OBJECTIVE: To evaluate the role of lateral tibial cortex integrity in open wedge tibial osteotomy (OWTO). METHODS: Experimental models of polyurethane fibers, simulating tibial models and modified with open wedge osteotomies were fixed with DCP® straight 4.5 mm plates. Four groups were constituted: two with cortical integrity and two with a gap in the lateral tibial cortex. Biomechanical analysis of torsion and axial compression were performed. RESULTS: The measures of twist recorded in the group with cortical integrity were higher than those obtained in the group with noncontinuous cortices (p <0.001). The groups with cortical gap on the lateral side that were fixed with screws had a biomechanical behavior comparable to the group with cortical integrity. Measures of compression obtained in the group with full cortical integrity were greater than those of other groups (p <0.001). In torsion and compression, no statistical difference between lag and position screws on the lateral cortical was demonstrated (p>0.05). CONCLUSION: Integrity of lateral tibial cortex adds stability to open wedge tibial osteotomies. Models with lateral cortical integrity demonstrated superiority in biomechanical stiffness even under torsion or compression. In torsion tests, models with a gap on the lateral cortex, fixed with a lag or position screw to promote lateral stabilization had similar biomechanical behavior to those with lateral cortex integrity.
Osteotomy; Tibial fractures; Biomechanics
