Whole-bone toughness is linked to canal and osteocyte lacunae deficits in the ZDSD type 2 diabetic rat model

Abstract

Type 2 diabetes mellitus (T2DM) is associated with an increased fracture risk independent of bone mass. The exact origin of this increased fracture risk is still not well understood. Using a polygenic diabetic rat model, synchrotron radiation micro-computed tomography (SRμCT), and in situ scanning electron microscope (SEM) fracture toughness, we related the changes at the microscale to toughness and material properties of diabetic rat femurs. The diabetic rat model (ZDSD) displayed overnight fasting hyperglycemia and an increased AGEs content. Additionally, we measured the impairment of post-yield properties and toughness in diabetic rats. The cortical geometry and porosity were also affected in this ZDSD model. We measured a decrease in osteocyte lacunar density associated with a decreased lacunar volume. Moreover, we found decreased canal density while maintaining a similar canal diameter. These results indicate that diabetes impairs bone remodeling, affecting bone microstructure. Because canals and lacunae are also linked with extrinsic toughening mechanisms, we attribute the decreased toughness largely to these microstructural changes. In conclusion, we showed that changes in lacunae and canal density, combined with AGEs accumulation, decreased toughness in T2DM rat bone.