Biomimetic, Bioresponsive, and Bioactive Materials
An Introduction to Integrating Materials with Tissues
1. Edition April 2012
248 Pages, Hardcover
Wiley & Sons Ltd
The accessible introduction to biomaterials and their
applications in tissue replacement, medical devices, and
more
Molecular and cell biology is being increasingly integrated into
the search for high-performance biomaterials and biomedical
devices, transforming a formerly engineering- and materials
science-based field into a truly interdisciplinary area of
investigation. Biomimetic, Bioresponsive, and Bioactive Materials
presents a comprehensive introduction to biomaterials, discussing
how they are selected, designed, and modified for integration with
living tissue and how they can be utilized in the development of
medical devices, orthopedics, and other related areas.
Examining the physico chemical properties of widely used
biomaterials and their uses in different clinical fields, the book
explores applications including soft and hard tissue replacement;
biointeractive metals, polymers, and ceramics; and in vitro, in
vivo, and ex vivo biocompatibility tests and clinical trials. The
book critically assesses the clinical level of research in the
field, not only presenting proven research, but also positing new
avenues of exploration.
Biomimetic, Bioresponsive, and Bioactive Materials contains
everything needed to get a firm grasp on materials science, fast.
Written in an accessible style and including practice questions
that test comprehension of the material covered in each chapter,
the book is an invaluable tool for students as well as
professionals new to the field.
1.1 The first generation of biomaterials: the search for 'the bioinert'.
1.2 Second-generation of biomaterials: biomimetic, bioresponsive, bioactive.
1.3 The third-generation biomaterials: biomimicking natural bioactive and bioresponsive processes.
1.4 Principles of biomimesis and bioactivity.
1.5 Bioactive biomaterials from different natural sources.
1.6 Scope of this book.
1.7 Exercises/Questions Chapter 1.
1.8 References.
Chapter 2. Soft Tissue Structure and Functionality (Gabriela Voskerician).
2.1 Overview.
2.2 Epithelial Tissue.
2.3 The Skin.
2.4 Muscle Tissue.
2.5 Connective Tissue.
2.6 The Foreign Body Response.
2.7 Exercises/Questions Chapter 2.
2.8 References.
Chapter 3. Hard Tissues Structures and Functionality (Antonio Merolli and Paolo Tranquilli Leali).
3.1 Definition of hard tissues.
3.2 Articular cartilage.
3.3 Bone tissue.
3.4 Conclusive remarks.
3.5 Exercises/Questions Chapter 3.
3.6 References.
Chapter 4. Biomedical Applications of Biomimetic Polymers: The Phosphorylcholine-Containing Polymers (Andrew L. Lewis and Andrew W. Lloyd).
4.1 Historical Perspective.
4.2 Synthesis of Pc-containing Polymers.
4.3 Physicochemical Properties of PC-containing Polymers.
4.4 Stability and Mechanical Property Considerations.
4.5 Biological Compatibility.
4.6 Applications of PC Polymers.
4.7 Summary.
4.8 Exercises/Questions Chapter 4.
4.9 References.
Chapter 5. Biomimetic, Bioresponsive, and Bioactive Materials: Integrating Materials with Tissue (Roberto Chiesa and Alberto Cigada).
5.1 Introduction.
5.2 Mandatory requirements for metals as implantable materials.
5.3 Biocompatibility of metals.
5.4 Surface treatments of metals for biomedical applications.
5.5 Exercises/Questions Chapter 5.
5.6 References.
Chapter 6. Ceramics (Montserrat Espanol, Román A. Pérez, Edgar B. Montufar, Maria-Pau Ginebra).
6.1 Historical perspective.
6.2 Biostable ceramics.
6.3 Bioactive and resorbable ceramics.
6.4 Exercises/Questions Chapter 6.
6.5 References.
Chapter 7. Biofunctional Biomaterials of the Future (Mario Barbosa, Gary Phillips, Matteo Santin).
7.1 Clinically led generation biomaterials.
7.2 Biomacromolecule-inspired biomaterials.
7.3 Nanostructured biomimetic, bioresponsive and bioactive biomaterials.
7.4 Conclusions.
7.5 Exercises/Questions Chapter 7.
7.6 References.
of Pharmacy and Biomolecular Studies at the University of
Brighton.
Gary J. Phillips is Principal Research Fellow in the School of
Pharmacy and Bimolecular Sciences at the University of
Brighton.
