Bioinspired Materials Science and Engineering

1 - Title Page [Seite 5]
2 - Copyright Page [Seite 6]
3 - Contents [Seite 7]
4 - List of Contributors [Seite 15]
5 - Foreword [Seite 19]
6 - Preface [Seite 21]
7 - Introduction to Science and Engineering Principles for the Development of Bioinspired Materials [Seite 23]
7.1 - I.1 Bioinspiration [Seite 23]
7.2 - I.2 BioinspiredMaterials [Seite 23]
7.3 - I.3 Biofabrication [Seite 24]
7.3.1 - I.3.1 Summary of Part I Biofabrication [Seite 24]
7.4 - I.4 Biofabrication Strategies [Seite 25]
7.4.1 - I.4.1 Conventional Biofabrication Strategies [Seite 25]
7.4.2 - I.4.2 Advanced Biofabrication Strategies [Seite 25]
7.5 - I.5 Part II Biomacromolecules [Seite 27]
7.5.1 - I.5.1 Summary of Part II Biomacromolecules [Seite 27]
7.5.2 - I.5.2 Carbohydrates [Seite 27]
7.5.3 - I.5.3 Proteins [Seite 30]
7.5.4 - I.5.4 Nucleic Acids [Seite 31]
7.6 - I.6 Part III Biomaterials [Seite 33]
7.6.1 - I.6.1 Summary of Part III Biomaterials [Seite 33]
7.6.2 - I.6.2 Features of Biomaterials [Seite 34]
7.6.3 - I.6.3 Current Advances in Biomaterials Science [Seite 35]
7.7 - I.7 Scope of the Book [Seite 35]
7.8 - Acknowledgments [Seite 36]
7.9 - References [Seite 36]
8 - Part I Biofabrication [Seite 39]
8.1 - Chapter 1 Biotemplating Principles [Seite 41]
8.1.1 - 1.1 Introduction [Seite 41]
8.1.2 - 1.2 Mineralization in Nature [Seite 42]
8.1.2.1 - 1.2.1 Biomineralization [Seite 42]
8.1.2.2 - 1.2.2 Geological Mineralization [Seite 43]
8.1.3 - 1.3 Petrified Wood in Construction and Technology [Seite 45]
8.1.4 - 1.4 Structural Description and Emulation [Seite 46]
8.1.4.1 - 1.4.1 Antiquity [Seite 46]
8.1.4.2 - 1.4.2 Modern Age: Advent of the Light Microscope [Seite 46]
8.1.4.3 - 1.4.3 Aqueous Silicon Dioxide, Prime Mineralization Agent [Seite 47]
8.1.4.4 - 1.4.4 Artificial Petrifaction of Wood [Seite 47]
8.1.5 - 1.5 Characteristic Parameters [Seite 50]
8.1.5.1 - 1.5.1 Hierarchical Structuring [Seite 50]
8.1.5.2 - 1.5.2 Specific Surface Areas [Seite 54]
8.1.5.3 - 1.5.3 Pore Structures [Seite 54]
8.1.6 - 1.6 Applications [Seite 56]
8.1.6.1 - 1.6.1 Mechanoceramics [Seite 56]
8.1.6.2 - 1.6.2 Nanoparticle Substrates [Seite 57]
8.1.6.3 - 1.6.3 Filter and Burner Assemblies [Seite 57]
8.1.6.4 - 1.6.4 Photovoltaic and Sensing Materials [Seite 58]
8.1.6.5 - 1.6.5 Wettability Control [Seite 59]
8.1.6.6 - 1.6.6 Image Plates [Seite 60]
8.1.7 - 1.7 Limitations and Challenges [Seite 60]
8.1.7.1 - 1.7.1 Particle Growth [Seite 60]
8.1.7.2 - 1.7.2 Comparison with Alternating Processing Principles [Seite 62]
8.1.7.3 - 1.7.3 Availability [Seite 62]
8.1.8 - 1.8 Conclusion and Future Topics [Seite 64]
8.1.9 - Acknowledgments [Seite 64]
8.1.10 - Notes [Seite 64]
8.1.11 - References [Seite 65]
8.2 - Chapter 2 Tubular Tissue Engineering Based on Microfluidics [Seite 75]
8.2.1 - 2.1 Introduction [Seite 75]
8.2.2 - 2.2 Natural Tubular Structures [Seite 75]
8.2.2.1 - 2.2.1 Blood Vessels [Seite 75]
8.2.2.2 - 2.2.2 Lymphatic Vessels [Seite 75]
8.2.2.3 - 2.2.3 Vessels in the Digestive System [Seite 76]
8.2.2.4 - 2.2.4 Vessels in the Respiratory System [Seite 76]
