BACKGROUND: Fracture healing is a complex and sequential process. One important step in fracture healing is callus remodeling. As we could previously show, an increase of osteoclast bone resorption as a result of estrogen deficiency impairs the fracture healing process. Therefore, the aim of our study was to analyze whether an increased bone formation, as the counterpart of bone resorption in callus remodeling, would accelerate the fracture healing process. METHODS: Standardized femoral fractures were produced in 10-week-old control, leptin-deficient (ob/ob), and leptin receptor-deficient (db/db) mice using a guillotine-like fracture device. Accordingly, the fractures were intramedullary stabilized. The ob/ob and db/db mice are known to have a twofold increase in bone formation in comparison with normal wildtype mice. At different stages of fracture healing, contact X-ray, histologic, and biomechanical analyses were performed. RESULTS: We observed that a twofold increase in bone formation leads to an accelerated periosteal callus formation followed by callus remodeling. As compared with the control group, chondrocytes area was increased, and the subsequent mineralization appeared earlier. In the late stage of fracture healing, the ob/ob and db/db mice showed a thinner but increased mineralized cortex. Biomechanical testing confirmed the beneficial effects of an increased bone formation on restoration of biomechanical competence. CONCLUSION: These results indicate that bone formation is of major importance in all stages of fracture healing. A twofold increase in bone formation is able to significantly accelerate the fracture healing process of long bones at least in mice. Therefore, an increase in bone formation would be a possible pharmaceutical target to enhance fracture healing.
BACKGROUND:Fracture healing is a complex and sequential process. One important step in fracture healing is callus remodeling. As we could previously show, an increase of osteoclast bone resorption as a result of estrogen deficiency impairs the fracture healing process. Therefore, the aim of our study was to analyze whether an increased bone formation, as the counterpart of bone resorption in callus remodeling, would accelerate the fracture healing process. METHODS: Standardized femoral fractures were produced in 10-week-old control, leptin-deficient (ob/ob), and leptin receptor-deficient (db/db) mice using a guillotine-like fracture device. Accordingly, the fractures were intramedullary stabilized. The ob/ob and db/db mice are known to have a twofold increase in bone formation in comparison with normal wildtype mice. At different stages of fracture healing, contact X-ray, histologic, and biomechanical analyses were performed. RESULTS: We observed that a twofold increase in bone formation leads to an accelerated periosteal callus formation followed by callus remodeling. As compared with the control group, chondrocytes area was increased, and the subsequent mineralization appeared earlier. In the late stage of fracture healing, the ob/ob and db/db mice showed a thinner but increased mineralized cortex. Biomechanical testing confirmed the beneficial effects of an increased bone formation on restoration of biomechanical competence. CONCLUSION: These results indicate that bone formation is of major importance in all stages of fracture healing. A twofold increase in bone formation is able to significantly accelerate the fracture healing process of long bones at least in mice. Therefore, an increase in bone formation would be a possible pharmaceutical target to enhance fracture healing.
Authors: Alexander S Spiro; Shahram Khadem; Anke Jeschke; Robert Percy Marshall; Pia Pogoda; Anita Ignatius; Michael Amling; Frank Timo Beil Journal: J Bone Miner Metab Date: 2013-04-02 Impact factor: 2.626
Authors: Zhengmeng Yang; Lu Feng; Ming Wang; Yucong Li; Shanshan Bai; Xuan Lu; Haixing Wang; Xiaoting Zhang; Yaofeng Wang; Sien Lin; Micky D Tortorella; Gang Li Journal: Nutrients Date: 2022-05-18 Impact factor: 6.706
Authors: F Graef; R Seemann; A Garbe; K Schmidt-Bleek; K D Schaser; J Keller; G Duda; S Tsitsilonis Journal: J Musculoskelet Neuronal Interact Date: 2017-06-01 Impact factor: 2.041