Integrated Biomaterials in Tissue Engineering
, by Ramalingam, Murugan; Haidar, Ziyad; Ramakrishna, Seeram; Kobayashi, Hisatoshi; Haikel, Youssef
- ISBN: 9781118311981 | 1118311981
- Cover: Hardcover
- Copyright: 4/3/2012
"Integrated Biomaterials in Tissue Engineering" features all aspects from fundamental principles to current technological advances in biomaterials at the macro/micro/nano/molecular scales suitable for tissue engineering and regenerative medicine. The book is unique as it provides all important aspects dealing with the basic science involved in structure and properties, techniques and technological innovations in material processing and characterizations, and applications of biomaterials in tissue engineering and regenerative medicine.
Murugan Ramalingam is an Associate Professor of Biomaterials and Tissue Engineering at the Institut National de la Sant et de la Recherche Mdicale U977 and Facult de Chirurgie Dentaire, Universit de Strasbourg, France. Concurrently, he holds an Adjunct Associate Professorship at the Tohoku University, Japan. Ziyad Haidar is a Research Assistant Professor at the Departments of BioEngineering and Pharmaceutics and Pharmaceutical Chemistry, School of Medicine, University of Utah. He is also an Adjunct Professor at the Inha University Hospital, College of Medicine, Incheon, South Korea. Seeram Ramakrishna, FREng, FNAE, FAJTMBE, is the Director of HEM Labs at the National University of Singapore. He has authored five books and over four hundred international journal papers, which garnered more than 14,000 citations. Hisatoshi Kobayashi is a group leader of WPI Research center MANA, National Institute for Materials Science, Tsukuba, Japan. He is currently the President of International Association of Advanced Materials. Youssef Haikel is the Dean of Faculty of Dental Surgery, University of Strasbourg, France. He is also affiliated with the Beijing Faculty of Stomatology as a Honorary Professor and at the Medical University for Health Sciences Hokkaido as an Honorary Visiting Professor.
| Preface | p. xiii |
| List of Contributors | p. xv |
| Protocols for Biomaterial Scaffold Fabrication | p. 1 |
| Introduction | p. 1 |
| Scaffolding Materials | p. 4 |
| Naturally Derived Materials | p. 4 |
| Scaffolds Based on Synthetic Polymers | p. 7 |
| Techniques for Biomaterial Scaffolds Fabrication | p. 7 |
| Solvent Casting | p. 8 |
| Salt-leaching | p. 8 |
| Gas Foaming | p. 11 |
| Phase Separation | p. 12 |
| Electrospinning | p. 13 |
| Self-assembly | p. 15 |
| Rapid Prototyping | p. 16 |
| Membrane Lamination | p. 18 |
| Freeze Drying | p. 18 |
| Summary | p. 19 |
| Acknowledgements | p. 20 |
| References | p. 20 |
| Ceramic Scaffolds, Current Issues and Future Trends | |
| Introduction | p. 25 |
| Essential Properties and Current Problems of Ceramic Scaffolds | p. 27 |
| Approaches to Overcome Ceramic Scaffolds Issues for the Next Generation of Scaffolds | p. 30 |
| Silk - a Bioactive Material | p. 35 |
| Conclusions and Future Trends | p. 35 |
| Acknowledgements | p. 36 |
| References | p. 36 |
| Preparation of Porous Scaffolds from Ice Particulate Templates for Tissue Engineering | p. 47 |
| Introduction | p. 48 |
| Preparation of Porous Scaffolds Using Ice Particulates as Porogens | p. 48 |
| Preparation of Funnel-like Porous Scaffolds Using Embossed Ice Particulate Templates | p. 51 |
| Overview of Protocol | p. 51 |
| Preparation of Funnel-like Collagen Sponges | p. 51 |
| Preparation of Funnel-like Chitosan Sponges | p. 54 |
| Preparation of Funnel-like Hyaluronic Acid Sponges | p. 55 |
| Preparation of Funnel-like Collagen-glycosaminoglycan Sponges | p. 55 |