8.2.2.5 - 2.2.5 The Features of the Natural Tubular Structures [Seite 76]
8.2.3 - 2.3 Microfluidics [Seite 76]
8.2.3.1 - 2.3.1 An Introduction to Microfluidics [Seite 76]
8.2.3.2 - 2.3.2 Microfluidics to Manipulate Cells [Seite 77]
8.2.4 - 2.4 Fabrication of Tubular Structures by Microfluidics [Seite 79]
8.2.4.1 - 2.4.1 Angiogenesis [Seite 79]
8.2.4.2 - 2.4.2 Tissue Engineering of Natural Tubes [Seite 79]
8.2.4.3 - 2.4.3 Tissue Engineering of Other Tubular Structures [Seite 82]
8.2.5 - 2.5 Conclusion [Seite 84]
8.2.6 - Acknowledgments [Seite 84]
8.2.7 - References [Seite 84]
8.3 - Chapter 3 Construction of Three?Dimensional Tissues with Capillary Networks by Coating of Nanometer? or Micrometer?Sized Film on Cell Surfaces [Seite 89]
8.3.1 - 3.1 Introduction [Seite 89]
8.3.2 - 3.2 Fabrication of Nanometer? and Micrometer?Sized ECM Layers on Cell Surfaces [Seite 90]
8.3.2.1 - 3.2.1 Control of Cell Surface by FN Nanofilms [Seite 90]
8.3.2.2 - 3.2.2 Control of Cell Surface by Collagen Microfilms [Seite 94]
8.3.3 - 3.3 3D-Tissue with Various Thicknesses and Cell Densities [Seite 97]
8.3.4 - 3.4 Fabrication of Vascularized 3D?Tissues and Their Applications [Seite 99]
8.3.5 - 3.5 Conclusion [Seite 102]
8.3.6 - Acknowledgments [Seite 102]
8.3.7 - References [Seite 102]
8.4 - Chapter 4 Three-dimensional Biofabrication on Nematic Ordered Cellulose Templates [Seite 105]
8.4.1 - 4.1 Introduction [Seite 105]
8.4.2 - 4.2 What Is Nematic Ordered Cellulose (NOC)? [Seite 106]
8.4.2.1 - 4.2.1 Nematic Ordered Cellulose [Seite 106]
8.4.2.2 - 4.2.2 Various Nematic Ordered Templates and Modified Nematic Ordered Cellulose [Seite 109]
8.4.3 - 4.3 Exclusive Surface Properties of NOC and Its Unique Applications [Seite 111]
8.4.3.1 - 4.3.1 Bio-Directed Epitaxial Nano-Deposition on Molecular Tracks of the NOC Template [Seite 111]
8.4.3.2 - 4.3.2 Critical Factors in Bio?Directed Epitaxial Nano?Deposition on Molecular Tracks [Seite 112]
8.4.3.3 - 4.3.3 Regulated Patterns of Bacterial Movements Based on Their Secreted Cellulose Nanofibers Interacting Interfacially with Ordered Chitin and Honeycomb Cellulose Templates [Seite 115]
8.4.3.4 - 4.3.4 NOC Templates Mediating Order-Patterned Deposition Accompanied by Synthesis of Calcium Phosphates as Biomimic Mineralization [Seite 119]
8.4.3.5 - 4.3.5 Three-Dimensional Culture of Epidermal Cells on NOC Scaffolds [Seite 120]
8.4.4 - 4.4 Conclusion [Seite 122]
8.4.5 - References [Seite 123]
8.5 - Chapter 5 Preparation and Application of Biomimetic Materials Inspired by Mussel Adhesive Proteins [Seite 125]
8.5.1 - 5.1 Introduction [Seite 125]
8.5.2 - 5.2 Various Research Studies [Seite 126]
8.5.3 - 5.3 Conclusion [Seite 138]
8.5.4 - References [Seite 138]
8.6 - Chapter 6 Self-assembly of Polylactic Acid-based Amphiphilic Block Copolymers and Their Application in the Biomedical Field [Seite 141]
8.6.1 - 6.1 Introduction [Seite 141]
8.6.2 - 6.2 Micellar Structures from PLA?based Amphiphilic Block Copolymers [Seite 141]
8.6.2.1 - 6.2.1 Preparation and Mechanism of Micellar Structures [Seite 142]
