RESUMO
Osteogenesis imperfecta (OI) type V is the second most common form of OI, distinguished by hyperplastic callus formation and calcification of the interosseous membranes in addition to bone fragility. It is caused by a recurrent, dominant pathogenic variant (c.-14C>T) in IFITM5. Here, we generated a conditional Rosa26 knock-in mouse model to study the mechanistic consequences of the recurrent mutation. Expression of the mutant Ifitm5 in osteo-chondroprogenitor or chondrogenic cells resulted in low bone mass and growth retardation. Mutant limbs showed impaired endochondral ossification, cartilage overgrowth, and abnormal growth plate architecture. The cartilage phenotype correlates with the pathology reported in OI type V patients. Surprisingly, expression of mutant Ifitm5 in mature osteoblasts caused no obvious skeletal abnormalities. In contrast, earlier expression in osteo-chondroprogenitors was associated with increase in the skeletal progenitor population within the periosteum. Lineage tracing showed that chondrogenic cells expressing the mutant Ifitm5 showed decreased differentiation into osteoblastic cells in diaphyseal bone. Moreover, mutant IFITM5 disrupts early skeletal homeostasis in part by activating ERK signaling and downstream SOX9 protein, and inhibition of these pathways partially rescued the phenotype in mutant animals. These data identify the contribution of a signaling defect altering osteo-chondroprogenitor differentiation as a driver in the pathogenesis of OI type V.
RESUMO
PURPOSE: To compare the biomechanical characteristics of screw versus plate versus both screw and plate fixation for large, type 3 O'Driscoll coronoid fractures. METHODS: Synthetic ulnas had 70% of their coronoids cut. Fixation was performed with either a cannulated screw, a plate, or both a screw and a plate. Energy to failure, force at failure, first cycle stiffness, and stiffness at failure were measured on a servohydraulic testing machine under cyclic posterior axial loading. RESULTS: The combination of a plate and screw had significantly greater energy to failure (83 Nm), force required to cause failure (634 N), and stiffness at failure (387 N/mm) compared to either an isolated plate (38 Nm, 474 N, 237 N/mm, respectively) or a screw (10 Nm, 279 N, 149 N/mm, respectively). For energy to failure and force required to cause failure, the plate group significantly outperformed the screw group. There was no significant difference in stiffness at the time of failure between the plate and screw groups. CONCLUSIONS: For type 3 O'Driscoll coronoid fractures or nonunions when both a screw and a plate can be placed, the combination of these 2 fixation devices appears to produce significantly greater biomechanical stability than either fixation device alone.