Abstract
Summary Statement
Prolonged presence of VEGF (released from gelatin microspheres) led to a significant increase in scaffold vascularization when applied in vivo. Bioprinted scaffolds with regional VEGF presence retained their architecture and regional vessel formation occurred.
Introduction
Tissue-engineered bone constructs need timely vascularization for optimal performance in regeneration. A potent stimulus of vascularization is vascular endothelial growth factor (VEGF), a factor with a short half-life time. Controlled release of VEGF from gelatin microparticles (GMPs) was investigated as a means to prolong VEGF presence at the preferred location within bioprinted scaffolds, and study subsequent vascularization.
Methods
Release of VEGF from GMPs was measured with ELISA and bioactivity was assessed using human endothelial progenitor cells (EPC) in Transwell and real-time migration assays. Matrigel scaffolds containing EPCs and VEGF, which was released either in a fast or sustained fashion by application of GMPs, were investigated for their in vivo vasculogenic capacity. In addition, regional differences with respect to VEGF release were introduced in 3D-printed EPC-laden scaffolds. Scaffolds were implanted in subcutaneous pockets in mice for 1 week and analyzed for vessel formation.
Results
Release of VEGF from GMPs was continuous for 3 weeks. VEGF bioactivity was confirmed, EPC migration in the presence of GMP-released VEGF was indistinguishable from VEGF added to the medium. Implantation in subcutaneous pockets in mice demonstrated that vessel formation was significantly higher in the VEGF sustained release group when compared to fast release or control groups. In addition, the different regions in the bioprinted scaffolds were retained and vessel formation occurred analogous with the results seen in the Matrigel plugs.
Discussion/Conclusion
We conclude that GMPs are suitable to generate sustained release profiles of bioactive VEGF, and that they can be used to generate defined differentiation regions in 3D printed heterogeneous constructs. The prolonged presence of VEGF led to a significant increase in scaffold vascularization when applied in vivo.
