Biomaterials for Tissue Engineering and Regeneration

Biomaterials are an integral component of tissue engineering, and their development is crucial to the progress of new and efficient approaches in the regenerative medicine of bone, cartilage, tendons and ligaments, skin, soft-tissue wounds, cardiac muscle, vascular tissues, and neural tissues.Polyme...

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collection Directory of Open Access Books
description Biomaterials are an integral component of tissue engineering, and their development is crucial to the progress of new and efficient approaches in the regenerative medicine of bone, cartilage, tendons and ligaments, skin, soft-tissue wounds, cardiac muscle, vascular tissues, and neural tissues.Polymer-based biomaterials are extensively studied in the field of tissue engineering due to their biocompatible and biodegradable properties. This Special Issue is devoted to recent developments of synthetic and/or natural biomaterial scaffolds, hydrogels, polypeptides, polymer-based composites, and composites based on polymers and inorganic materials, such as bioactive ceramics and glasses. New technologies (e.g., bioprinting, additive manufacturing, etc.) used to form biomaterials for tissue engineering of three-dimensional (3D) constructs are of particular interest.
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publisherStr MDPI - Multidisciplinary Digital Publishing Institute
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spelling doab-20.500.12854ir-966562024-03-30T23:21:49Z Biomaterials for Tissue Engineering and Regeneration Ressler, Antonia Urlic, Inga keratin hydrolysate bioactive keratin skin homeostasis restoration skin wound healing decellularization Tergitol valve bioprostheses cardiac tissue engineering mesenchymal stem cells biocompatibility oxidized sodium alginate oxidation degree biodegradation gelation ability rheological properties ascorbate ascorbyl palmitate drug delivery cellular uptake nanoparticles antitumor effect collagen tissue engineering biomaterials scaffolds heparinize bovine pericardium scaffold hemocompatibility endothelialization extracellular matrix porcine pericardium high hydrostatic pressurization method surfactant method 3D fabrication ligament hydrogel diabetic foot wound dressing bioactive glass polylactic acid electrochemical evaluations homografts ischaemic harvesting cryopreservation glutaraldehyde-fixation alginate chitosan bone regeneration composite polymer graphene osteogenesis rat femur defect in vivo bone healing injectable hydrogel chondrocytes co-cultures subcutaneous implantation cartilage regeneration PLGA electrospinning morphology immune response microscopy defect bone remodeling bovine hydroxyapatite calcium lactate BHA–GEL pellet PCL-PEG polymer micelle drug cargo breast cancer cross-linked hyaluronic acid nano hydroxyapatite bone morphogenetic protein injection-type bone forming material ectopic bone formation bone augmentation cell culture fibroblasts gelatin GelMA XPS (X-ray photoelectron spectroscopy) tensile properties in vitro study thema EDItEUR::M Medicine and Nursing Biomaterials are an integral component of tissue engineering, and their development is crucial to the progress of new and efficient approaches in the regenerative medicine of bone, cartilage, tendons and ligaments, skin, soft-tissue wounds, cardiac muscle, vascular tissues, and neural tissues.Polymer-based biomaterials are extensively studied in the field of tissue engineering due to their biocompatible and biodegradable properties. This Special Issue is devoted to recent developments of synthetic and/or natural biomaterial scaffolds, hydrogels, polypeptides, polymer-based composites, and composites based on polymers and inorganic materials, such as bioactive ceramics and glasses. New technologies (e.g., bioprinting, additive manufacturing, etc.) used to form biomaterials for tissue engineering of three-dimensional (3D) constructs are of particular interest. 2023-02-02T16:32:12Z 2023-02-02T16:32:12Z 2023 book ONIX_20230202_9783036563619_57 9783036563619 9783036563602 https://directory.doabooks.org/handle/20.500.12854/96656 eng image/jpeg Attribution 4.0 International https://mdpi.com/books/pdfview/book/6601 https://mdpi.com/books/pdfview/book/6601 MDPI - Multidisciplinary Digital Publishing Institute 10.3390/books978-3-0365-6360-2 10.3390/books978-3-0365-6360-2 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 9783036563619 9783036563602 366 Basel open access
spellingShingle keratin hydrolysate
bioactive keratin
skin homeostasis restoration
skin wound healing
decellularization
Tergitol
valve bioprostheses
cardiac tissue engineering
mesenchymal stem cells
biocompatibility
oxidized sodium alginate
