The pore size of polycaprolactone scaffolds has limited influence on bone regeneration in an in vivo model
Sara M. Mantila Roosa,Jessica M. Kemppainen,Erin N. Moffitt,Paul H. Krebsbach,Scott J. Hollister +4 more
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TLDR
Pore sizes between 350 and 800 microm play a limited role in bone regeneration in this tissue engineering model, and it may be advantageous to explore the effects of other scaffold structural properties, such as pore shape, pore interconnectivity, or scaffold permeability, on bone regeneration when designing PCL scaffolds for bone tissue engineering.Abstract:
Bone tissue engineering scaffolds should be designed to optimize mass transport, cell migration, and mechanical integrity to facilitate and enhance new bone growth. Although many scaffold parameters could be modified to fulfill these requirements, pore size is an important scaffold characteristic that can be rigorously controlled with indirect solid freeform fabrication. We explored the effect of pore size on bone regeneration and scaffold mechanical properties using polycaprolactone (PCL) scaffolds designed with interconnected, cylindrical orthogonal pores. Three scaffold designs with unique microarchitectures were fabricated, having pore sizes of 350, 550, or 800 μm. Bone morphogenetic protein-7 transduced human gingival fibroblasts were suspended in fibrin gel, seeded into scaffolds, and implanted subcutaneously in immuno-compromised mice for 4 or 8 weeks. We found that (1) modulus and peak stress of the scaffold/bone constructs depended on pore size and porosity at 4 weeks but not at 8 weeks, (2) bone growth inside pores depended on pore size at 4 weeks but not at 8 weeks, and (3) the length of implantation time had a limited effect on scaffold/bone construct properties. In conclusion, pore sizes between 350 and 800 μm play a limited role in bone regeneration in this tissue engineering model. Therefore, it may be advantageous to explore the effects of other scaffold structural properties, such as pore shape, pore interconnectivity, or scaffold permeability, on bone regeneration when designing PCL scaffolds for bone tissue engineering. © 2009 Wiley Periodicals, Inc. J Biomed Mater Res, 2010read more
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The effect of mean pore size on cell attachment, proliferation and migration in collagen–glycosaminoglycan scaffolds for bone tissue engineering
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Gareth Turnbull,Jon Clarke,Frederic Picard,Frederic Picard,Philip Riches,Luanluan Jia,Fengxuan Han,Bin Li,Wenmiao Shu +8 more
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Chitosan-based scaffolds for bone tissue engineering
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References
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J. M. Williams,Adebisi Adewunmi,Rachel M. Schek,Colleen L. Flanagan,Paul H. Krebsbach,Stephen E. Feinberg,Scott J. Hollister,Suman Das +7 more
TL;DR: The integration of scaffold computational design and free-form fabrication techniques presented here could prove highly useful for the construction of scaffolds that have anatomy specific exterior architecture derived from patient CT or MRI data and an interior porous architecturederived from computational design optimization.
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TL;DR: FDM allows the design and fabrication of highly reproducible bioresorbable 3D scaffolds with a fully interconnected pore network and shows that fibroblasts and osteoblast-like cells can proliferate, differentiate, and produce a cellular tissue in an entirely interconnected 3D polycaprolactone matrix.
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Potential of ceramic materials as permanently implantable skeletal prostheses
TL;DR: High-fired calcium aluminate samples in the form of quarter-inch diameter cylindrical pellets containing interconnecting porous networks were implanted in vivo into canine femurs for 4, 11, and 22-week periods, showing the ceramic samples to be bound lightly by natural bone and gave no detectable signs of tissue incompatibility.