Edouard Dessyn1,2, Akash Sharma1,2, Mathias Donnez1,2, Patrick Chabrand1,2, Matthieu Ehlinger3, Jean-Noël Argenson1,2, Sebastien Parratte1,2, Matthieu Ollivier4,5. 1. Department of Orthopedics and Traumatology, Institute of movement and locomotion, St Marguerite Hospital, 270 Boulevard Sainte Marguerite, BP 29, 13274, Marseille, France. 2. Department of Orthopedics and Traumatology, Institute for Locomotion, Aix Marseille Univ, APHM, CNRS, ISM, Sainte-Marguerite Hospital, Marseille, France. 3. Service de Chirurgie Orthopédique et de Traumatologie, CHU Hautepierre, Hôpital de Hautepierre, Hôpitaux Universitaires de Strasbourg, 1 Avenue Molière, 67098, Strasbourg Cedex, France. 4. Department of Orthopedics and Traumatology, Institute of movement and locomotion, St Marguerite Hospital, 270 Boulevard Sainte Marguerite, BP 29, 13274, Marseille, France. matthieu.ollivier@ap-hm.fr. 5. Department of Orthopedics and Traumatology, Institute for Locomotion, Aix Marseille Univ, APHM, CNRS, ISM, Sainte-Marguerite Hospital, Marseille, France. matthieu.ollivier@ap-hm.fr.
Abstract
PURPOSE: It was hypothesized in this in-vitro study that positioning a K-wire intersecting the cutting plane at the theoretical lateral hinge location would limit the cut depth and help preserve the lateral hinge during the opening of the osteotomy. Objectives were (1) to compare the mechanical resistance of the hinge and the protective effect of leaving the K-wire during the opening procedure (2) to check if the K-wire would limit the depth of the osteotomy. METHODS: An ex-vivo mechanical study, testing 5 pairs of fresh-frozen tibias, was designed. CT-scan based Patient-specific cutting guides were obtained to define the cutting plane and the location of the K-wire at the hinge, using standardized 3D planning protocol. In each pair, OWHTO was performed either with or without the K-wire. To evaluate the hinge's resistance to fracture, the specimens were rigidly fixed at the proximal tibia and a direct load was applied on the free tibial diaphysis to open the osteotomy. The maximum load at breakage, maximum permissible displacement and maximal angulation of the osteotomy before hinge failure was measured. To assess the preservation of an unscathed hinge (protected by the K-wire), the distance from the end of the osteotomy cut to the lateral tibial cortical was measured in mm. RESULTS: The maximum load to hinge breakage in the K-wires PsCG knees compared to the control group (48.3 N vs 5.5 N, p = 0.004), the maximum permissible displacement (19.8 mm vs 7.5 mm, p = 0.005) and the maximal angulation of the osteotomy before hinge breakage (9.9° vs 2.9°, p = 0.002) were all statistically superior in the K-wires PsCG knees compared to the control group. A mean distance of 10 ± 1 mm between cut-bone (saw-print) and lateral hinge cortical bone was found post-performing the osteotomy and the hinge failing. CONCLUSION: The maximum load to breakage and the maximum permissible displacement were, respectively, 880% and 260% higher during the opening of the OWHTO in using K-wires compared to the non-K-wire control group. This confirms the mechanical advantage of using a K-wire for both stabilization and protecting the Hinge during OWHTO. This comparative cadaveric study shows an improvement of the lateral hinges resistance to failing during the opening of the osteotomy. This can be achieved by the placement of a K-wire intersecting the cutting plane at the theoretical location of the lateral hinge.
PURPOSE: It was hypothesized in this in-vitro study that positioning a K-wire intersecting the cutting plane at the theoretical lateral hinge location would limit the cut depth and help preserve the lateral hinge during the opening of the osteotomy. Objectives were (1) to compare the mechanical resistance of the hinge and the protective effect of leaving the K-wire during the opening procedure (2) to check if the K-wire would limit the depth of the osteotomy. METHODS: An ex-vivo mechanical study, testing 5 pairs of fresh-frozen tibias, was designed. CT-scan based Patient-specific cutting guides were obtained to define the cutting plane and the location of the K-wire at the hinge, using standardized 3D planning protocol. In each pair, OWHTO was performed either with or without the K-wire. To evaluate the hinge's resistance to fracture, the specimens were rigidly fixed at the proximal tibia and a direct load was applied on the free tibial diaphysis to open the osteotomy. The maximum load at breakage, maximum permissible displacement and maximal angulation of the osteotomy before hinge failure was measured. To assess the preservation of an unscathed hinge (protected by the K-wire), the distance from the end of the osteotomy cut to the lateral tibial cortical was measured in mm. RESULTS: The maximum load to hinge breakage in the K-wires PsCG knees compared to the control group (48.3 N vs 5.5 N, p = 0.004), the maximum permissible displacement (19.8 mm vs 7.5 mm, p = 0.005) and the maximal angulation of the osteotomy before hinge breakage (9.9° vs 2.9°, p = 0.002) were all statistically superior in the K-wires PsCG knees compared to the control group. A mean distance of 10 ± 1 mm between cut-bone (saw-print) and lateral hinge cortical bone was found post-performing the osteotomy and the hinge failing. CONCLUSION: The maximum load to breakage and the maximum permissible displacement were, respectively, 880% and 260% higher during the opening of the OWHTO in using K-wires compared to the non-K-wire control group. This confirms the mechanical advantage of using a K-wire for both stabilization and protecting the Hinge during OWHTO. This comparative cadaveric study shows an improvement of the lateral hinges resistance to failing during the opening of the osteotomy. This can be achieved by the placement of a K-wire intersecting the cutting plane at the theoretical location of the lateral hinge.
Entities:
Keywords:
High tibial valgus osteotomy; Hinge; Maximum load, cadaveric study; Patient-specific cutting guides
Authors: Dae Kyung Bae; Young Wan Ko; Sang Jun Kim; Jong Hun Baek; Sang Jun Song Journal: Knee Surg Sports Traumatol Arthrosc Date: 2016-02-11 Impact factor: 4.342
Authors: M Munier; M Donnez; M Ollivier; X Flecher; P Chabrand; J-N Argenson; S Parratte Journal: Orthop Traumatol Surg Res Date: 2017-01-27 Impact factor: 2.256
Authors: Kyung Wook Nha; Myung Jin Shin; Dong Won Suh; Young Jun Nam; Ki Seong Kim; Bong Soo Kyung Journal: Knee Surg Sports Traumatol Arthrosc Date: 2019-05-08 Impact factor: 4.342