8.6.2.2 - 6.2.2 Stability and Stimuli?Responsive Properties: Molecular Design and Biomedical Applications [Seite 144]
8.6.3 - 6.3 Hydrogels from PLA?based Amphiphilic Block Copolymers [Seite 147]
8.6.3.1 - 6.3.1 Mechanism of Hydrogel Formation from PLA?based Amphiphilic Block Copolymers [Seite 147]
8.6.3.2 - 6.3.2 Properties and Biomedical Applications of Hydrogel from PLA?based Amphiphilic Block Copolymers [Seite 148]
8.6.4 - 6.4 Conclusion [Seite 149]
8.6.5 - Acknowledgments [Seite 149]
8.6.6 - References [Seite 149]
9 - Part II Biomacromolecules [Seite 153]
9.1 - Chapter 7 Electroconductive Bioscaffolds for 2D and 3D Cell Culture [Seite 155]
9.1.1 - 7.1 Introduction [Seite 155]
9.1.2 - 7.2 Electrical Stimulation [Seite 155]
9.1.3 - 7.3 Electroconductive Bioscaffolds [Seite 157]
9.1.3.1 - 7.3.1 Conductive Polymers-based Electroconductive Bioscaffolds [Seite 157]
9.1.3.2 - 7.3.2 Carbon Nanotubes-based Electroconductive Bioscaffolds [Seite 159]
9.1.3.3 - 7.3.3 Graphene-based Electroconductive Bioscaffolds [Seite 162]
9.1.4 - 7.4 Conclusion [Seite 167]
9.1.5 - Acknowledgments [Seite 167]
9.1.6 - References [Seite 167]
9.2 - Chapter 8 Starch and Plant Storage Polysaccharides [Seite 171]
9.2.1 - 8.1 Starch and Other Seed Polysaccharides: Availability, Molecular Structure, and Heterogeneity [Seite 171]
9.2.1.1 - 8.1.1 Molecular Structure and Composition of Seeds and Cereal Grains [Seite 171]
9.2.1.2 - 8.1.2 Starch Hierarchical Structure from Bonds to the Granule [Seite 171]
9.2.1.3 - 8.1.3 Crystalline Structure [Seite 171]
9.2.1.4 - 8.1.4 Granular Structure [Seite 172]
9.2.1.5 - 8.1.5 Mannans, Galactomannans, and Glucomannans [Seite 172]
9.2.1.6 - 8.1.6 Xyloglucans [Seite 173]
9.2.1.7 - 8.1.7 Xylans. Arabinoxylans, Glucuronoxylans, and Glucuronoarabinoxylans [Seite 175]
9.2.2 - 8.2 Effect of the Molecular Structure of Starch and Seed Polysaccharides on the Macroscopic Properties of Derived Carbohydrate?based Materials [Seite 176]
9.2.2.1 - 8.2.1 Factors Affecting Starch Digestibility [Seite 176]
9.2.2.2 - 8.2.2 Structural Aspects of Seed Polysaccharides Affecting Configuration and Macroscopic Properties [Seite 180]
9.2.3 - 8.3 Chemo-enzymatic Modification Routes for Starch and Seed Polysaccharides [Seite 182]
9.2.4 - 8.4 Conclusion [Seite 183]
9.2.5 - References [Seite 184]
9.3 - Chapter 9 Conformational Properties of Polysaccharide Derivatives [Seite 189]
9.3.1 - 9.1 Introduction [Seite 189]
9.3.2 - 9.2 Theoretical Backbone to Determine the Chain Conformation of Linear and Cyclic Polymers from Dilute Solution Properties [Seite 191]
9.3.3 - 9.3 Chain Conformation of Linear Polysaccharides Carbamate Derivatives in Dilute Solution [Seite 193]
9.3.3.1 - 9.3.1 Effects of the Main Chain Linkage of the Polysaccharides Phenylcarbamate Derivatives [Seite 193]
9.3.3.2 - 9.3.2 Effects of Hydrogen Bonds to Stabilize the Helical Structure [Seite 194]
9.3.3.3 - 9.3.3 Enantiomeric Composition Dependent Chain Dimensions: ATBC and ATEC in d?, dl?, l-ethyl lactates [72, 76] [Seite 197]
9.3.3.4 - 9.3.4 Solvent-Dependent Helical Structure and the Chain Stiffness of Amylose Phenylcarbamates in Polar Solvents [Seite 198]
