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Correction of large jawbone defect in the mouse using immature osteoblast-like cells and a 3D polylactic acid scaffold.

Shigeto SuzukiVenkata Suresh VenkataiahYoshio YahataAkira KitagawaMasahiko InagakiMary M NjugunaRisako NozawaYusuke KakiuchiMasato NakanoKeisuke HandaMasahiro YamadaHiroshi EgusaMasahiro Saito
Published in: PNAS nexus (2022)
Bone tissue engineering has been developed using a combination of mesenchymal stem cells (MSCs) and calcium phosphate-based scaffolds. However, these complexes cannot regenerate large jawbone defects. To overcome this limitation of MSCs and ceramic scaffolds, a novel bone regeneration technology must be developed using cells possessing high bone forming ability and a scaffold that provides space for vertical bone augmentation. To approach this problem in our study, we developed alveolar bone-derived immature osteoblast-like cells (HAOBs), which have the bone regenerative capacity to correct a large bone defect when used as a grafting material in combination with polylactic acid fibers that organize the 3D structure and increase the strength of the scaffold material (3DPL). HAOB-3DPL constructs could not regenerate bone via xenogeneic transplantation in a micromini pig alveolar bone defect model. However, the autogenic transplantation of mouse calvaria-derived immature osteoblast-like cells (MCOBs) isolated using the identical protocol for HAOBs and mixed with 3DPL scaffolds successfully regenerated the bone in a large jawbone defect mouse model, compared to the 3DPL scaffold alone. Nanoindentation analysis indicated that the regenerated bone had a similar micromechanical strength to native bone. In addition, this MCOB-3DPL regenerated bone possesses osseointegration ability wherein a direct structural connection is established with the titanium implant surface. Hence, a complex formed between a 3DPL scaffold and immature osteoblast-like cells such as MCOBs represents a novel bone tissue engineering approach that enables the formation of vertical bone with the micromechanical properties required to treat large bone defects.
Keyphrases
  • bone regeneration
  • tissue engineering
  • bone mineral density
  • soft tissue
  • mesenchymal stem cells
  • bone loss
  • postmenopausal women
  • randomized controlled trial
  • stem cells
  • body composition
  • bone marrow