| Application of Funnel-like Porous Scaffolds in Three-dimensional Cell Culture | p. 56 |
| Application of Funnel-like Collagen Sponges in Cartilage Tissue Engineering | p. 57 |
| Summary | p. 60 |
| References | p. 60 |
| Fabrication of Tissue Engineering Scaffolds Using the Emulsion Freezing/Freeze-drying Technique and Characteristics of the Scaffolds | p. 63 |
| Introduction | p. 64 |
| Materials for Tissue Engineering Scaffolds | p. 65 |
| Fabrication Techniques for Tissue Engineering Scaffolds | p. 68 |
| Fabrication of Pure Polymer Scaffolds via Emulsion Freezing/Freeze-drying and Characteristics of the Scaffolds | p. 70 |
| Fabrication of Polymer Blend Scaffolds via Emulsion Freezmg/Freeze-drying and Characteristics of the Scaffolds | p. 78 |
| Fabrication of Nanocomposite Scaffolds via Emulsion Freezing/Freeze-drying and Characteristics of the Scaffolds | p. 80 |
| Surface Modification for PHBV-based Scaffolds | p. 85 |
| Concluding Remarks | p. 87 |
| Acknowledgements | p. 87 |
| References | p. 88 |
| Electrospun Nanofiber and Stem Cells in Tissue Engineering | p. 91 |
| Introduction | p. 92 |
| Biodegradable Materials for Tissue Engineering | p. 93 |
| Nanofibrous Scaffolds | p. 97 |
| Technologies to Fabricate Nanofibers | p. 98 |
| In Vitro and In Vivo Studies of Nanofibrous Scaffold | p. 103 |
| Stem Cells: A Potential Tool for Tissue Engineering | p. 108 |
| Stem Cells in Tissue Engineering and Regeneration | p. 108 |
| Effect of Stem Cells on Electrospun Nanofibrous Scaffolds | p. 111 |
| Prospects | p. 113 |
| Acknowledgement | p. 115 |
| p. 115 | |
| Materials at the Interface Tissue-Implant | p. 119 |
| Introduction | p. 120 |
| Description of the Tissue-Implant Interface | p. 121 |
| Expected Function of the Materials at the Interface and their Evaluation and Selection | p. 123 |
| General Purpose Non-biological Materials | p. 127 |
| General Purpose Natural Materials and Biopolymers | p. 128 |
| Other Regenerative Biomaterials and Techniques | p. 129 |
| Future Approaches | p. 129 |
| Experimental Techniques for the Tissue-Implant Interface | p. 130 |
| Conclusion | p. 133 |
| References | p. 133 |
| Mesenchymal Stem Cells in Tissue Regeneration | p. 137 |
| Introduction | p. 137 |
| Mesenchymal stem cells (MSCs) | p. 140 |
| Self-renewal of MSCs | p. 142 |
| Heterogeneity of MSCs | p. 143 |
| MSCs from Different Types of Tissues | p. 144 |
| MSCs, Progenitor Cells and Precursor Cells | p. 144 |
| Differentiation Potential of MSCs | p. 145 |
| Dedifferentiation and Transdifferentiation of hMSCs | p. 146 |
| Understanding the Mesenchymal Stem Cells (MSCs) | p. 147 |
| Integrins and Their Role in Mesenchymal Stem Cells (MSCs) | p. 147 |
| Mesenchymal Stem Cell (MSC) Niche | p. 149 |
| Immunomodulatory Effect of MSCs | p. 150 |
| Mesenchymal Stem Cell (MSC) Culture | p. 150 |
| Mesenchymal Stem Cell (MSC) Isolation | p. 151 |
| Mesenchymal Stem Cell (MSC) Expansion | p. 151 |
| Media for Inducing Osteogenic Differentiation in MSCs | p. 152 |
| Characterization of MSCs | p. 153 |
| Microscopy Techniques | p. 154 |
| Differentiation and Cell Proliferation Assays for MSCs | p. 155 |
| MSCs in Bone Remodeling, Fracture Repair and Their Use in Bone Tissue Engineering Applications | p. 156 |
| Influence of External Stimuli on MSC Behavior | p. 157 |
| Role of Mechanical Stimulus on hMSCs | p. 158 |
| Role of Electrical Stimulus on MSCs | p. 159 |
| Perspectives on Future of hMSCs in Tissue Engineering | p. 159 |
| References | p. 160 |
| Endochondral Bone Tissue Engineering | p. 165 |
| Introduction | p. 165 |
| Tissue Engineering and Stem Cells | p. 169 |
| Tissue Engineering | p. 169 |
| Stem Cells | p. 170 |
