Feasibility of Defect Tunable Bone Engineering Using Electroblown Bioactive Fibrous Scaffolds with Dental Stem Cells.

Healing and repair of damaged bones with various geometries are challenging issues in personalized regenerative medicine. Herein, we examine if the engineered electroblown scaffolds can be suitable to this purpose with the ability to shape and fill defects, populate stem cells, and stimulate the regeneration process of defected bone. The electroblowing method could generate bioactive nanocomposite scaffolds made of poly(caprolactone) and bioactive glass nanoparticles, of which the macrostructure is highly spaced and fibrous networked. The scaffolds were easily formable to different shapes with space filling ability, and were hydrophilic to soak water and blood rapidly. Multipotent stem cells from dental pulp effectively infiltrated the scaffold networks, anchored the fiber surface within few hours, proliferated actively over weeks, and were stimulated to differentiate into osteogenic cells. The cell/scaffold constructs, implanted to tooth-extracted, irregular-shaped alveolar bone defects, were shown to fit the defect and to stimulate early new bone formation. Taken together, the electroblown bioactive fibrous scaffolds and their constructs with multipotent dental stem cells may be useful as a potential 3D platform for future personalized bone tissue engineering.