Polymer Materials for Drug Delivery and Tissue Engineering

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

silk sericin; nanoprecipitation; breast cancer; doxorubicin; P(3HB-co-4HB); silver sulfadiazine; collagen peptide; infection-resistance scaffolds; transdermal drug delivery system (TDDS); hydroxypropyl methyl cellulose (HPMC); ethyl cellulose (EC); methotrexate; patches; silk fibroin; spider silk; hydrogel; self-assembly; cell culture; benzydamine; casein; biopolymers; nanoparticles; nano spray drying; nano micelles; drug delivery; poly(hydroxyalkylmethacrylate)/Naproxen; drug release; solubility enhancement; drug-polymer miscibility; cell adhesion; toxicity; performance comparison; biocompatible; antibacterial; halloysite; erythromycin; polycaprolactone; nanofibers; electrospinning; tissue engineering; biopolymers; demineralized human spongiosa; scanning electron microscopy; micro-computed tomography; Raman spectroscopy; proteomic analysis; chondroblasts; tissue engineering; scaffold; fluorophores; organ-on-chip; tumor-on-chip; polymeric microfluidic devices; kidney-on-chip; bladder-on-chip; prostate-on-chip; nanotechnology; burn wound; ex-vivo permeation; essential oil; statins; Box–Behnken design; antibacterial; biopolymers; curcumin; drug delivery; hydrogels; pH-responsive; skin wound healing; colon cancer; targeted delivery; folate-conjugated nanoparticles; cytotoxicity; elastin; collagen; polymerization; fiber formation; synthetic dural substitute; drug release; antibiotics carrier; cefazolin; polycaprolactone; diopside; akermanite; merwinite; electrospinning; bone scaffolds; thermoresponsive copolymer; curcumin; pH-stimuli; cytocompatibility; drug delivery; n/a