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Discover a rigorous treatment of aerogels processing and techniques for characterization with this easy-to-use reference. Presents the basics of aerogel synthesis and gelation to open porous nanostructures, and the processing of wet gels like ambient and supercritical drying leading to aerogels. Describes their essential properties with their measurement techniques and theoretical models used to analyse relations to their nanostructure. Linking the fundamentals and with practical applications, this is a useful toolkit for advanced undergraduates, and graduate students doing research in material and polymer science, physical chemistry, and chemical and environmental engineering.

Aerogels. --- Polymer colloids.

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This indispensable handbook provides comprehensive coverage of the current state-of-the-art in inorganic, organic, and composite aerogels – from synthesis and characterization to cutting-edge applications and their potential market impact. Built upon Springer’s successful Aerogels Handbook published in 2011, this handbook features extensive revisions and timely updates, reflecting the changes in this fast-growing field. Aerogels are the lightest solids known to man. Up to 1000 times lighter than glass and with a density only four times that of air, they possess extraordinarily high thermal, electrical, and acoustic insulation properties, and boast numerous entries in Guinness World Records. Originally based on silica, R&D efforts have extended this class of materials to incorporate non-silicate inorganic oxides, natural and synthetic organic polymers, carbon, metal, and ceramic materials. Composite systems involving polymer-crosslinked aerogels and interpenetrating hybrid networks have been developed and exhibit remarkable mechanical strength and flexibility. Even more exotic aerogels based on clays, chalcogenides, phosphides, quantum dots, and biopolymers such as chitosan are opening new applications for the construction, transportation, energy, defense and healthcare industries. Applications in electronics, chemistry, mechanics, engineering, energy production and storage, sensors, medicine, nanotechnology, military and aerospace, oil and gas recovery, thermal insulation, and household uses are being developed. Readers of this fully updated and expanded edition will find an exhaustive source for all aerogel materials known today, their fabrication, upscaling aspects, physical and chemical properties, and the most recent advances towards applications and commercial use. This key reference is essential reading for a combined audience of graduate students, academic researchers, and industry professionals.

Aerogels. --- Ceramic materials. --- Inorganic chemistry. --- Microtechnology. --- Microelectromechanical systems. --- Energy storage. --- Biotechnology. --- Building materials. --- Ceramics. --- Inorganic Chemistry. --- Microsystems and MEMS. --- Mechanical and Thermal Energy Storage. --- Structural Materials. --- Aerogels

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Biopolymers including natural (e.g., polysaccharides, proteins, gums, natural rubbers, bacterial polymers), synthetic (e.g., aliphatic polyesters and polyphosphoester), and biocomposites are of paramount interest in regenerative medicine, due to their availability, processability, and low toxicity. Moreover, the structuration of biopolymer-based materials at the nano- and microscale along with their chemical properties are crucial in the engineering of advanced carriers for drug products. Finally, combination products including or based on biopolymers for controlled drug release offer a powerful solution to improve the tissue integration and biological response of these materials. Understanding the drug delivery mechanisms, efficiency, and toxicity of such systems may be useful for regenerative medicine and pharmaceutical technology. The main aim of the Special Issue on “Biopolymers in Drug Delivery and Regenerative Medicine” is to gather recent findings and current advances on biopolymer research for biomedical applications, particularly in regenerative medicine, wound healing, and drug delivery. Contributions to this issue can be as original research or review articles and may cover all aspects of biopolymer research, ranging from the chemical synthesis and characterization of modified biopolymers, their processing in different morphologies and hierarchical structures, as well as their assessment for biomedical uses.

Medicine --- curcumin --- pectin aerogels --- chitosan coating --- burst release --- controlled release --- Keratose --- drug-coated balloon --- paclitaxel --- drug delivery --- pre-clinical --- peripheral arterial disease --- endovascular --- cellulose phosphate --- cellulose phosphate aerogel --- interconnected porosity --- supercritical carbon dioxide --- tetrabutylammonium fluoride --- TBAF/DMSO --- polysaccharide --- κ-carrageenan --- dexamethasone --- electrochemical active deliver system --- doping agent --- charged molecule --- conductive polymers --- colorectal cancer --- antioxidants --- 5-fluorouracil --- polymer nanomaterials --- nanocapsules --- chemotherapy --- cryogel --- starch --- NMR spectroscopy --- morphology --- drug release --- polysaccharides --- hydrogels --- prilling --- droplets --- ionotropic gelation --- drying --- xerogels --- cryogels --- aerogels --- lipid microparticles --- PGSS® --- supercritical CO2 --- modeling --- solvent-free technology --- biomaterials --- porous materials --- biomimetic --- multi-stimulation --- tissue engineering --- n/a

