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TY  - BOOK
ID  - 135903014
TI  - Physical Vapor Deposited Biomedical Coatings
AU  - Stan, George E.
AU  - Stuart, Bryan W.
PY  - 2021
PB  - Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute
DB  - UniCat
KW  - pulsed electron deposition
KW  - thin films
KW  - orthopedic applications
KW  - bioactivity
KW  - ceramic coatings
KW  - yttria-stabilized zirconia
KW  - calcium phosphates
KW  - hydroxyapatite
KW  - biomimetic coatings
KW  - antibacterial coatings
KW  - thin film
KW  - RF magnetron sputtering
KW  - pulsed DC
KW  - Silicon
KW  - bio-coatings
KW  - biomimetics
KW  - laser deposition
KW  - PLD
KW  - MAPLE
KW  - tissue engineering
KW  - cancer
KW  - titanium-based carbonitrides
KW  - coating
KW  - corrosion resistance
KW  - X-ray diffraction
KW  - nanoindentation
KW  - cathodic arc deposition
KW  - biological-derived hydroxyapatite coatings
KW  - lithium doping
KW  - food industrial by-products
KW  - in vivo extraction force
KW  - pulsed laser deposition
KW  - 3D printing
KW  - calcium phosphate
KW  - PEEK
KW  - surface modification
KW  - sputtering
KW  - ToFSIMS
KW  - XPS
KW  - implant coating
KW  - bioactive glass
KW  - copper doping
KW  - gallium doping
KW  - mechanical
KW  - cytocompatibility
KW  - antibacterial
KW  - physical vapour deposition
KW  - thin-films
KW  - medical devices
KW  - biomimicry
UR  - https://www.unicat.be/uniCat?func=search&query=sysid:135903014
AB  - 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.
ER  -