9.3.4 - 9.4 Lyotropic Liquid Crystallinity of Polysaccharide Carbamate Derivatives [Seite 199]
9.3.5 - 9.5 Cyclic Amylose Carbamate Derivatives: An Application to Rigid Cyclic Polymers [Seite 200]
9.3.6 - 9.6 Conclusion [Seite 202]
9.3.7 - Appendix: Wormlike Chain Parameters for Polysaccharide Carbamate Derivatives [Seite 203]
9.3.8 - References [Seite 204]
9.4 - Chapter 10 Silk Proteins: A Natural Resource for Biomaterials [Seite 207]
9.4.1 - 10.1 Introduction [Seite 207]
9.4.2 - 10.2 Bio-synthesis of Silk Proteins [Seite 208]
9.4.2.1 - 10.2.1 Silkworm Silk Glands [Seite 208]
9.4.2.2 - 10.2.2 Regulation of Silk Proteins Synthesis [Seite 208]
9.4.2.3 - 10.2.3 Synthesis of Fibroin [Seite 209]
9.4.2.4 - 10.2.4 Synthesis of Sericin [Seite 209]
9.4.2.5 - 10.2.5 Silk Filament Assembly [Seite 209]
9.4.3 - 10.3 Extraction of Silk Proteins [Seite 210]
9.4.3.1 - 10.3.1 Silk Degumming [Seite 210]
9.4.3.2 - 10.3.2 Fibroin Regeneration [Seite 210]
9.4.3.3 - 10.3.3 Sericin Recovery [Seite 211]
9.4.4 - 10.4 Structure and Physical Properties of Silk Proteins [Seite 211]
9.4.4.1 - 10.4.1 Silk Fibroin [Seite 211]
9.4.4.2 - 10.4.2 Silk Sericin [Seite 211]
9.4.5 - 10.5 Properties of Silk Proteins in Biomedical Applications [Seite 212]
9.4.5.1 - 10.5.1 Silk Fibroin [Seite 212]
9.4.5.2 - 10.5.2 Biomedical Uses of Silk Sericin [Seite 212]
9.4.6 - 10.6 Processing Silk Fibroin for the Preparation of Biomaterials [Seite 214]
9.4.6.1 - 10.6.1 Fabrication of 3D Matrices [Seite 215]
9.4.6.2 - 10.6.2 Fabrication of SF?based Films [Seite 215]
9.4.6.3 - 10.6.3 Preparation of SF?based Particulate Materials [Seite 216]
9.4.7 - 10.7 Processing Silk Sericin for Biomaterials Applications [Seite 216]
9.4.8 - 10.8 Conclusion [Seite 216]
9.4.9 - Acknowledgments [Seite 217]
9.4.10 - Abbreviations [Seite 217]
9.4.11 - References [Seite 217]
9.5 - Chapter 11 Polypeptides Synthesized by Ring-opening Polymerization of N-Carboxyanhydrides: : Preparation, Assembly, and Applications [Seite 223]
9.5.1 - 11.1 Introduction [Seite 223]
9.5.2 - 11.2 Living Polymerization of NCAs [Seite 223]
9.5.2.1 - 11.2.1 Transition Metal Complexes [Seite 223]
9.5.2.2 - 11.2.2 Active Initiators Based on Amines [Seite 225]
9.5.2.3 - 11.2.3 Recent Advances in Living NCA ROP Polymerization, 2013?2016 [Seite 226]
9.5.3 - 11.3 Synthesis of Traditional Copolypeptides and Hybrids [Seite 226]
9.5.3.1 - 11.3.1 Random Copolypeptides [Seite 227]
9.5.3.2 - 11.3.2 Hybrid Block Polypeptides [Seite 227]
9.5.3.3 - 11.3.3 Block Copolypeptides [Seite 228]
9.5.3.4 - 11.3.4 Non-linear Polypeptides and Copolypeptides [Seite 228]
9.5.4 - 11.4 New Monomers and Side?Chain Functionalized Polypeptides [Seite 230]
9.5.4.1 - 11.4.1 New NCA Monomers [Seite 230]
9.5.4.2 - 11.4.2 Glycopolypeptides [Seite 230]
9.5.4.3 - 11.4.3 Water-soluble Polypeptides with Stable Helical Conformation [Seite 231]
9.5.4.4 - 11.4.4 Stimuli-responsive Polypeptides [Seite 232]
9.5.5 - 11.5 The Self-assembly of Polypeptides [Seite 234]
9.5.5.1 - 11.5.1 Chiral Self-assembly [Seite 234]
9.5.5.2 - 11.5.2 Self-assembly with Inorganic Sources [Seite 235]
