Title of article
Mechanical and structural properties of bone in non-critical and critical healing in rat
Author/Authors
Hoerth، نويسنده , , Rebecca M. and Seidt، نويسنده , , Britta M. and Shah، نويسنده , , Miheer and Schwarz، نويسنده , , Carolin and Willie، نويسنده , , Bettina M. and Duda، نويسنده , , Georg N. and Fratzl، نويسنده , , Peter and Wagermaier، نويسنده , , Wolfgang، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2014
Pages
11
From page
4009
To page
4019
Abstract
A fracture in bone results in a dramatic change of mechanical loading conditions at the site of injury. Usually, bone injuries heal normally but with increasing fracture gaps, healing is retarded, eventually leading to non-unions. The clinical situation of these two processes with different outcomes is well described. However, the exact relation between the mechanical environment and characteristics of the tissues at all levels of structural hierarchy remains unclear. Here we studied the differences in material formation of non-critical (1 mm) and critical (5 mm gap) healing. We employed a rat osteotomy model to explore bone material structure depending upon the different mechanical conditions. In both cases, primary bone formation was followed by secondary bone deposition with mineral particle sizes changing from on average short and thick to long and thin particles. Bony bridging occurred at first in the endosteal callus and the nanostructure and microstructure developed towards cortical ordered material organization. In contrast, in critical healing, instead of bridging, a marrow cavity closure was formed endosteal, exhibiting tissue structure oriented along the curvature and a periosteal callus with less mature material structure. The two healing processes separated between 4 and 6 weeks post-osteotomy. The outcome of healing was determined by the varied geometrical conditions in critical and non-critical healing, inducing completely different mechanical situations.
Keywords
Bone healing , Critical size defect , mechanical properties , Nanostructure , X-Ray scattering
Journal title
Acta Biomaterialia
Serial Year
2014
Journal title
Acta Biomaterialia
Record number
1758372
Link To Document