AI Article Synopsis
- Rapid vascularization of tissue-engineered osteogenic grafts is crucial for bone repair, and VEGF plays a key role in promoting vascular growth.
- A study using genetically modified human bone marrow-derived stromal/stem cells (BMSC) expressing rat VEGF showed a threefold increase in vascular density in grafts after 8 weeks in a rat model, with well-structured vascular networks.
- However, the excess VEGF led to a decrease in bone quantity and increased osteoclast recruitment, indicating a risk of disrupting bone balance, which complicates its use in clinical applications for bone tissue engineering.
Article Abstract
Rapid vascularisation of tissue-engineered osteogenic grafts is a major obstacle in the development of regenerative medicine approaches for bone repair. Vascular endothelial growth factor (VEGF) is the master regulator of vascular growth. We investigated a cell-based gene therapy approach to generate osteogenic grafts with an increased vascularization potential in an ectopic nude rat model in vivo, by genetically modifying human bone marrow-derived stromal/stem cells (BMSC) to express rat VEGF. BMSC were loaded onto silicate-substituted apatite granules, which are a clinically established osteo-conductive material. Eight weeks after implantation, the vascular density of constructs seeded with VEGF-BMSC was 3-fold greater than with control cells, consisting of physiologically structured vascular networks with both conductance vessels and capillaries. However, VEGF specifically caused a global reduction in bone quantity, which consisted of thin trabeculae of immature matrix. VEGF did not impair BMSC engraftment in vivo, but strongly increased the recruitment of TRAP- and Cathepsin K-positive osteoclasts. These data suggest that VEGF over-expression is effective to improve the vascularization of osteogenic grafts, but also has the potential to disrupt bone homoeostasis towards excessive degradation, posing a challenge to its clinical application in bone tissue engineering.
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| http://dx.doi.org/10.1016/j.biomaterials.2013.03.040 | DOI Listing |
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