9.5.5.3 - 11.5.3 Microphase Separation of Polypeptides [Seite 236]
9.5.5.4 - 11.5.4 Self-assembly in Solution [Seite 236]
9.5.5.5 - 11.5.5 Polypeptide Gels [Seite 237]
9.5.6 - 11.6 Novel Bio-related Applications of Polypeptides [Seite 238]
9.5.6.1 - 11.6.1 Drug Delivery [Seite 238]
9.5.6.2 - 11.6.2 Gene Delivery [Seite 238]
9.5.6.3 - 11.6.3 Membrane Active and Antimicrobial Polypeptides [Seite 239]
9.5.6.4 - 11.6.4 Tissue Engineering [Seite 239]
9.5.7 - 11.7 Conclusion [Seite 241]
9.5.8 - References [Seite 241]
9.6 - Chapter 12 Preparation of Gradient Polymeric Structures and Their Biological Applications [Seite 247]
9.6.1 - 12.1 Introduction [Seite 247]
9.6.2 - 12.2 Gradient Polymeric Structures [Seite 247]
9.6.2.1 - 12.2.1 Gradient Hydrogels [Seite 247]
9.6.2.2 - 12.2.2 Gradient Polymer Brushes [Seite 252]
9.6.3 - 12.3 Gradient Polymeric Structures Regulated Cell Behavior [Seite 263]
9.6.3.1 - 12.3.1 Gradient Cell Adhesion [Seite 263]
9.6.3.2 - 12.3.2 Cell Migration [Seite 266]
9.6.4 - 12.4 Conclusion [Seite 269]
9.6.5 - References [Seite 269]
10 - Part III Biomaterials [Seite 273]
10.1 - Chapter 13 Bioinspired Materials and Structures: A Case Study Based on Selected Examples [Seite 275]
10.1.1 - 13.1 Introduction [Seite 275]
10.1.2 - 13.2 Fiber-reinforced Structures Inspired by Unbranched and Branched Plant Stems [Seite 275]
10.1.2.1 - 13.2.1 Technical Plant Stem [Seite 276]
10.1.2.2 - 13.2.2 Branched Fiber-reinforced Structures [Seite 276]
10.1.3 - 13.3 Pomelo Peel as Inspiration for Biomimetic Impact Protectors [Seite 277]
10.1.3.1 - 13.3.1 Hierarchical Structuring and its Influence on the Mechanical Properties [Seite 278]
10.1.3.2 - 13.3.2 Functional Principles for Biomimetic Impact Protectors [Seite 280]
10.1.4 - 13.4 Self-repair in Technical Materials Inspired by Plants' Solutions [Seite 280]
10.1.4.1 - 13.4.1 Plant Latex: Self-Sealing, Self-Healing and More [Seite 280]
10.1.4.2 - 13.4.2 Wound Sealing in the Dutchmen's Pipe: Concept Generator for Self?Sealing Pneumatic Systems [Seite 281]
10.1.5 - 13.5 Elastic Architecture: Lessons Learnt from Plant Movements [Seite 283]
10.1.5.1 - 13.5.1 Plant Movements: A Treasure Trove for Basic and Applied Research [Seite 283]
10.1.5.2 - 13.5.2 Flectofin®: a Biomimetic Façade?Shading System Inspired by the Deformation Principle of the "Perch" of the Bird of Paradise Flower [Seite 284]
10.1.6 - 13.6 Conclusions [Seite 286]
10.1.7 - Acknowledgments [Seite 286]
10.1.8 - References [Seite 286]
10.2 - Chapter 14 Thermal- and Photo-deformable Liquid Crystal Polymers and Bioinspired Movements [Seite 289]
10.2.1 - 14.1 Introduction [Seite 289]
10.2.2 - 14.2 Thermal-responsive CLCPs [Seite 289]
10.2.2.1 - 14.2.1 Thermal-responsive Deformation of CLCPs [Seite 289]
10.2.2.2 - 14.2.2 Bioinspired Thermal-responsive Nanostructure CLCP Surfaces [Seite 291]
10.2.3 - 14.3 Photothermal-responsive CLCPs [Seite 293]
10.2.4 - 14.4 Light-responsive CLCPs [Seite 294]
10.2.4.1 - 14.4.1 Light-responsive Deformation of CLCPs [Seite 294]
10.2.4.2 - 14.4.2 Bioinspired Soft Actuators [Seite 296]
10.2.4.3 - 14.4.3 Bioinspired Light-responsive Microstructured CLCP Surfaces [Seite 297]
