Orthopedic biomaterials : progress in biology, manufacturing, and industry perspectives /
Saved in:
| Imprint: | Cham, Switzerland : Springer, 2018. |
|---|---|
| Description: | 1 online resource |
| Language: | English |
| Subject: | |
| Format: | E-Resource Book |
| URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/11690368 |
Table of Contents:
- Intro; Preface; Contents; Part I: Design, Manufacturing, Assessment, and Applications; Nanotechnology for Orthopedic Applications: From Manufacturing Processes to Clinical Applications; 1 Introduction; 2 The Extracellular Matrix (ECM); 2.1 ECM Composition; 2.2 The ECM as a Molecular Reservoir; 2.3 Cell-ECM Interactions; 2.4 Bone; 2.4.1 Cortical Bone; 2.4.2 Cancellous Bone; 3 Tissue Engineering; 3.1 Nanotechnology for Tissue Engineering; 3.2 Control of Cell Functions Using Nanotechnology; 3.3 Cell Sensitivity to Nanofeatures; 3.4 Important Features of Scaffolds for Tissue Engineering.
- 3.5 Materials for Scaffold Construction4 Unmet Clinical Need; 4.1 Substrate Properties for Osseointegration; 4.2 Substrate Properties to Resist Bacterial Infection; 4.2.1 Shot Peened 316 L Stainless Steel; 4.2.2 Electrophoretic Deposition; 5 Conclusions; References; Additive Manufacturing of Orthopedic Implants; 1 Introduction; 2 Additive Manufacturing Techniques; 2.1 Binder Jetting; 2.2 Directed Energy Deposition (DED); 2.3 Powder Bed Fusion (PBF); 2.4 Material Extrusion; 3 Additively Manufactured Biomaterials; 3.1 Metallic Biomaterials; 3.1.1 Stainless Steel; 3.1.2 Co-Cr Alloys.
- 3.1.3 Titanium Alloys3.1.4 Tantalum; 3.2 Other Biomaterials; 3.2.1 PEEK; 3.2.2 Ceramics; 4 AM Design Considerations; 4.1 Patient-Specific Design Procedures; 4.2 Porosity; 4.3 Clinical Applications; 4.4 Patient Variability; 4.5 Shoulder and Other Joint Replacements; 4.6 Fracture Fixation; 4.7 Large Bone Defects; 4.8 Surgical Guides; 4.9 Additional Clinical Examples; 5 Summary; References; 3D Printed Porous Bone Constructs; 1 Introduction; 2 3D Printing Techniques; 3 Porous Materials for Cell Growth; 4 3D Printing of Porous Ceramic Materials; 5 3D Printing of Porous Metal Materials.
- 6 3D Printing of Porous Polymer Materials7 Conclusions; References; Biopolymer Based Interfacial Tissue Engineering for Arthritis; 1 Introduction; 2 Anatomy of Osteochondral Tissue Interface; 3 Conventional Vs. Interfacial Tissue Engineering; 4 Polymeric Biomaterials for Interfacial Tissue Engineering; 5 Design Considerations for Interfacial Tissue Engineering; 5.1 Stratified Scaffold Design; 5.2 Gradient Scaffold Design; 6 Present Clinical Status of Interfacial Tissue Engineering; 7 Future Perspectives of Interfacial Tissue Engineering in Orthopedic Applications; 8 Conclusion; References.
- Performance of Bore-Cone Taper Junctions on Explanted Total Knee Replacements with Modular Stem Extensions: Mechanical Disassembly and Corrosion Analysis of Two Designs1 Introduction; 2 Materials and Methods; 2.1 Implant Retrieval and Archiving; 2.2 Assessment of Surface Corrosion Area; 2.3 Damage Mode Characterization; 2.4 Data Analysis; 3 Results; 4 Discussion; 4.1 Effects of Design and Modes of Corrosion; 4.2 Effects of Patient Factors and Anatomical Location; 4.3 Mechanical Disassembly and Surface Corrosion Area; 4.4 Limitations; 5 Conclusion; References.