Published online May 26, 2024. doi: 10.4252/wjsc.v16.i5.499
Revised: January 17, 2024
Accepted: April 2, 2024
Published online: May 26, 2024
Processing time: 176 Days and 5.5 Hours
Repairing large bone defects is a major challenge for plastic surgeons, and autologous bone transplantation is currently the best treatment option. However, its application is limited due to scarce resources and complications. Exosomes derived from mesenchymal stem cells (MSCs) have shown great potential in bone regenerative medicine, but they face issues such as rapid degradation, short half-life, and unpredictable side effects. Bone marrow stromal cells play a crucial role in bone formation and tissue repair by migrating from their niche to surrounding tissues and promoting regeneration. The interaction between angiogenic factors and bone marrow-derived MSCs (BMSCs) regulates downstream osteogenesis; for example, vascular endothelial growth factor A can stimulate platelet-derived growth factor receptors to modulate the migration and proliferation of BMSCs.
To find a more effective method for bone defect repair to overcome the limitation of autologous bone grafting. Develop and optimize extracellular vesicle technology to improve its usability and safety in clinical practice. To further investigate the role of BMSCS in bone regeneration and explore their wider application in tissue repair. To reveal the mechanism of interaction between angiogenic factors and BMSCS and provide a theoretical basis for future therapeutic strategies.
Bone healing is an intricate physiological process initiated by early inflammatory immune regulation encompassing multiple events, including angiogenesis, osteogenic differentiation, and biommineralization. In this study, we fabricated a BMSC-derived exosomes (BMSC-exos)-loaded hydrogel that dynamically integrates diverse biological functions and thus operates at distinct stages of the fracture healing process.
The characterization of hydrogels and loaded BMSC-exo gels was verified to validate their properties. In vitro evaluations were conducted to assess the impact of hydrogels on various stages of the healing process. Hydrogels demonstrated the ability to recruit macrophages and inhibition of inflammatory responses, enhance human umbilical vein endothelial cell angiogenesis, and promote osteogenic differentiation of primary cranial osteoblasts. Furthermore, the effect of hydrogel on fracture healing was confirmed using a mouse fracture model.
During the initial stage of repair, the hydrogel loaded with BMSC-exos effectively attenuated the inflammatory response. Furthermore, they significantly enhanced vascular migration and angiogenesis. These effects were further corroborated in a fracture model.
The present study proposes a novel approach for loading BMSC-exos, aiming to optimize patient outcomes by enhancing angiogenesis and bone regeneration capacity in a clinical setting. Simultaneously, continuous development and optimization of extracellular vesicle technology in clinical practice are necessary to improve its usability and safety.
Further in-depth study of its possible mechanism of action and gradually spread to clinical application.