Journal
MATERIALS SCIENCE & ENGINEERING C-MATERIALS FOR BIOLOGICAL APPLICATIONS
Volume 68, Issue -, Pages 153-162Publisher
ELSEVIER SCIENCE BV
DOI: 10.1016/j.msec.2016.05.106
Keywords
Calcium phosphate cement; Vascularization; Gelatin fiber; Tissue engineering; HIF1 alpha
Categories
Funding
- National Natural Science Foundation of China [51302089, 81371931, 81301240, 31571030]
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Despite calcium phosphate cement (CPC) is promising for bone repair therapy, slow biodegradation and insufficient vascularization in constructs negatively impacts its clinical application. A self-setting CPC composited with gelatin fiber is investigated to test the utility of this tissue engineering strategy to support rapid and extensive vascularization process. The interconnected hollow channels in CPC are formed after dissolution of gelatin fibers in vivo. The CPC-gelatin samples exhibit relatively decent/enhanced mechanical property, compared to the control. When implanted in vivo, the pre-established vascular networks in material anastomose with host vessels and accelerate vascular infiltration throughout the whole tissue construct. Different channel sizes induce different vascularization behaviors in vivo. Results indicate that the channel with the size of 250 pm increases the expression of the representative angiogenic factors HIF1 alpha, PLGF and migration factor CXCR4, which benefit the formation of small vessels. On the other hand, the channel with the size of 500 pm enhances VEGF-A expression, which benefit the development of large vessels. Notably, the intersection area of channels has high invasive, sprouting and vasculogenesis potential under hypoxic condition, because more HIF1 alpha-positive cells are observed there. Observation of the CD31-positive lumen in the border of scaffold indicates the ingrowth of blood vessels from its host into material through channel, benefited from gradually increased HIF1 alpha expression. This kind of material was suggested to promote the effective application of bone regeneration through the combination of in situ self-setting, plasticity, angiogenesis, and osteoconductivity. (C) 2016 Elsevier B.V. All rights reserved.
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