| Bone Tissue Engineering | p. 171 |
| Bone Tissue Engineering via the Endochondral Pathway | p. 172 |
| Scaffolds | p. 173 |
| General Requirements of Scaffolds | p. 173 |
| Scaffolds for Endochondral Tissue Engineering | p. 175 |
| Hydrogels | p. 176 |
| Synthetic Polymer Woven Structure | p. 177 |
| Calcium Phosphate (CaP) Ceramics | p. 178 |
| Summary | p. 179 |
| References | p. 180 |
| Principles, Applications, and Technology of Craniofacial Bone Engineering | p. 183 |
| Introduction | p. 184 |
| Anatomy and Physiology of Craniofacial Bone | p. 185 |
| Functional Characteristics of Craniofacial Tissues | p. 190 |
| Bone Strength | p. 190 |
| Effect of Forces | p. 191 |
| Angiogenesis in Bone Physiology | p. 192 |
| Prevalence of Craniofacial Congenital Anomalies and Acquired Defects | p. 192 |
| Congenital Anomalies | p. 192 |
| Acquired Defects | p. 193 |
| Road Map for the Application of Tissue Engineering and Regenerative Medicine for Craniofacial Bone Regeneration | p. 195 |
| Vascularization and Its Strategies | p. 197 |
| Stem Cell-based Craniofacial Bone Engineering | p. 199 |
| The Stem Cell Concept: Recreating the Local Tissue Microenvironment | p. 200 |
| Applied Stem Cell-based Craniofacial Bone Engineering | p. 201 |
| Additional Viable Stem Cell Sources for Craniofacial Bone Engineering | p. 204 |
| Biomaterial-based Therapy in Craniofacial Bone Engineering | p. 206 |
| Surface Biomirnetism | p. 210 |
| Principles of Imaging in Craniofacial Bone Regeneration | p. 212 |
| Modeling of, Preparation for, and Planning Tissue Engineering | p. 212 |
| Image Guided Design | p. 215 |
| Follow-up and Assessment | p. 216 |
| Medical Imaging Techniques for Craniofacial Bone Engineering | p. 218 |
| Plain X-rays | p. 218 |
| Computed Tomography (CT)-based Methods | p. 218 |
| Magnetic Resonance Imaging | p. 219 |
| Future Methods: High Frequency Ultrasound Imaging | p. 220 |
| Current Clinical Application and Future Direction in the Field of Craniofacial Bone Engineering | p. 220 |
| Current Treatments of Bone Defects | p. 220 |
| Modern Treatment of Bone Defects | p. 221 |
| Some Examples of Tissue Engineering Materials and Clinical Trials | p. 223 |
| Future Prospects | p. 225 |
| Economics and Marketing | p. 225 |
| Conclusions | p. 226 |
| References | p. 226 |
| Functionally-Graded Biomimetic Vascular Grafts for Enhanced Tissue Regeneration and Bio-integration | p. 235 |
| Introduction | p. 236 |
| Approaches in Vascular Tissue Engineering | p. 237 |
| Nanostructured Scaffolds for Vascular Tissue Engineering | p. 239 |
| Electrospinning for Producing ECM-like Fibers | p. 241 |
| Biomimetic Electrospun Vascular Scaffolds | p. 244 |
| Functionally-Graded Tubular Scaffolds | p. 247 |
| Graded-Tissue Design in Native Vessels | p. 247 |
| Biomimetic Multi-layered Tubular Scaffolds | p. 249 |
| Mechanical Properties of Trilayered Tubular Grafts | p. 251 |
| Biodegradation Characteristics of Trilayered Grafts | p. 255 |
| In Vitro Cell Interactions and In Vivo Performance | p. 260 |
| Summary and Future Outlook | p. 266 |
| Acknowledgements | p. 267 |
| List of Abbreviations Used | p. 268 |
| References | p. 269 |
| Vascular Endothelial Growth Factors in Tissue Engineering: Challenges and Prospects for Therapeutic Angiogenesis | p. 275 |
| Introduction | p. 276 |
| VEGF and Angiogenesis | p. 276 |
| VEGF Family | p. 277 |
| VEGF Therapy | p. 279 |
| VEGF Delivery Systems | p. 280 |
| Soft versus Hard Tissues | p. 282 |
| Concluding Remarks | p. 287 |
| References | p. 290 |
| Index | p. 295 |
| Table of Contents provided by Ingram. All Rights Reserved. |
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