Reprint

Advances in Biocompatible and Biodegradable Polymers

Volume II

Edited by
April 2023
484 pages
  • ISBN978-3-0365-7406-6 (Hardback)
  • ISBN978-3-0365-7407-3 (PDF)

This is a Reprint of the Special Issue Advances in Biocompatible and Biodegradable Polymers that was published in

This Reprint is part of the book set Advances in Biocompatible and Biodegradable Polymers.

Chemistry & Materials Science
Engineering
Summary

Among the strategies for reducing the negative effects on the environment effected by the uncontrolled consumption and low potential for the recovery of conventional plastics, the synthesis of new biodegradable and recyclable plastics represents one of the most promising methods for minimizing the negative effects of conventional non-biodegradable plastics. The spectrum of existing biodegradable materials is still very narrow; thus, to achieve greater applicability, research is being carried out on biodegradable polymer mixtures, the synthesis of new polymers, and the incorporation of new stabilizers for thermal degradation, alongside the use of other additives such as antibacterials or new and more sustainable plasticizers. Some studies analyze direct applications, such as shape memory foams, new cartilage implants, drug release, etc.The reader can find several studies on the degradation of biodegradable polymers under composting conditions; however, novel bacteria that degrade polymers considered non-biodegradable in other, unusual conditions (such as conditions of high salinity) are also presented.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
rice husk waste; polybutylenes adipate-Co-terephthalate (PBAT); polybutylene succinate (PBS); eosinophilic esophagitis (EoE), esophageal drug delivery systems; drug-eluting string; 3D printing; photopolymerizable resins; Drug loading strategies; steroids; fluticasone; bamboo fiber; cellulose nanofiber; adhesion; multiscale hybridization; fibrous composite; oil palm empty fruit bunch (OPEFB); microcrystalline cellulose; nano-bentonite; bio-composites; tensile properties; modified PU film; protein adsorption; antibacterial; hyaluronic acid (HA); polyhexamethylene guanidine (PHMG); liposomes; dexketoprofen; biocompatibility; hot plate test; rats; polyethylene glycol; polylactic acid; starch mixture; hydrolytic degradation; biodegradation; almond shell; starch thermoplastic polymer; biodegradable; biocomposite; recycling; reprocessing cycle; injection molding; natural filler; PLA; epoxidized chia seed oil (ECO); plasticizers; migration; disintegration; polylactic acid; PLA; poly(butylene adipate-co-terephthalate; PBAT; gum rosin; biodegradable polymers; barrier properties; biomaterials; biodegradation; bioplastics; mechanical performance; barrier performance; processability; TMDCs-WS2; PLLA; PVDF; nanomaterials; morphology; crystallization; dynamic-mechanical properties; photodegradation; biodegradable polymer; poly(butylene succinate-co-adipate); Zn-Ti LDH; bioplastics; PHBV; rheological characterization; plastics processing; Flory–Huggins; free energy of mixing; glass transition temperature; group contribution; molecular weight; miscibility prediction; PBAT; PLA; simulation; solubility parameter; biodegradable packaging; biopolymer; starch; storage conditions; thermal properties; physicochemical properties; maleinized hemp seed oil; maleinized Brazil nut seed oil; bio-plasticizers; polylactic acid; absorbency; commercial biopolymer additive (CBA); micro/nanofibrillated cellulose (CMF); softness; strength; tissue paper materials; antioxidant; antioxidant polymers; lignin polymers; graft polymers; dopamine; polydopamine; inulin; quercetin; limonene; vitamins; polycaprolactone (PCL); polyesters; hydrophobic-hydrophilic balance (HHB); nanoparticle formulation; nanoparticle crystallinity; FLAP antagonist; BRP-187; polylactide; biofoam; hydrolysis; degradation; drug; controlled release; polysaccharide; probiotics; biosensor; laser-induced graphene; polyimide; glucose; enzyme; mesenchymal stem cells; polymers; matrix; stiffness; osteoblasts; differentiation; cartilage defect; knee; Kartigen®; chondrocyte precursors; stem cell therapy; polylactic acid; silica; composites; thermal stability; toughness; biodegradability; 3D printing applications; non-viral vectors; polymers; liposomes; gold nanoparticles; mesoporous silica nanoparticles; carbon nanotubes; nanoparticle size distribution; cellulose nanocrystals; negative staining; cryo-TEM ADF-STEM; electron tomography; coffee-ring effect; fractionation; vinyl addition polymerization; ring-opening polymerization (ROP); bromolactide; methylenelactide; poly(methylenelactide); poly(methylenelactide-g-L-lactide); thermal stability; 3D scaffolds; biomaterial engineering; tissue engineering; mesenchymal stem cells; polymeric foams; surface functionalization; protein nanoparticles; cell growth; compressed fluids; Freon R134a; biodegradation; polystyrene; comparison; gut microbes; insect larvae; MXene; PHBV; composite membrane; hydrophilicity; antibacterial properties; coagulation; PLLA; hydroxyapatite; WS2 nanotubes; biodegradable polymers; mechanical properties; PLA; PA; bioblend; thermal stability; kinetic models; reaction mechanisms; random scission; shape memory polymers; polyurethanes; oxidation; degradation; biostable; foams; additive manufacturing; surface roughness; FFF; ANFIS; modeling; desirability; biomaterials; filaments; antimicrobial; fused filament fabrication (FFF); fused deposition modelling (FDM); Poly(lactic acid) (PLA); starch-based bioplastic; chitosan; co-polymer; reinforcement; biodegradation; biodegradation; biosynthesized polyesters; polyhydroxyalkanoates; seawater; residual toxicity assessment; thermochromic printing inks; UV stability; polycaprolactone; nanoparticles; TiO2; ZnO; poly (lactic acid); Kraft lignin; tannin; multifunctionality of PLA composites; surface mechanical properties; antioxidant/antibacterial activity; poly-β-hydroxybutyrate; plasticizer; biodegradation; imagery analysis; Actinomucor elegans; materials testing; resin based dental materials; biocompatibility; monomer; bisphenol A; elution; leaching; adipate; effective plasticizer; environmentally friendly; esterification; polyvinyl chloride; technological; sustainability; levoglucosenone; oxa-Michael addition; cross-linkable polymers; renewable polyesters; biodegradation; biosurfactants; thermostability; emulsion stability; rheology; PHA extraction; chemical digestion; design of experiments; polymer properties; micro-pollutants; landfill; soil biota; polyethylene; polyester; polysaccharide; FucoPol; response surface methodology; oil-in-water emulsions; rheology; texture; poly(lactic acid); PLA; biocomposites; mineral filler; calcium sulfate; natural gypsum; anhydrite II; melt–mixing; thermal and mechanical properties; crystallization; Vicat softening temperature; injection molding and extrusion; technical applications; biodegradation; keratin; feather; poultry waste; nonwovens; electrocardiography; electromyography; PEDOT:PSS; degradability; polymer electrode; phytopathogenic fungi; polysaccharides; plant protection; antifungal coatings; seed coating; seed treatments; field applications; pre-harvest treatments; post-harvest treatments; edible coatings; Poly(L–lactic acid); Poly(D–lactic acid); stereocomplex; magnesium hydroxide; biodegradable vascular scaffold; nanoparticles