00925nam1 22002531i 450 SUN004431720060414120000.020060414d1932 |0itac50 baitaIT|||| |||||Giornali di Napolidal 1547 al 1706Antonio Bulifona cura di Nino CorteseNapoliSocieta napoletana di storia patria1932v.28 cm.001SUN00443162001 Cronache e documenti per la storia dell'Italia meridionale dei secoli 16. e 17210 NapoliLubrano.001SUN00443182001 <<1: >>1547-1691NapoliSUNL000005Bulifon, AntonioSUNV03578537273Cortese, NinoSUNV035786Società napoletana di storia patriaSUNV001642650ITSOL20181109RICASUN0044317Giornali di Napoli222809UNICAMPANIA04694nam 2201273z- 450 9910404076103321202105013-03928-775-3(CKB)4100000011302377(oapen)https://directory.doabooks.org/handle/20.500.12854/68595(oapen)doab68595(EXLCZ)99410000001130237720202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierElectrospun Nanofibers for Biomedical ApplicationsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (310 p.)3-03928-774-5 Electrospinning is a versatile and effective technique widely used to manufacture nanofibrous structures from a diversity of materials (synthetic, natural or inorganic). The electrospun nanofibrous meshes' composition, morphology, porosity, and surface functionality support the development of advanced solutions for many biomedical applications. The Special Issue on "Electrospun Nanofibers for Biomedical Applications" assembles a set of original and highly-innovative contributions showcasing advanced devices and therapies based on or involving electrospun meshes. It comprises 13 original research papers covering topics that span from biomaterial scaffolds' structure and functionalization, nanocomposites, antibacterial nanofibrous systems, wound dressings, monitoring devices, electrical stimulation, bone tissue engineering to first-in-human clinical trials. This publication also includes four review papers focused on drug delivery and tissue engineering applications.History of engineering and technologybicssc3D printingalginateantibacterialantibacterial activityantibacterial coatingsantibody immobilizationantioxidant activitybioactive glassbiocompatibilitybiocompatible polymersbiomaterialsbiomedicalbiomedical applicationsbiomimetic scaffoldsbiopolymersbone regenerationcancer treatmentcell attachmentcell proliferationcomposite fibrescomposite nanofibercytotoxicitydrug deliverydrug releaseelectrospinningelectrospun fiber matselectrospun nanofibersencapsulationfabricationfinite element modelinggelatingelatin fibersglioblastomaguided tissue regeneration (GTR)hepatocellular carcinoma cellshuman articular chondrocyteshydroxyapatitehyperthermiaimmuno-isolationin vivo tissue engineeringlive assaymechanobiologymicrofluidic chipmicromoldingnanocomposite coatingsnanofibernanofibersnanomedicineorthopedic infectionsP(VDF-TrFE)packagingpharmaceuticalphysical propertiespiezoelectric nanogeneratorpiezoelectricityPLA95poly(lactic acid) (PLLA)poly(vinylidene fluoride)preosteoblasts electrospinningprotein diffusionrheumatoid arthritisscaffoldssilicone modified polyurethane nanofiberssol-gelsputteringtherapeuticsTiO2 photocatalytictissue engineeringtitaniumTNF-α capturetransplantationwell-aligned nanofiberswound dressingZnO particlesHistory of engineering and technologyMartins Albinoedt1331938Reis RuiedtNeves NunoedtMartins AlbinoothReis RuiothNeves NunoothBOOK9910404076103321Electrospun Nanofibers for Biomedical Applications3040676UNINA