3D printed TCP-based scaffold incorporating VEGF-loaded PLGA microspheres for craniofacial tissue engineering

Vascularization is a critical process during bone regeneration/repair and the lack of tissue vascularization is recognized as a major challenge in applying bone tissue engineering methods for cranial and maxillofacial surgeries. The aim of our study is to fabricate a vascular endothelial growth fact...

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Bibliographic Details
Published in:Dental materials 2017-11, Vol.33 (11), p.1205-1216
Main Authors: Fahimipour, F., Rasoulianboroujeni, M., Dashtimoghadam, E., Khoshroo, K., Tahriri, M., Bastami, F., Lobner, D., Tayebi, L.
Format: Article
Language:English
Subjects:
3-D printers
3D printing
Alginic acid
Bioavailability
Biocompatibility
Biomedical materials
Bone growth
Calcium phosphates
Cancellous bone
Cartridges
Cell culture
Cell proliferation
Defects
Dentistry
Endothelial cells
Formulations
Gelatin
Kinetics
Maxillofacial
Microspheres
Modulus of elasticity
PLGA microsphere
Polylactide-co-glycolide
Printing
Regeneration
Regeneration (physiology)
Rheological properties
Scaffold
Scaffolds
Skull
Three dimensional composites
Three dimensional printing
Tissue culture
Tissue engineering
Umbilical vein
Vascular endothelial growth factor
Vascularization
VEGF
β-Tricalcium phosphate
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Summary:Vascularization is a critical process during bone regeneration/repair and the lack of tissue vascularization is recognized as a major challenge in applying bone tissue engineering methods for cranial and maxillofacial surgeries. The aim of our study is to fabricate a vascular endothelial growth factor (VEGF)-loaded gelatin/alginate/β-TCP composite scaffold by 3D printing method using a computer-assisted design (CAD) model. The paste, composed of (VEGF-loaded PLGA)-containing gelatin/alginate/β-TCP in water, was loaded into standard Nordson cartridges and promptly employed for printing the scaffolds. Rheological characterization of various gelatin/alginate/β-TCP formulations led to an optimized paste as a printable bioink at room temperature. The in vitro release kinetics of the loaded VEGF revealed that the designed scaffolds fulfill the bioavailability of VEGF required for vascularization in the early stages of tissue regeneration. The results were confirmed by two times increment of proliferation of human umbilical vein endothelial cells (HUVECs) seeded on the scaffolds after 10 days. The compressive modulus of the scaffolds, 98±11MPa, was found to be in the range of cancellous bone suggesting their potential application for craniofacial tissue engineering. Osteoblast culture on the scaffolds showed that the construct supports cell viability, adhesion and proliferation. It was found that the ALP activity increased over 50% using VEGF-loaded scaffolds after 2 weeks of culture. The 3D printed gelatin/alginate/β-TCP scaffold with slow releasing of VEGF can be considered as a potential candidate for regeneration of craniofacial defects.
ISSN:0109-5641
1879-0097
DOI:10.1016/j.dental.2017.06.016