Advances in Biocompatible and Biodegradable Polymers

© 2022 by the authors; CC BY-NC-ND license

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