Reprint
Advances in Chitin/Chitosan Characterization and Applications
Edited by
April 2019
414 pages
- ISBN978-3-03897-802-2 (Paperback)
- ISBN978-3-03897-803-9 (PDF)
This is a Reprint of the Special Issue Advances in Chitin/Chitosan Characterization and Applications that was published in
Chemistry & Materials Science
Engineering
Summary
Functional advanced biopolymers have received far less attention than renewable biomass (cellulose, rubber, etc.) used for energy production. Among the most advanced biopolymers known is chitosan. The term chitosan refers to a family of polysaccharides obtained by partial de-N-acetylation from chitin, one of the most abundant renewable resources in the biosphere. Chitosan has been firmly established as having unique material properties as well as biological activities. Either in its native form or as a chemical derivative, chitosan is amenable to being processed—typically under mild conditions—into soft materials such as hydrogels, colloidal nanoparticles, or nanofibers. Given its multiple biological properties, including biodegradability, antimicrobial effects, gene transfectability, and metal adsorption—to name but a few—chitosan is regarded as a widely versatile building block in various sectors (e.g., agriculture, food, cosmetics, pharmacy) and for various applications (medical devices, metal adsorption, catalysis, etc.). This Special Issue presents an updated account addressing some of the major applications, including also chemical and enzymatic modifications of oligos and polymers. A better understanding of the properties that underpin the use of chitin and chitosan in different fields is key for boosting their more extensive industrial utilization, as well as to aid regulatory agencies in establishing specifications, guidelines, and standards for the different types of products and applications.
Format
- Paperback
License and Copyright
© 2019 by the authors; CC BY-NC-ND license
Keywords
aerogels; chitosan; ionic liquids; ionogels; zinc–chitosan complexes; characterization; bio-sorbent; phosphate; adsorption; mechanism; thermodynamic; chitosan; hydrogel; phase transition; gelation mechanism; chitosan; defense responses; fruits; nanoparticles; plant growth; pesticides; Boron; chitosan; iron(III) hydroxide; neodymium; sorption; chitin; chitosan; chitosan derivative; chitin derivative; oral care; skin care; hear care; marine resources; over-the counter-drug; polymer carrier; chitin; chitosan; nanostructured biomaterial; polymer; self-masking nanosphere lithography; cicada; chitosan; self-assembled; polyelectrolyte complex; nanoparticle; drug delivery; Citrobacter; biosynthesis; bioflocculant; chitosan; metabolic pathway; PEO/chitosan blend; swelling; mechanical properties; wet and dried states; chitosan; biological activity; medical applications; chitosan; PCL; strontium; scaffolds; craniofacial engineering; chitin; chitosan; derivatization; controlled functionalization; click chemistry; graft copolymer; cyclodextrin; dendrimer; ionic liquids; chitin deacetylases; chitosan; chitooligosaccharides; carbohydrate esterases; structure; substrate specificity; deacetylation pattern; binary; chitosan; desorption; iron; lead; mercury; salt effects; single; sorption competition; chitosan supported copper; heterogeneous catalyst; organosilicon compound; easily recyclable; chitosan; papermaking; wet-end; coating; wastewater; ionic cross-linking; eco-friendly formulations; thermal transition sol-gel; drug delivery systems; MTDSC; DSC; gene delivery; non-viral vectors; chitosan structure; pDNA; siRNA; TEOS; methylene blue; chitosan; modelling; cross-linking; interpenetrating; XRD; FTIR