Abstract
Gene-activated scaffolds have shown potential in localised gene delivery resulting in bone tissue regeneration. In this study, the ability of two gene delivery vectors, polyethyleneimine (PEI) and nano-hydroxyapatite (nHA), to act as carriers for the delivery of therapeutic genes when combined with our collagen-nHA (coll-nHA) scaffolds to produce gene-activated scaffolds [1, 2], was determined. In addition, coll-nHA-dual gene scaffolds containing both an angiogenic gene and an osteogenic gene were assessed for bone healing in an in vivo Wistar rat calvarial defect model. When cells were applied to the coll-nHA scaffolds under osteogenic conditions in vitro, the dual scaffolds exhibited significantly superior osteogenic potential when analysed using microCT, calcium quantification and histology compared to single-gene scaffolds and gene-free controls. When the dual scaffolds were assessed in vivo, the nHA dual scaffold outperformed all other groups as early as 4 weeks post-implantation as determined using X-ray, microCT, quantification of new bone volume, histology and vessel formation. This research has demonstrated the potential of using novel coll-nHA scaffolds for therapeutic gene therapy while also being capable of simultaneously delivering numerous genes. This study underlines the effect of specifically tailoring gene-activated scaffolds for bone regeneration applications.