"Written for chemists, physicists, molecular biologists, and students in related fields, this reference covers information presently available on the specific properties of metallic nanoparticles, and compares their properties with those related to nanoobjects formed by biological molecules. It also discloses details of formation and physic-chemical peculiarities of the DNA nanostructures and DNA-based nanoconstructions. Timely in publication, the reference contains more DNA physics and molecular biology than other published titles. Authors discuss how nucleic acid molecules and their complexes with chemical and biologically active compounds are of great interest in the development of various nanoscale systems and devices of practical importance"-- Read more...
Content: Nanoparticles and Biological Molecules Metal Nanoparticles and Their Properties Biological Molecules: A New Background for the Creation of Nanoobjects Organization of Research in Nanotechnology Area The Health Risk of Nanomaterials Nanostructures Formed by Hybridization of Synthetic Single- Stranded DNA Molecules General Concept of the Fundamental Properties of DNA Used in Nanotechnology Hybridization Technique of Creating Nanostructures Based on Synthetic Single-Stranded DNA Molecules (Bottom-Up Approach to the Creation of DNA Nanostructures) Organic Linker Molecules as Rigid "Vertices" in the Tailored Spatial DNA Nanostructures Formed by Hybridization Technique Arrangement of Objects on the Surface of DNA Nanostructures "Liquid" Nanoconstructions Based on Spatially Ordered Double-Stranded DNA Molecules Double-Stranded DNA Molecules as Building Blocks for Nanotechnology Phase Exclusion of Double-Stranded DNA Molecules from Polyethylene Glycol Solutions The Cholesteric Mode of Nucleic Acid Molecules Packing in Particles of Dispersions Results in an Appearance of Abnormal CD Spectra Accumulation of the "Guest" Molecules in the DNA Molecules Forming CLCD Particles "Rigid" Nanoconstructions Based by Spatially Ordered Double-Stranded DNA Molecules Complexed with Various Compounds and Nanoparticles Backgrounds for Formation of Rigid DNA Nanoconstructions Rigid Nanoconstructions Formed as a Result of Formation of Nanobridges between Neighboring DNA Molecules Fixed in Quasinematic Layers The Magnetometric Evaluation of Cu2+ Ions in the Content of Nanobridges Formed between Spatially Fixed DNA Molecules Visualization of Rigid DNA Nanoconstructions Linked with Nanobridges and Manipulations with These Nanoconstructions Dependence of Optical Properties of DNA Nanoconstructions on Temperature Rigid Nanoconstruction Formed as a Result of Formation of Complexes of DNA Molecules Fixed in Quasinematic Layers with Rare-Earth Metal Cations Visualization of Rigid Particles of Cholesteric Liquid-Crystalline Dispersion of a [DNA-Gd3+] Complex Au Nanoparticles Can Induce Formation of Rigid DNA Nanoconstruction An Additional Case: Formation of Semi-Rigid Liquid-Crystalline Particles Viral Particles as "Rigid" Biological Nanoconstructions: Their Creation and Medical Application Prospects D. Yu. Logunov, B. S. Naroditsky, and A. L. Gintsburg A "PEG-Like Situation" in Biological Systems and Peculiarities of Biological Nanoconstructions Methods for Obtaining Recombinant Adenovirus "Rigid" Nanostructures Recombinant Adenovirus Nanostructures with a Modified Genome Replication-Competent Recombinant Adenovirus Nanostructures Replication-Incompetent Recombinant Adenovirus Nanostructures Capsid-Modified Recombinant Adenovirus Nanostructures Physicochemical Modifications of Recombinant Adenovirus Particles Application of Recombinant Adenovirus Nanostructures in Medicine Application of "Liquid" and "Rigid" DNA Nanoconstructions Immobilized in Polymeric Hydrogel as Sensing Units Issues of Stabilization of Particles of Liquid-Crystalline Dispersions Immobilization of DNA LCD Particles in a Hydrogel Formation and Immobilization of DNA Nanoconstruction in a Hydrogel
Abstract: "Written for chemists, physicists, molecular biologists, and students in related fields, this reference covers information presently available on the specific properties of metallic nanoparticles, and compares their properties with those related to nanoobjects formed by biological molecules. It also discloses details of formation and physic-chemical peculiarities of the DNA nanostructures and DNA-based nanoconstructions. Timely in publication, the reference contains more DNA physics and molecular biology than other published titles. Authors discuss how nucleic acid molecules and their complexes with chemical and biologically active compounds are of great interest in the development of various nanoscale systems and devices of practical importance"