C W Bruce1, T W G Gibson, R J Runciman. 1. Dr. Charles W. Bruce, Department of Specialty Surgery, Alta Vista Animal Hospital, Ottawa, Ontario, K1T1M9, Canada, Phone: +1 613 731 6851, Fax: +1 613 731 2315, E-mail: bruce.charles@rocketmail.com.
Abstract
OBJECTIVES: The purpose of this study was to compare the stiffness, yield load, ultimate load at failure, displacement at failure, and mode of failure in cantilever bending of locking compression plates (LCP) and dynamic compression plates (DCP) in an acute failure ilial fracture model. Our hypothesis was that the LCP would be superior to the DCP for all of these biomechanical properties. METHODS: Ten pelves were harvested from healthy dogs euthanatized for reasons unrelated to this study and divided into two groups. A transverse osteotomy was performed and stabilized with either a 6-hole DCP applied in compression or a 6-hole LCP. Pelves were tested in cantilever bending at 20 mm/min to failure and construct stiffness, yield load, ultimate load at failure, displacement at failure, and mode of failure were compared. RESULTS: The mean stiffness of DCP constructs (193 N/mm [95% CI 121 - 264]) and of LCP constructs (224 N/mm [95% CI 152 - 295]) was not significantly different. Mean yield load of DCP constructs (900 N [95% CI 649 -1151]) and of LCP constructs (984 N [95% CI 733 -1235]) was not significantly different. No significant differences were found between the DCP and LCP constructs with respect to mode of failure, displacement at failure, or ultimate load at failure. CLINICAL SIGNIFICANCE: Our study did not demonstrate any differences between DCP and LCP construct performance in acute failure testing in vitro.
OBJECTIVES: The purpose of this study was to compare the stiffness, yield load, ultimate load at failure, displacement at failure, and mode of failure in cantilever bending of locking compression plates (LCP) and dynamic compression plates (DCP) in an acute failure ilial fracture model. Our hypothesis was that the LCP would be superior to the DCP for all of these biomechanical properties. METHODS: Ten pelves were harvested from healthy dogs euthanatized for reasons unrelated to this study and divided into two groups. A transverse osteotomy was performed and stabilized with either a 6-hole DCP applied in compression or a 6-hole LCP. Pelves were tested in cantilever bending at 20 mm/min to failure and construct stiffness, yield load, ultimate load at failure, displacement at failure, and mode of failure were compared. RESULTS: The mean stiffness of DCP constructs (193 N/mm [95% CI 121 - 264]) and of LCP constructs (224 N/mm [95% CI 152 - 295]) was not significantly different. Mean yield load of DCP constructs (900 N [95% CI 649 -1151]) and of LCP constructs (984 N [95% CI 733 -1235]) was not significantly different. No significant differences were found between the DCP and LCP constructs with respect to mode of failure, displacement at failure, or ultimate load at failure. CLINICAL SIGNIFICANCE: Our study did not demonstrate any differences between DCP and LCP construct performance in acute failure testing in vitro.
Authors: Predrag Grubor; Milorad Mitković; Milan Grubor; Milan Mitković; Luigi Meccariello; Gabriele Falzarano Journal: Acta Inform Med Date: 2016-07-16
Authors: Tryssia S M Moi; Bruno W Minto; Ana P Macedo; Dayvid V F Lucena; Caio A S Malta; Luis G G G Dias Journal: PLoS One Date: 2022-08-26 Impact factor: 3.752