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Biopolymers including natural (e.g., polysaccharides, proteins, gums, natural rubbers, bacterial polymers), synthetic (e.g., aliphatic polyesters and polyphosphoester), and biocomposites are of paramount interest in regenerative medicine, due to their availability, processability, and low toxicity. Moreover, the structuration of biopolymer-based materials at the nano- and microscale along with their chemical properties are crucial in the engineering of advanced carriers for drug products. Finally, combination products including or based on biopolymers for controlled drug release offer a powerful solution to improve the tissue integration and biological response of these materials. Understanding the drug delivery mechanisms, efficiency, and toxicity of such systems may be useful for regenerative medicine and pharmaceutical technology. The main aim of the Special Issue on “Biopolymers in Drug Delivery and Regenerative Medicine” is to gather recent findings and current advances on biopolymer research for biomedical applications, particularly in regenerative medicine, wound healing, and drug delivery. Contributions to this issue can be as original research or review articles and may cover all aspects of biopolymer research, ranging from the chemical synthesis and characterization of modified biopolymers, their processing in different morphologies and hierarchical structures, as well as their assessment for biomedical uses.

Medicine --- curcumin --- pectin aerogels --- chitosan coating --- burst release --- controlled release --- Keratose --- drug-coated balloon --- paclitaxel --- drug delivery --- pre-clinical --- peripheral arterial disease --- endovascular --- cellulose phosphate --- cellulose phosphate aerogel --- interconnected porosity --- supercritical carbon dioxide --- tetrabutylammonium fluoride --- TBAF/DMSO --- polysaccharide --- κ-carrageenan --- dexamethasone --- electrochemical active deliver system --- doping agent --- charged molecule --- conductive polymers --- colorectal cancer --- antioxidants --- 5-fluorouracil --- polymer nanomaterials --- nanocapsules --- chemotherapy --- cryogel --- starch --- NMR spectroscopy --- morphology --- drug release --- polysaccharides --- hydrogels --- prilling --- droplets --- ionotropic gelation --- drying --- xerogels --- cryogels --- aerogels --- lipid microparticles --- PGSS® --- supercritical CO2 --- modeling --- solvent-free technology --- biomaterials --- porous materials --- biomimetic --- multi-stimulation --- tissue engineering --- curcumin --- pectin aerogels --- chitosan coating --- burst release --- controlled release --- Keratose --- drug-coated balloon --- paclitaxel --- drug delivery --- pre-clinical --- peripheral arterial disease --- endovascular --- cellulose phosphate --- cellulose phosphate aerogel --- interconnected porosity --- supercritical carbon dioxide --- tetrabutylammonium fluoride --- TBAF/DMSO --- polysaccharide --- κ-carrageenan --- dexamethasone --- electrochemical active deliver system --- doping agent --- charged molecule --- conductive polymers --- colorectal cancer --- antioxidants --- 5-fluorouracil --- polymer nanomaterials --- nanocapsules --- chemotherapy --- cryogel --- starch --- NMR spectroscopy --- morphology --- drug release --- polysaccharides --- hydrogels --- prilling --- droplets --- ionotropic gelation --- drying --- xerogels --- cryogels --- aerogels --- lipid microparticles --- PGSS® --- supercritical CO2 --- modeling --- solvent-free technology --- biomaterials --- porous materials --- biomimetic --- multi-stimulation --- tissue engineering

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This book explores the improvement in thermal insulation properties of protein-based silica aerogel composites fabricated by a novel, inexpensive and feasible method. The resulting material exhibits polymeric foam behavior including high compressibility, super-hydrophobic qualities and excellent strain recovery in addition to low thermal conductivity. The fabrication methodologies are explained in great detail and represented in flowcharts for easy reference and understanding. This monograph gives readers a new perspective on composite fabrication using methods other than the traditional ones and explores the endless ways of altering the composition to modify the properties of the silica aerogel composites. Applications for this novel composite are diverse and range from those in the pharmaceutical and aerospace industries to the oil and gas industries.

Materials Science --- Chemical Engineering --- Chemical & Materials Engineering --- Engineering & Applied Sciences --- Silica gel. --- Aerogels. --- Colloids --- Drying agents --- Ceramic materials --- Polymers. --- Ceramics, Glass, Composites, Natural Materials. --- Materials Engineering. --- Polymer Sciences. --- Polymere --- Polymeride --- Polymers and polymerization --- Macromolecules --- Ceramics. --- Glass. --- Composites (Materials). --- Composite materials. --- Engineering—Materials. --- Polymers  . --- Ceramic technology --- Industrial ceramics --- Keramics --- Building materials --- Chemistry, Technical --- Clay --- Composites (Materials) --- Multiphase materials --- Reinforced solids --- Solids, Reinforced --- Two phase materials --- Materials --- Amorphous substances --- Ceramics --- Glazing