TY  - GEN
AU  - Dobrzański,Leszek Adam
AU  - Dobrzańska-Danikiewicz,Anna D.
AU  - Dobrzański,Lech Bolesław
AU  - Dobrzańska,Joanna
AU  - Dobrzański,Leszek Adam
AU  - Dobrzańska-Danikiewicz,Anna D.
AU  - Dobrzański,Lech Bolesław
AU  - Dobrzańska,Joanna
TI  - Synthesis and Characterization of Biomedical Materials
SN  - books978-3-0365-2523-5
PY  - 2021///
CY  - Basel, Switzerland
PB  - MDPI - Multidisciplinary Digital Publishing Institute
KW  - Technology: general issues
KW  - bicssc
KW  - sol-gel phase transitions
KW  - injectable scaffolds
KW  - chitosan
KW  - calcium β-glycerophosphate
KW  - rheology
KW  - bone tissue engineering
KW  - diblock copolymers
KW  - drug delivery systems
KW  - nanoparticles
KW  - nanoprecipitation
KW  - self-assembly
KW  - implant
KW  - stainless steel
KW  - nickel
KW  - leaching
KW  - nitrogen
KW  - cytotoxicity
KW  - nanodendrites
KW  - nanostar
KW  - fibroblast cells
KW  - gelatin
KW  - one-pot synthesis
KW  - hollow mesoporous silica
KW  - porous silica
KW  - high drug loading capacity
KW  - drug delivery system
KW  - fretting
KW  - fretting wear
KW  - Ni-Cr-Mo
KW  - dental alloys
KW  - titaniumcarbonitride
KW  - Ti(C, N) coating
KW  - thin films
KW  - zirconium carbide
KW  - antimicrobial properties
KW  - medical implants
KW  - 316L stainless steel
KW  - sintering
KW  - surface nitriding
KW  - nitrogen absorption
KW  - response surface methodology
KW  - sodium alginate
KW  - hydrogel material
KW  - regenerative medicine
KW  - urethra
KW  - hybrid materials
KW  - hydroxyapatite
KW  - FEA
KW  - V-shaped tooth defects
KW  - fillings
KW  - glass-ionomer cement
KW  - flowable composite
KW  - stomatognathic system
KW  - prosthetic restorations
KW  - surgical guide
KW  - dental prosthesis restoration manufacturing center
KW  - CBCT tomography
KW  - dental implants
KW  - implant-scaffolds
KW  - hybrid multilayer biological-engineering composites biomaterials
KW  - CAD/CAM methods
KW  - additive manufacturing technologies
KW  - selective laser sintering
KW  - stereolithography
KW  - Dentistry 4.0
KW  - Industry 4.0
KW  - robocasting
KW  - bioactive glass
KW  - scaffold
KW  - sol-gel
KW  - 45S5 Bioglass®
KW  - biomaterials
KW  - biomedical implants
KW  - additive manufacturing
KW  - dental prosthetic restorations
KW  - Ti6Al4V dental alloy
KW  - structural X-ray analysis
KW  - energy-dispersive X-ray spectroscope
KW  - metallography
KW  - tensile and bending strength
KW  - corrosion resistance
KW  - tribological tests
KW  - in-vitro tests
KW  - industry 4.0
KW  - dentistry 4.0
KW  - SARS-CoV-2 pandemic
KW  - SPEC strategy
KW  - elimination clinical aerosol at the source
KW  - dendrological matrix
KW  - photopolymer materials
KW  - additive digital light printing
KW  - dentistry sustainable development
KW  - dental prophylaxis
KW  - dental interventionistic treatment
KW  - caries
KW  - periodontology
KW  - toothlessness
KW  - endodontics
KW  - dental implantology
KW  - dental prosthetics
KW  - dentist safety
KW  - dentist ethics
KW  - Co-Cr dental alloys
KW  - corrosion
KW  - porcelain firing
KW  - SLM
KW  - MSM
KW  - CST
KW  - light-cured composites
KW  - photopolymerization process
KW  - microhardness
KW  - optimization
KW  - regression analysis
KW  - health
KW  - well-being
KW  - long and healthy life policy
KW  - medicine
KW  - dentistry
KW  - medical ethics
KW  - COVID-19 pandemic
KW  - bioengineering
KW  - medical engineering
KW  - dental engineering
KW  - biomedical materials
KW  - Bioengineering 4.0
KW  - engineers' ethics
KW  - filling materials
KW  - sealants
KW  - obturation
KW  - gutta-percha
KW  - Resilon
KW  - procedural benchmarking
KW  - comparative matrices
KW  - virtual approach
KW  - digital twin
KW  - scanning electron microscopy
KW  - n/a
N1  - Open Access
N2  - This book aims to summarize the latest achievements in the development and manufacturing of modern biomaterials used in modern medicine and dentistry, for example, in cases where, as a result of a traffic or sports accident, aging, resection of organs after oncological surgery, or dangerous inflammation, there is a need to replace lost organs, tissues, and parts of the human body. The essence of biomedical materials is their constant contact with living tissues, organisms, or microorganisms and, therefore, they should meet numerous requirements from various fields, including medicine, biology, chemistry, tissue engineering, and materials science. For this reason, biomaterials must be compatible with the organism, and biocompatibility issues must be addressed before using the product in a clinical setting. The production and synthesis of biomaterials require the use of various technologies and methods to obtain the appropriate material, which is then processed using advanced material processing technologies. Often, however, it is necessary to directly manufacture a specific product with individualized geometric features and properties tailored to the requirements of a particular patient. In such cases, additive manufacturing methods are increasingly used. In this sense, it can be considered that the Biomaterials 4.0 stage has been reached, and detailed information is included in the individual chapters of this book on the achievements in the development and manufacturing of modern biomaterials used in modern regenerative medicine, regenerative dentistry, and tissue engineering
UR  - https://mdpi.com/books/pdfview/book/4734
UR  - https://directory.doabooks.org/handle/20.500.12854/77115
ER  -