38 2.3.5 Hydrogel scaffolds ..............................................................40 2.4 Future perspectives of biomaterials for 3D scaffolds ...................41 Conclusion ..............................................................................................42 Acknowledgment ...................................................................................42 References ..............................................................................................42 CHAPTER 3 Projection Printing of Three-Dimensional Tissue Scaffolds with Tunable Poisson s Ratio ...........47 Introduction ............................................................................................47 3.1 Digital micromirror-assisted projection printing stereolithography ..............................................................48 3.2 Negative Poisson s ratio biomaterials ............................................50 3.3 Hybrid Poisson s ratio biomaterial ................................................52 3.4 Zero Poisson s ratio biomaterials ..................................................54 Conclusion ..............................................................................................55 References ..............................................................................................55 CHAPTER 4 Fabrication of Microscale Hydrogels for Tissue Engineering Applications ...................................59 Introduction ............................................................................................59 4.1 Technologies for fabrication of microengineered hydrogels ........................................................................................61 4.1.1 Photolithography .................................................................61 4.1.2 Soft lithography ...................................................................61 4.1.3 Bioprinting ...........................................................................63 4.1.4 Microfluidics .......................................................................64 4.1.5 Emulsification .....................................................................64 4.2 Tissue engineering applications .....................................................65 4.2.1 Applications of photolithography in tissue engineering ..........................................................................65 4.2.2 Applications of soft lithography in tissue engineering ..........................................................................67 4.2.3 Applications of bioprinting in tissue engineering ..............70 4.2.4 Applications of microfluidics in tissue engineering ..........................................................................71 4.2.5 Applications of emulsification in tissue engineering ..........................................................................73 Contents vìi Conclusion ..............................................................................................74 Acknowledgments ..................................................................................75 References ..............................................................................................75 CHAPTER 5 Polymeric Membranes for the Biofabrication of Tissues and Organs .....................................................81 Introduction ............................................................................................81 5.1 Properties of polymeric membranes ..............................................82 5.2 Membranes for tissue engineering .................................................84 5.3 Hollow fiber polymeric membranes for cell and tissue perfusion ........................................................................87 5.4 Membrane bioreactors for tissue constructs ..................................88 5.5 Future perspectives .........................................................................92 References ..............................................................................................92 CHAPTER 6 Laser-Assisted Bioprinting for Tissue Engineering .......................................................................95 Introduction ............................................................................................96 6.1 LAB s terms of reference ..............................................................98 6.1.1 Workstation requirements ...................................................98 6.1.2 Droplet ejection mechanism .............................................101 6.2 LAB parameters for cell printing .................................................105 6.2.1 Bioink composition considerations ...................................105 6.2.2 Viscosity of the bioink and laser energy influence cell viability .......................................................105 6.3 High-resolution/high-throughput trade-offs .................................106 6.3.1 Tissue engineering needs versus LAB limits ...................106 6.3.2 Printing resolution .............................................................106 6.3.3 High cell density printing with cell-level resolution ...........................................................................107 6.4 Three-dimensional printing: the layer-by-layer approach .......................................................................................110 6A1 The bioink as a scaffold ....................................................110 6.4.2 Biopapers ...........................................................................11 1 6.5 Applications ..................................................................................112 6.5.1 Multicolor printing at the microscale ...............................112 6.5.2 LAB engineered stem cell niche and tissue chips ............112 6.5.3 Addressing the perfusion issue in tissue engineering ........................................................................112 viii Contents 6.5.4 Laser-assisted engineering of transplants .........................113 6.5.5 In vivo printing ..................................................................113 Conclusion ............................................................................................114 Acknowledgments ................................................................................115 References ............................................................................................115 CHAPTER 7 The Modular Approach ..................................................119 Introduction ..........................................................................................119 7.1 Materials used to fabricate