Development, Validation and Characterization of a Novel Portable Closed Fracture Device.

Abstract

As one of the common clinical diseases, fractures have many causes, mechanisms, healing and influencing factors; especially fracture healing is a long-term and complex process. Animal fracture models can simulate the various states of human fractures, and on this basis, the prevention, mechanism, and treatment of fractures can be studied to further guide clinical practice. Here, we developed a novel and portable device to create a closed fracture model in mice. We then compared this novel closed fracture model with the traditional open model in multiple dimensions to evaluate the modelling process of establishment and healing. The two models were evaluated by imaging, immunostaining, and behavioral tests, which fully demonstrated the stability, universality and operability of the modified fracture model in mice. Surgical quality assessment revealed that the closed fracture model had a shorter operation time and smaller wound than the open model. X-ray and micro-CT results showed no differences between the two models in the evaluation of radiographic and morphological changes during fracture healing. Histological examination revealed the process of the typical intrachondral osteogenic pathway after fracture. Moreover, animal gait analysis indicated reduced postoperative pain in the closed group compared to the open group. This study provides a constructive strategy for a closed fracture model in mice and demonstrates the effectiveness and feasibility of the closed fracture model in studying the typical intrachondral osteogenic pathway of fractures from multiple dimensions.