oxidation degree
biodegradation gelation ability
rheological properties
ascorbate
ascorbyl palmitate
drug delivery
cellular uptake
nanoparticles
antitumor effect
collagen
tissue engineering
biomaterials
scaffolds
heparinize
bovine pericardium
scaffold
hemocompatibility
endothelialization
extracellular matrix
porcine pericardium
high hydrostatic pressurization method
surfactant method
3D fabrication
ligament
hydrogel
diabetic foot
wound dressing
bioactive glass
polylactic acid
electrochemical evaluations
homografts
ischaemic harvesting
cryopreservation
glutaraldehyde-fixation
alginate
chitosan
bone regeneration
composite
polymer
graphene
osteogenesis
rat femur defect
in vivo
bone healing
injectable hydrogel
chondrocytes
co-cultures
subcutaneous implantation
cartilage regeneration
PLGA
electrospinning
morphology
immune response
microscopy
defect
bone remodeling
bovine hydroxyapatite
calcium lactate
BHA–GEL pellet
PCL-PEG
polymer micelle
drug cargo
breast cancer
cross-linked hyaluronic acid
nano hydroxyapatite
bone morphogenetic protein
injection-type bone forming material
ectopic bone formation
bone augmentation
cell culture
fibroblasts
gelatin
GelMA
XPS (X-ray photoelectron spectroscopy)
tensile properties
in vitro study
thema EDItEUR::M Medicine and Nursing
Biomaterials for Tissue Engineering and Regeneration
title Biomaterials for Tissue Engineering and Regeneration
title_full Biomaterials for Tissue Engineering and Regeneration
title_fullStr Biomaterials for Tissue Engineering and Regeneration
title_full_unstemmed Biomaterials for Tissue Engineering and Regeneration
title_short Biomaterials for Tissue Engineering and Regeneration
title_sort biomaterials for tissue engineering and regeneration
topic keratin hydrolysate
bioactive keratin
skin homeostasis restoration
skin wound healing
decellularization
Tergitol
valve bioprostheses
cardiac tissue engineering
mesenchymal stem cells
biocompatibility
oxidized sodium alginate
oxidation degree
biodegradation gelation ability
rheological properties
ascorbate
ascorbyl palmitate
drug delivery
cellular uptake
nanoparticles
antitumor effect
collagen
tissue engineering
biomaterials
scaffolds
heparinize
bovine pericardium
scaffold
hemocompatibility
endothelialization
extracellular matrix
porcine pericardium
high hydrostatic pressurization method
surfactant method
3D fabrication
ligament
hydrogel
diabetic foot
wound dressing
bioactive glass
polylactic acid
electrochemical evaluations
homografts
ischaemic harvesting
cryopreservation
glutaraldehyde-fixation
alginate
chitosan
bone regeneration
composite
polymer
graphene
osteogenesis
rat femur defect
in vivo
bone healing
injectable hydrogel
chondrocytes
co-cultures
subcutaneous implantation
cartilage regeneration
PLGA
electrospinning
morphology
immune response
microscopy
defect
bone remodeling
bovine hydroxyapatite
calcium lactate
BHA–GEL pellet
PCL-PEG
polymer micelle
drug cargo
breast cancer
cross-linked hyaluronic acid
nano hydroxyapatite
bone morphogenetic protein
injection-type bone forming material
ectopic bone formation
bone augmentation
cell culture
fibroblasts
gelatin
GelMA
XPS (X-ray photoelectron spectroscopy)
tensile properties
in vitro study
thema EDItEUR::M Medicine and Nursing
topic_facet keratin hydrolysate
bioactive keratin
skin homeostasis restoration
skin wound healing
decellularization
Tergitol
valve bioprostheses
cardiac tissue engineering
mesenchymal stem cells
biocompatibility
oxidized sodium alginate
oxidation degree
biodegradation gelation ability
rheological properties
ascorbate
ascorbyl palmitate
drug delivery
cellular uptake
nanoparticles
antitumor effect
collagen
tissue engineering
biomaterials
scaffolds
heparinize
bovine pericardium
scaffold
hemocompatibility
endothelialization
extracellular matrix
porcine pericardium
high hydrostatic pressurization method
surfactant method
3D fabrication
ligament
hydrogel
diabetic foot
wound dressing
bioactive glass
polylactic acid
electrochemical evaluations
homografts
ischaemic harvesting
cryopreservation
glutaraldehyde-fixation
alginate
chitosan
bone regeneration
composite
polymer
graphene
osteogenesis
rat femur defect
in vivo
bone healing
injectable hydrogel
chondrocytes
co-cultures
subcutaneous implantation
cartilage regeneration
PLGA
electrospinning
morphology
immune response
microscopy
defect
bone remodeling
bovine hydroxyapatite
calcium lactate
BHA–GEL pellet
PCL-PEG
polymer micelle
drug cargo
breast cancer
cross-linked hyaluronic acid
nano hydroxyapatite
bone morphogenetic protein
injection-type bone forming material
ectopic bone formation
bone augmentation
cell culture
fibroblasts
gelatin
GelMA
XPS (X-ray photoelectron spectroscopy)
tensile properties
in vitro study
thema EDItEUR::M Medicine and Nursing
url ONIX_20230202_9783036563619_57