the modular building blocks ............121 7.1.1 ECM-based materials ........................................................123 7.1.2 PEG-based materials .........................................................125 7.2 Intrinsically vascularized tissue constructs ..................................126 7.2.1 In vivo fate of endothelialized modules ...........................126 7.2.2 Cell sheet technology ........................................................131 7.2.3 In vitro modular tissue engineering ..................................132 7.3 Building tissue constructs by assembling building blocks ............................................................................................133 7.3.1 Self-assembly of modules .................................................133 7.3.2 Directed assembly of modules ..........................................136 7.4 Modular tissue engineering combined with microfluidics ..........141 Conclusion ............................................................................................143 References ............................................................................................144 CHAPTER 8 Formation of Multicellular Microtissues and Applications in Biofabrication .............................. И9 Introduction ..........................................................................................149 8.1 Materials and methods .................................................................152 8.2 Results ..........................................................................................154 8.3 Discussion .....................................................................................157 8.4 Future considerations ...................................................................162 References ............................................................................................164 CHAPTER 9 A Digital Microfabrication-Based System for the Fabrication of Cancerous Tissue Models .............167 Introduction ..........................................................................................167 9.1 Digital micro-mirroring microfabrication system .......................169 9.1.1 Digital micro-mirroring projection system .......................169 9.1.2 Photolithographic substrate alignment system .................171 Contents ix 9.2 Multinozzle biologies deposition system ...................................171 9.3 Methods and materials ...............................................................172 9.3.1 Fabrication protocols and cell cultures ...........................173 9.4 Results ........................................................................................175 9.4.1 Preliminary investigation ................................................175 9.4.2 Cancer model investigation .............................................177 Conclusion ............................................................................................180 References ............................................................................................180 CHAPTER 10 Breast Reconstruction Using Biofabrication-Based Tissue Engineering Strategies ......................................................................183 introduction ..........................................................................................184 10.1 Anatomy of the breast ................................................................184 10.2 Current methods of breast reconstruction ..................................184 10.2.1 Prosthetic implant-based reconstruction .......................185 10.2.2 Cellular breast reconstruction .......................................186 10.3 Biofabrication-based tissue engineering strategy ......................189 10.3.1 Engineering challenges .................................................189 10.3.2 Formation of tissue constructs ......................................196 Conclusion ............................................................................................205 References ............................................................................................207 CHAPTER 11 Fabrication of Artificial Bacteria for Targeted Drug Delivery ................................................217 Introduction ..........................................................................................218 11.1 Drug delivery ..............................................................................218 11.1.1 Active and passive drug delivery ..................................219 11.1.2 Targeted drug delivery using microrobotics .................219 11.1.3 Interaction with biomechanical microstructures of soft biological tissues ...............................................221 11.2 Bioinspired locomotion and microswimming ...........................222 11.2.1 Ragella..........................................................................222 11.3 Materials and methods ...............................................................225 11.3.1 Microswimmer fabrication ............................................226 11.3.2 Microswimmer structures ..............................................230 Conclusion ............................................................................................232 Contents Acknowledgment .............. , ..................................................................233 References ............................................................................................234 CHAPTER 12 Biofabricating the Bio-Device Interface Using Biological Materials and Mechanisms .....................239 Introduction ..........................................................................................239 12.1 Complementarity of biofabrication and microfabrication .........................................................................240 12.2 Biofabrication methods ..............................................................241 12.2.1 Self-assembly ................................................................241 12.2.2 Enzymatic-assembly ......................................................243 12.2.3 Biomolecular engineering .............................................246 123 Biofabrication of a multifunctional matrix ................................246 12.4 Postfabrication biofunctionalization of devices .........................248 12.5 Test device ..................................................................................249 12.6 Electroaddressing a biosensing enzyme ....................................249 12.7 Creation of a spatially segregated bacterial biofilm ........................................................................................252 