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Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
|---|---|---|---|---|---|
Searching... | 30000010161072 | TA418.9.N35 B57 2008 | Open Access Book | Book | Searching... |
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Summary
Summary
This ready reference is the first to collate the interdisciplinary knowledge from materials science, bioengineering and nanotechnology to give an in-depth overview of the topic. As such, it provides broad coverage of combinations between inorganic materials and such key biological structures as proteins, enzymes, DNA, or biopolymers. With its treatment of various application directions, including bioelectronic interfacing, tissue repair, porous membranes, sensors, nanocontainers, and DNA engineering, this is essential reading for materials engineers, medical researchers, catalytic chemists, biologists, and those working in the biotechnological and semiconductor industries.
Author Notes
Eduardo Ruiz-Hitzky is the director of the Department of Porous Materials and Intercalation Compounds at the Materials Science Institute of Madrid (CSIC), Spain. His research work during the last 30 years has focused on organic-inorganic hybrids and bio-nanocomposite materials. Professor Ruiz-Hitzky has authored over 150 scientific publications and edited two journal special issues, one of them (now in preparation) on bio-nanohybrid materials. He has received several scientific awards from different countries, including the AIPEA Medal from the International Association for the Study of Clays (Tokyo, 2005).
Katsuhiko Ariga is the director of the Supermolecules Group at the National Institute for Materials Science (NIMS), Japan. His research work during the last 20 years has focused on fabrication of nanostructured materials through specific interaction at interfaces, creating novel hybrids of inorganic, organic and biological materials. Dr. Katsuhiko Ariga has authored over 230 scientific publications and received more than 3600 citations. He has published three text books on supramolecular chemistry and served as an editor of one book and one journal special issue on nanomaterials.
Yuri M. Lvov is Chemistry Professor and Pipes Endowed Chair on Micro and Nanosystems at Louisiana Tech University, USA. Earlier, he worked in the Center for Biomolecular Science and Engineering at the Naval Research Laboratory. He is author of more than 150 scientific publications on ultrathin films, biomaterials, clay nanocomposites, and nanocapsules for sustained drug release. Professor Yuri Lvov was among the pioneers of the layer-by-layer nanoassembly technique based on alternate adsorption of oppositely charged components with more than 4000 citations of these works.
Table of Contents
| Preface |
| Contributors |
| 1 An Introduction to Bio-nanohybrid MaterialsEduardo Ruiz-Hitzky and Margarita Darder and Pilar Aranda |
| 1.1 Introduction: The Assembly of Biological Species to Inorganic Solids |
| 1.2 Bio-nanohybrids Based on Silica Particles and Siloxane Networks |
| 1.3 Calcium Phosphates and Carbonates in Bioinspired and Biomimetic Materials |
| 1.4 Clay Minerals and Organoclay Bio-nanocomposites |
| 1.5 Bio-Nanohybrids Based on Metal and Metal Oxide Nanoparticles |
| 1.6 Carbon-based Bio-nanohybrids |
| 1.7 Bio-nanohybrids Based on Layered Transition Metal Solids |
| 1.8 Trends and Perspectives |
| References |
| 2 Biomimetic Nanohybrids Based on Organosiloxane UnitsKazuko Fujii and Jonathan P. Hill and Katsuhiko Ariga |
| 2.1 Introduction |
| 2.2 Monolayer on Solid Support |
| 2.3 Layered Alkylsiloxane |
| 2.4 Organic-Inorganic Hybrid Vesicle Cerasome |
| 2.5 Mesoporous Silica Prepared by the Lizard Template Method |
| 2.6 Future Perspectives |
| References |
| 3 Entrapment of Biopolymers into Sol-Gel-derived Silica NanonocompositesYury A. Shchipunov |
| 3.1 Introduction |
| 3.2 Sol-Gel Processes |
| 3.3 Biocompatible Approaches |
| 3.4 One-Stage Approach Based on a Silica Precursor with Ethylene Glycol Residues |
| 3.5 Perspectives |
| References |
| 4 Immobilization of Biomolecules on Mesoporous Structured MaterialsAjayan Vinu and Narasimhan Gokulakrishnan and Toshiyuki Mori and Katsuhiko Ariga |
| 4.1 Introduction |
| 4.2 Immobilization of Protein on Mesoporous Silica |
| 4.3 Immobilization of Protein on Mesoporous Carbon and Related Materials |
| 4.4 Immobilization of Other Biopolymers on Mesoporous Materials |
| 4.5 Immobilization of Small Biomolecules on Mesoporous Materials |
| 4.6 Advanced Functions of Nanohybrids of Biomolecules and Mesoporous Materials |
| 4.7 Future Perspectives |
| References |
| 5 Bio-controlled Growth of Oxides and Metallic NanoparticlesThibaud Coradin and Roberta Brayner and Fernand Fiévet and Jacques Livage |
| 5.1 Introduction |
| 5.2 Biomimetic Approaches |
| 5.3 In vitro Synthesis of Hybrid Nanomaterials |
| 5.4 Perspectives: Towards a Green Nanochemistry |
| References |
| 6 Biomineralization of Hydrogels Based on Bioinspired Assemblies for Injectable BiomaterialsJunji Watanabe and Mitsuru Akashi |
| 6.1 Introduction |
| 6.2 Fundamental Concept of Bioinspired Approach |
| 6.3 Alternate Soaking Process for Biomineralization and their Bio-functions |
| 6.4 Electrophoresis Process for Biomineralization |
| 6.5 Conclusions |
| References |
| 7 Bioinspired Porous Hybrid Materials via Layer-by-Layer AssemblyYajun Wang and Frank Caruso |
| 7.1 Introduction |
| 7.2 Porous Materials |
| 7.3 LbL Assembly |
| 7.4 LbL Assembly on MS Substrates |
| 7.5 LbL Assembly on Macroporous Substrates |
| 7.6 Summary and Outlook |
| References |
| 8 Bio-inorganic Nanohybrids Based on Organoclay Self-assemblyAvinash J. Patil and Stephen Mann |
| 8.1 Introduction |
| 8.2 Synthesis and Characterization of Organically Functionalized 2:1 Magnesium Phyllosilicates |
| 8.3 MagnesiumOrganophyllosilicates withHigher-order Organization |
| 8.4 Intercalation of Biomolecules within Organically Modified Magnesium Phyllosilicates |
| 8.5 Hybrid Nanostructures Based on Organoclay Wrapping of Single Biomolecules |
| 8.6 Functional Mesolamellar Bio-inorganic Nanocomposite Films |
| 8.7 S |
