01171nam0-2200397---450 99000576774020331620190403125030.0000576774USA01000576774(ALEPH)000576774USA0100057677420081205d1989----|||y0itaa50------baitait0 00|||Mathesis universalisgenesi di un'idea nel 16. secoloGiovanni CrapulliRomaedizioni dell' Ateneoc1989285 p.21 cm.Lessico intellettuale europeo22001Lessico intellettuale europeo2MatematicaTeorieStoriaFROMA510.9CRAPULLI,Giovanni160583ITSA20111219990005767740203316Dipar.to di Filosofia - SalernoDFCC 510.9 CRA3262 FILCC 510.9 CRA3262 FILBKFIL20121027USA01152620121027USA011615PATRY9020130226USA011542Mathesis universalis1082313UNISASA002660103804nam 2200961z- 450 991055744310332120220111(CKB)5400000000043291(oapen)https://directory.doabooks.org/handle/20.500.12854/76992(oapen)doab76992(EXLCZ)99540000000004329120202201d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierPhysical Vapor Deposited Biomedical CoatingsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (174 p.)3-0365-2414-2 3-0365-2415-0 The book outlines a series of developments made in the manufacturing of bio-functional layers via Physical Vapour-Deposited (PVD) technologies for application in various areas of healthcare. The scrutinized PVD methods include Radio-Frequency Magnetron Sputtering (RF-MS), Cathodic Arc Evaporation, Pulsed Electron Deposition and its variants, Pulsed Laser Deposition, and Matrix-Assisted Pulsed Laser Evaporation (MAPLE) due to their great promise, especially in dentistry and orthopaedics. These methods have yet to gain traction for industrialization and large-scale application in biomedicine. A new generation of implant coatings can be made available by the (1) incorporation of organic moieties (e.g., proteins, peptides, enzymes) into thin films using innovative methods such as combinatorial MAPLE, (2) direct coupling of therapeutic agents with bioactive glasses or ceramics within substituted or composite layers via RF-MS, or (3) innovation in high-energy deposition methods, such as arc evaporation or pulsed electron beam methods.Technology: general issuesbicssc3D printingantibacterialantibacterial coatingsbio-coatingsbioactive glassbioactivitybiological-derived hydroxyapatite coatingsbiomimetic coatingsbiomimeticsbiomimicrycalcium phosphatecalcium phosphatescancercathodic arc depositionceramic coatingscoatingcopper dopingcorrosion resistancecytocompatibilityfood industrial by-productsgallium dopinghydroxyapatiteimplant coatingin vivo extraction forcelaser depositionlithium dopingMAPLEmechanicalmedical devicesnanoindentationorthopedic applicationsPEEKphysical vapour depositionPLDpulsed DCpulsed electron depositionpulsed laser depositionRF magnetron sputteringSiliconsputteringsurface modificationthin filmthin filmsthin-filmstissue engineeringtitanium-based carbonitridesToFSIMSX-ray diffractionXPSyttria-stabilized zirconiaTechnology: general issuesStan George Eedt1311342Stuart Bryan WedtStan George EothStuart Bryan WothBOOK9910557443103321Physical Vapor Deposited Biomedical Coatings3030268UNINA