Conclusion ............................................................................................253 Acknowledgment .................................................................................254 References ............................................................................................254 Index .............................................................................................................259 NANOTECHNOLOGY BIOFABRICATION Micro- and Nano-Fabrication, Printing, Patterning, and Assemblies Edited by Gabor Forgács and Wei Sun Discover the multidisciplinary toolkit provided by biofabrication and apply it to develop new products, techniques and therapies. Biofabrication is a novel, inherently cross-disciplinary scientific field that focuses on biomanufacturing processes. This is the first book that presents the range of biofabrication technologies - including cell printing, patterning, assembling, 3D scaffold fabrication and cell/tissue-on-chips - as a coherent тісго^/папо- fabrication toolkit. Written and edited by leaders in the field. Biofabrication ¡s a practical guide to these key emerging technologies, with real-world examples to help readers gain a working knowledge of how to apply biofabrication techniques in areas such as regenerative medicine, Pharmaceuticals and tissue engineering. The book introduces the most salient approaches and methods used by practitioners of this discipline, which generates models, systems, devices, interfaces, and products that can be used for a wide range of applications in tissue science and tissue engineering, disease pathogeneses studies, and the development of new drugs. In addition to being a vital reference for scientists, engineers and technicians seeking to apply biofabrication techniques, this book also provides an insight into future developments in the field, and potential new applications. Gabor Forgács is the George Vineyard Professor of Biological Physics at the University of Missouri, Director of the Shipley Center for Innovation at Clarkson University and co-founder of the biotech companies Organovo and Modern Meadow. He received his PhD in theoretical physics from the Roland Eotvos University, Budapest, Hungary and the Landau institute for Theoretical Physics, Moscow, Russia. His present research focuses on physical mechanisms in early embryonic development, which he is applying to building functional living structures using tissue engineering technologies, such as bioprinting, which he pioneered. He has been recognized with numerous awards and citations, in particular, by FastCompany as one of the 100 most innovative people in business in 2010 . Wei Sun received his PhD in Mechanical Engineering in 1992 from Drexel University, USA. He is currently Albert Soffa Chair Professor at the Department of Mechanical Engineering and Mechanics, Drexel University, USA, and Professor of Mechanical Engineering and Director of Biomanufacturing Engineering Research Institute in Tsinghua University, Beijing, China. Dr. Sun s research interests include Biomanufacturing, Computer-Aided Tissue Engineering, CAD /САМ and Additive Manufacturing. He is currently an elected President of International Society of Biofabrication, and serves as Editor-in-Chief for the journal Biofabrication. Micro-Drops and Digital Microfluidics 2e {2013), Berthier, 9781455725502 Microffuidic Celt Culture Systems (2013), Bettinger, Borenstein and Tao, 9781437734591 William Andrew www.williarnandrewcum
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spelling	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies ed. by Gabor Forgacs ... Amsterdam [u.a.] William Andrew Elsevier 2013 XVII, 265 S. txt rdacontent n rdamedia nc rdacarrier Micro & nano technologies series Medizin-Technik (DE-588)2071813-5 gnd rswk-swf 3D-Druck (DE-588)1032223197 gnd rswk-swf Herstellung (DE-588)4159653-5 gnd rswk-swf Biopolymere (DE-588)4006893-6 gnd rswk-swf Werkstoff (DE-588)4065579-9 gnd rswk-swf Biomaterial (DE-588)4267769-5 gnd rswk-swf Rapid Prototyping Fertigung (DE-588)4389159-7 gnd rswk-swf Biomedizinische Technik (DE-588)4006882-1 gnd rswk-swf Bioengineering. Biomedizinische Technik (DE-588)4006882-1 s Biomaterial (DE-588)4267769-5 s Herstellung (DE-588)4159653-5 s DE-604 Rapid Prototyping Fertigung (DE-588)4389159-7 s Werkstoff (DE-588)4065579-9 s Medizin-Technik (DE-588)2071813-5 f Biopolymere (DE-588)4006893-6 s 3D-Druck (DE-588)1032223197 s Forgacs, Gabor edt Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=026742682&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=026742682&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext
spellingShingle	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies Medizin-Technik (DE-588)2071813-5 gnd 3D-Druck (DE-588)1032223197 gnd Herstellung (DE-588)4159653-5 gnd Biopolymere (DE-588)4006893-6 gnd Werkstoff (DE-588)4065579-9 gnd Biomaterial (DE-588)4267769-5 gnd Rapid Prototyping Fertigung (DE-588)4389159-7 gnd Biomedizinische Technik (DE-588)4006882-1 gnd
subject_GND	(DE-588)2071813-5 (DE-588)1032223197 (DE-588)4159653-5 (DE-588)4006893-6 (DE-588)4065579-9 (DE-588)4267769-5 (DE-588)4389159-7 (DE-588)4006882-1
title	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies
title_auth	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies
title_exact_search	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies
title_full	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies ed. by Gabor Forgacs ...
title_fullStr	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies ed. by Gabor Forgacs ...
title_full_unstemmed	Biofabrication micro- and nano-fabrication, printing, patterning and assemblies ed. by Gabor Forgacs ...
title_short	Biofabrication
title_sort	biofabrication micro and nano fabrication printing patterning and assemblies
title_sub	micro- and nano-fabrication, printing, patterning and assemblies
topic	Medizin-Technik (DE-588)2071813-5 gnd 3D-Druck (DE-588)1032223197 gnd Herstellung (DE-588)4159653-5 gnd Biopolymere (DE-588)4006893-6 gnd Werkstoff (DE-588)4065579-9 gnd Biomaterial (DE-588)4267769-5 gnd Rapid Prototyping Fertigung (DE-588)4389159-7 gnd Biomedizinische Technik (DE-588)4006882-1 gnd
topic_facet	Medizin-Technik 3D-Druck Herstellung Biopolymere Werkstoff Biomaterial Rapid Prototyping Fertigung Biomedizinische Technik
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=026742682&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=026742682&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT forgacsgabor biofabricationmicroandnanofabricationprintingpatterningandassemblies

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