Journal article
Far Cortical Locking Can Improve Healing of Fractures Stabilized with Locking Plates
Journal of bone and joint surgery. American volume, Vol.92A(7), pp.1652-1660
2010
DOI: 10.2106/JBJS.I.01111
PMCID: PMC2897208
PMID: 20595573
Abstract
Background: Locked bridge plating relies on secondary bone healing, which requires interfragmentary motion for callus formation. This study evaluated healing of fractures stabilized with a locked plating construct and a far cortical locking construct, which is a modified locked plating approach that promotes interfragmentary motion. The study tested whether far cortical locking constructs can improve fracture-healing compared with standard locked plating constructs.
Methods: In an established ovine tibial osteotomy model with a 3-mm gap size, twelve osteotomies were randomly stabilized with locked plating or far cortical locking constructs applied medially. The far cortical locking constructs were designed to provide 84% lower stiffness than the locked plating constructs and permitted nearly parallel gap motion. Fracture-healing was monitored on weekly radiographs. After the animals were killed at week 9, healed tibiae were analyzed by computed tomography, mechanical testing in torsion, and histological examination.
Results: Callus on weekly radiographs was greater in the far cortical locking constructs than in the locked plating constructs. At week 9, the far cortical locking group had a 36% greater callus volume (p = 0.03) and a 44% higher bone mineral content (p = 0.013) than the locked plating group. Callus in the locked plating specimens was asymmetric, having 49% less bone mineral content in the medial callus than in the lateral callus (p = 0.003). In far cortical locking specimens, medial and lateral callus had similar bone mineral content (p = 0.91). The far cortical locking specimens healed to be 54% stronger in torsion (p = 0.023) and sustained 156% greater energy to failure in torsion (p < 0.001) than locked plating specimens. Histologically, three of six locked plating specimens had deficient bridging across the medial cortex, while all remaining cortices had bridged.
Conclusions: Inconsistent and asymmetric callus formation with locked plating constructs is likely due to their high stiffness and asymmetric gap closure. By providing flexible fixation and nearly parallel interfragmentary motion, far cortical locking constructs form more callus and heal to be stronger in torsion than locked plating constructs.
Details
- Title: Subtitle
- Far Cortical Locking Can Improve Healing of Fractures Stabilized with Locking Plates
- Creators
- Michael BOTTLANG - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesMaren LESSER - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesJulia KOERBER - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesJosef DOORNINK - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesBrigitte VON RECHENBERG - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesPeter AUGAT - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesDaniel C FITZPATRICK - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesSteven M MADEY - Legacy Biomechanics Laboratory, Portland, Oregon, United StatesJ. Lawrence MARSH - Legacy Biomechanics Laboratory, Portland, Oregon, United States
- Resource Type
- Journal article
- Publication Details
- Journal of bone and joint surgery. American volume, Vol.92A(7), pp.1652-1660
- DOI
- 10.2106/JBJS.I.01111
- PMID
- 20595573
- PMCID
- PMC2897208
- NLM abbreviation
- J Bone Joint Surg Am
- ISSN
- 0021-9355
- eISSN
- 1535-1386
- Publisher
- Journal of Bone and Joint Surgery Incorporated; Boston, MA
- Language
- English
- Date published
- 2010
- Academic Unit
- Orthopedics and Rehabilitation
- Record Identifier
- 9984040595302771
Metrics
17 Record Views