Aging-Induced Discrepant Response of Fracture Healing is Initiated from the Organization and Mineralization of Collagen Fibrils in Callus.

Fracture healing is a complex process during which the bone restores its structural and mechanical integrity. Collagen networks and minerals are the fundamental components to rebuild the bone matrix in callus. It has been recognized that bone quality could be impaired during aging. However, how the structural and mechanical recovery of fracture healing is influenced by aging, particularly from the perspective of organization and mineralization of the collagen network in callus, remains unclear. A tibial fracture model was established for both the young (5 weeks) and aged mice (68 weeks). On the 21st day postfracture, the characteristics of the collagen network, mineralization, and the nanoscale mechanical properties of the callus were assessed. The results indicated that aging postpones the fracture healing process, leading to incomplete microstructure, less mineral content and mineralization, and weaker mechanical properties of callus. In the aged mice, the internal fixation and mechanical immobilization promoted the mineralization of callus by increasing mineral crystal length and mineral-to-matrix ratio by 48 and 42% compared to the internal fixation and free movement control group, respectively. By contrast, in the young mice, the internal fixation and mechanical immobilization induced disordered collagen fibrils and decreased the crystal length and mineral-to-matrix ratio by 32 and 36%, compared to the internal fixation and free movement control group, respectively. The present findings suggested that the aging-induced structure and mechanical differences of callus during fracture healing initiate from the organization and mineralization of collagen fibrils. Multiscale structural and mechanical analysis suggested mechanical immobilization is beneficial to the structure, composition, and mechanics of callus in the aged mice while impairing the organization and mineralization of collagen fibril in the callus of the young mice. These findings suggested that different mechanical intervention strategies should be adopted for fracture healing at different ages, which provides valuable insights for the clinical treatment of bone fracture.