It is still the very beginning of generating a better understanding of what is needed to make an organism tolerate implants, to guarantee the bidirectional communication between microelectronic devices and living tissue or to simply construct an interactive biocompatibility of surfaces in general. This book describes the design, synthesis, assembly and characterization, and the bio-(medical) application of interfacial layers on solid substrates with molecularly or supra-molecularly controlled architectures. Experts in the field describe their contributions that have been developed in recent years.
It is still the very beginning of generating a better understanding of what is needed to make an organism tolerate implants, to guarantee the bidirectional communication between microelectronic devices and living tissue or to simply construct an interactive biocompatibility of surfaces in general. This book describes the design, synthesis, assembly and characterization, and the bio-(medical) application of interfacial layers on solid substrates with molecularly or supra-molecularly controlled architectures. Experts in the field describe their contributions that have been developed in recent years.
Self-Assembled Monolayers (SAMs). Multi-Valent Chelator SAMs. Gemini SAMs. PEG SAMs. Electrochemically Designed SAMs. Polymer Brushes. Ultra-Sensitive Biosensing with Polymer Brushes. Noncovalent Anchoring of Proteins to Surfaces. S-Layer Proteins. Heparan Sulfate Surfaces to Probe the Functions of the Master Regulator of the Extracellular Space. Hemocompatible Surfaces. Peptide Nanotube Coatings for Bioapplications. Proteoglycanylated Surfaces. Surface-Attached Polymeric Hydrogel Films. Evanescent Wave Biosensors with Hydrogels Binding Matrix. IPNs. Biofunctional Grafted Dendrons. Glucase Biosensors: Transduction Method, Redox Materials, and Bio-Interface. Modification of Glass Surfaces by Phosphorus Dendrimer Layers for Biosensors. Tethering Lipid Bilayers to Solid Supports. In vitro Synthesis of Membrane Proteins. Integrin-Functionalized Artificial Membranes as Test Platforms for Monitoring Small Integrin Ligand Binding by Surface Plasmon-Enhanced Fluorescence Spectroscopy. Wetting of Surfaces by Lipid Bilayers. Patterned Lipid Bilayers on Solid Substrate as a Model System of the Biological Membrane. Electrically Addressable, Biologically Relevant Surface Supported Bilayers. Nanopatterning of Biomolecules by Dip Pen Lithography. Surfaces for Stem Cell Propagation. Mechanical Cues for Cell Culture. Constructing Defined Networks of Neurons. Mineralization on a Biomimetic Surface.MO-CVD on patterned SAMs. Application of Biofunctional Surfaces in Medical Diagnostics. Nanopatterning for Bioapplications.
Wolfgang Knoll received a Ph.D. degree in biophysics at the University of Konstanz in 1976. In 1977, he joined the group of Prof. E. Sackmann at the University of Ulm, Germany, working on model membrane systems and their phase behavior by neutron scattering, spectroscopic and thermodynamic measurements. After a postdoctoral stay at the IBM Research Laboratory in San Jose, California (1980--1981) and a stay as a visiting scientist at the Institute Laue-Langevin in Grenoble, he joined the Physics Department of the Technical University of Munich. From 1991 to 1999, he was Head of Laboratory for Exotic Nanomaterials hosted by the Institute of Physical and Chemical Research in Wako, Japan. In 1992, he was appointed consulting professor at the Department of Chemical Engineering at Stanford University, California. In 1998, he was appointed professor of chemistry (by courtesy) at the University of Florida in Gainesville and in 1999 adjunct professor at Hanyang University in Seoul, South Korea. His current research interests include aspects of the structure/order--property/function relationships of polymeric/organic systems, in particular, in thin films and at functionalized surfaces.
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