Advanced Polymers for Biomedical Applications

doi:10.3390/books978-3-0365-4613-1

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Advanced Polymers for Biomedical Applications

Edited by

June 2022

432 pages

ISBN978-3-0365-4614-8 (Hardback)
ISBN978-3-0365-4613-1 (PDF)

https://doi.org/10.3390/books978-3-0365-4613-1

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This book is a reprint of the Special Issue Advanced Polymers for Biomedical Applications that was published in

Chemistry & Materials Science

Engineering

Summary

Polymers are the largest and most versatile class of biomaterials, being extensively applied for therapeutic applications. From natural to synthetic polymers, the possibilities to design and modify their physical-chemical properties make these systems of great interest in a wide range of biomedical applications as diverse as drug delivery systems, organ-on-a-chip, diagnostics, tissue engineering, and so on.In recent years, advances in the synthesis and modification of polymers and characterization techniques have allowed the design of novel biomaterials as well as the study of their biological behavior in vitro and in vivo.The purpose of this Special Issue is to highlight recent achievements in the synthesis and modification of polymers for biomedical applications for final applications in the field of biomedicine.

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Keywords

biocomposite; chitosan; chlorhexidine; coating; hernia; mesh infection; nanoparticles; PLGA; polypropylene; rifampicin; 3D-bioprinting; static mixer; reactive hydrogel; chitosan; hyaluronic acid; modified chitosan; curcumin; microwave; nanoparticles; interpenetrated polymer network; semi-IPN; methacrylated hyaluronic acid; chitosan; glycerylphytate; mesenchymal stem cell; bioadhesion; biomaterials; biomedical application; healthcare system management; innovation; polymer based bioadhesive; polymers; magnetite nanoparticles; chitosan; Tween 80; synthesis; nanotoxicology; genotoxicity; hemotoxicity; soy protein; film; semiconductor; biomaterial; additive manufacturing; sterilization; medical devices; bioabsorbable; polymer; biopolymer; hydrogel; microparticles; dye release; drug delivery system; dual-responsiveness; dendritic polyglycerol sulfates; biofabrication; microfluidics; electrospinning; 3D printing; electrospraying; natural polymers; cell encapsulation; polymeric prodrug; dual-sensitive; combination chemotherapy; drug conjugation; dextran; hydrogels; carboxymethyl cellulose; succinoglycan; metal coordination; drug delivery; swelling properties; extracellular matrix; hydrogels; external stimuli; tissue maturation; drug delivery; gelatin; sodium carboxymethyl cellulose; scaffold; A549 cells; freeze drying; silicone rubber; biomechanical; hyper-elastic; constitutive model; FEA; pH-sensitive hydrogel; poly(acrylic acid); quartz crystal microbalance (QCM); ellipsometric measurement; antibacterial activity; Ganoderma lucidum; polysaccharides; cisplatin; synergistic effect; anti-lung cancer; nanocellulose fiber; hydrogel; low methoxyl pectin; sodium alginate; clindamycin; pancreatic cancer; gemcitabine; controlled release; non-woven sheet; chemotherapy; antitumor efficacy; poly(L-lactic acid); antimicrobials agents; amphiphilic block copolymer; quaternized polymer; hemolysis; micelle; black phosphorus; polyetheretherketone; lubrication properties; antibacterial properties; sensorineural hearing loss; cochlear implants; self-bending electrode arrays; silicone rubber–hydrogel composites; actuators; swelling behavior; curvature; biocompatibility; nanofibrous dura mater; antifibrosis; neuroprotection; PLGA; tetramethylpyrazine