Abstract
Atrophic non-union is attributed to biological failure of the fracture repair process. It occurs in up to 10% of fractures, results in significant morbidity to patients, and treatment often requires complex reconstructive procedures. We tested the ability of human bone derived marrow mesenchymal stem cells (MSC), and human adipose derived pericytes (the native ancestor of the MSC) delivered percutaneously to the fracture gap to prevent the formation of atrophic non-union in a rat model. At eight weeks, 80% of animals in the cell treatment groups showed evidence of bone healing compared to only 14% of those in the control group. Radiographic parameters showed significant improvement over the eight-week period in the cell treatment groups, and histology confirmed bone bridges at the fracture gap in the both treatment groups. The quality of bone produced and its biomechanical properties were significantly enhanced in both treatment groups. The results from this study demonstrate that MSC and pericytes have significant bone regeneration potential in an atrophic non-union model. These cells may have a role in the prevention of atrophic non-union and could enable a paradigm shift in the treatment of fractures at high risk of failing to heal and developing non-union.
Highlights
The majority of fractures heal without any complications, a significant proportion fail to heal resulting in delayed union and subsequent non-union
The aim of this study was to examine the ability of human adipose derived pericytes to heal a fracture destined to progress to an atrophic non-union in a rat tibia model, and to compare this to conventional human bone marrow mesenchymal stem cells (MSC)
At this point 5 were treated with MSC injection, 5 were treated with pericyte injection, and 7 were given PBS
Summary
The majority of fractures heal without any complications, a significant proportion fail to heal resulting in delayed union and subsequent non-union. Tissue that can be retrieved is vast in comparison to bone marrow, and the frequency of stem cells within adipose tissue has been shown to be 500 times greater than that of bone marrow per unit of mass[12] This has allowed a better understanding to be developed of the subpopulations of cells within the stromal vascular fraction (SVF). The aim of this study was to examine the ability of human adipose derived pericytes to heal a fracture destined to progress to an atrophic non-union in a rat tibia model, and to compare this to conventional human bone marrow MSC. Bone marrow MSC were chosen due to their recognized ability to repair and regenerate bone Their ability to treat established non-union has been described[21]
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