10.2.5 - 14.4 Conclusion [Seite 299]
10.2.6 - References [Seite 299]
10.3 - Chapter 15 Tuning Mechanical Properties of Protein Hydrogels: Inspirations from Nature and Lessons from Synthetic Polymers [Seite 317]
10.3.1 - 15.1 Introduction [Seite 317]
10.3.2 - 15.2 What Are Different about Proteins? [Seite 318]
10.3.2.1 - 15.2.1 Protein Structure and Function [Seite 318]
10.3.2.2 - 15.2.2 Protein Synthesis [Seite 319]
10.3.3 - 15.3 Protein Cross-linking [Seite 320]
10.3.3.1 - 15.3.1 Chemical Cross-linking of Proteins [Seite 320]
10.3.3.2 - 15.3.2 Physical Cross-linking of Proteins [Seite 321]
10.3.4 - 15.4 Strategies for Mechanical Reinforcement [Seite 322]
10.3.4.1 - 15.4.1 Lessons from Synthetic Polymers [Seite 324]
10.3.4.2 - 15.4.2 Inspirations from Nature [Seite 327]
10.3.5 - 15.5 Conclusion [Seite 328]
10.3.6 - References [Seite 329]
10.4 - Chapter 16 Dendritic Polymer Micelles for Drug Delivery [Seite 333]
10.4.1 - 16.1 Introduction [Seite 333]
10.4.2 - 16.2 Dendrimers [Seite 334]
10.4.2.1 - 16.2.1 Dendrimer Synthesis: Divergent and Convergent Methods [Seite 334]
10.4.3 - 16.3 Hyperbranched Polymers [Seite 341]
10.4.4 - 16.4 Dendrigraft Polymers [Seite 345]
10.4.4.1 - 16.4.1 Divergent Grafting Onto Strategy [Seite 345]
10.4.4.2 - 16.4.2 Divergent Grafting from Strategy [Seite 350]
10.4.4.3 - 16.4.3 Convergent Grafting Through Strategy [Seite 354]
10.4.5 - 16.5 Conclusion [Seite 355]
10.4.6 - References [Seite 356]
10.5 - Chapter 17 Bone-inspired Biomaterials [Seite 359]
10.5.1 - 17.1 Introduction [Seite 359]
10.5.2 - 17.2 Bone [Seite 359]
10.5.3 - 17.3 Bone-like Materials [Seite 362]
10.5.3.1 - 17.3.1 Biomimetic Apatite [Seite 362]
10.5.3.2 - 17.3.2 Bone-inspired Hybrids [Seite 365]
10.5.4 - 17.4 Bone-like Scaffolds [Seite 366]
10.5.4.1 - 17.4.1 Additive Manufacturing [Seite 366]
10.5.4.2 - 17.4.2 Ice Templating [Seite 368]
10.5.5 - 17.5 Conclusion [Seite 371]
10.5.6 - References [Seite 371]
10.6 - Chapter 18 Research Progress in Biomimetic Materials for Human Dental Caries Restoration [Seite 373]
10.6.1 - 18.1 Introduction [Seite 373]
10.6.2 - 18.2 Tooth Structure [Seite 373]
10.6.3 - 18.3 The Formation Mechanism of Dental Caries [Seite 374]
10.6.4 - 18.4 HA-filled Biomimetic Resin Composites [Seite 374]
10.6.4.1 - 18.4.1 Particulate HA as Filler in Dental Restorative Resin Composites [Seite 374]
10.6.4.2 - 18.4.2 Novel Shapes of HA as Fillers in Dental Restorative Resin Composites [Seite 376]
10.6.4.3 - 18.4.3 Challenges and Future Developments [Seite 377]
10.6.5 - 18.5 Biomimetic Synthesis of Enamel Microstructure [Seite 378]
10.6.5.1 - 18.5.1 Amelogenins-containing Systems [Seite 378]
10.6.5.2 - 18.5.2 Peptides-containing Systems [Seite 379]
10.6.5.3 - 18.5.3 Biopolymer Gel Systems [Seite 381]
10.6.5.4 - 18.5.4 Dendrimers-containing Systems [Seite 382]
10.6.5.5 - 18.5.5 Surfactants/Chelators-containing Systems [Seite 382]
10.6.5.6 - 18.5.6 Challenges and Future Developments [Seite 382]
10.6.6 - Acknowledgments [Seite 384]
10.6.7 - References [Seite 384]
11 - Index [Seite 387]
12 - EULA [Seite 412]