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Comparison of a 2.7-mm and 3.5-mm locking compression plate for ulnar fractures: a biomechanical evaluation

Jenna M. Wahbeh, Benjamin V. Kelley, Cyrus Shokoohi, Sang‐Hyun Park, Sai K. Devana, Edward Ebramzadeh, Sophia N. Sangiorgio, Devon M. Jeffcoat

2023OTA International The Open Access Journal of Orthopaedic Trauma13 citationsDOIOpen Access PDF

Abstract

Abstract Objectives: Implant prominence after ulnar fracture fixation may be mitigated by the use of lower profile plates. The biomechanical strength and stability of 2.7-mm and 3.5-mm locking compression plates for fixation were compared. Methods: Two fracture conditions, transverse (N = 10) and oblique (N = 10), were evaluated in an in vitro study. Half of the specimens for each condition were fixed with 2.7-mm plates and the other half with 3.5-mm plates, all fixed with conventional dynamic compression mechanisms. Specimens were loaded under ±2 Nm of cyclic axial torsion, then under 10 Nm of cyclic cantilever bending, and bending to failure. Interfragmentary motion and strain were analyzed to determine construct stability as a function of fracture pattern and plate size. Results: Interfragmentary motion was significantly larger in all constructs fixed with 2.7-mm plates, compared with 3.5-mm plates ( P < 0.01). The 2.7-mm constructs with transverse fractures had the greatest motion, ranging between 5° and 10° under axial rotation and 5.0–6.0 mm under bending. Motions were the lowest for 3.5-mm constructs with oblique fractures, ranging between 3.2 and 4.2 mm under bending and 2°–3.5° for axial rotation. For oblique fractures, the bending moment at ultimate failure was 31.4 ± 3.6 Nm for the 2.7-mm constructs and 10.0 ± 1.9 Nm for 3.5-mm constructs ( P < 0.01). Similarly, for transverse fractures, the bending moment was 17.9 ± 4.0 Nm for the 2.7-mm constructs and 9.7 ± 1.3 Nm for the 3.5-mm constructs ( P < 0.01). Conclusions: Although 3.5-mm plates were more effective at reducing fracture motion, they were consistently associated with refracture at the distal-most screw hole under load to failure. By contrast, 2.7-mm plates plastically deformed despite excessive loads, potentially avoiding a subsequent fracture. Level of Evidence: Level V.

Topics & Concepts

Materials scienceTorsion (gastropod)Compression (physics)Fixation (population genetics)Oblique caseTransverse planeBending momentBendingComposite materialBiomechanicsFracture (geology)OrthodonticsStructural engineeringAnatomyMedicinePhilosophyEngineeringEnvironmental healthPopulationLinguisticsOrthopedic Surgery and RehabilitationBone fractures and treatmentsElbow and Forearm Trauma Treatment
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