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Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_6 | Pages 106 - 106
1 Mar 2017
Yanoso-Scholl L Pierre D Lee R Ambrosi M Swaminathan V Faizan A TenHuisen K
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Introduction

In hip arthroplasty, it has been shown that assembly of the femoral head onto the stem remains a non-standardized practice and differs between surgeons [1]. Pennock et al. determined by altering mechanical conditions during seating there was a direct effect on the taper strength [2]. Furthermore, Mali et al. demonstrated that components assembled with a lower assembly load had increased fretting currents and micromotion at the taper junction during cyclic testing [3]. This suggests overall performance may be affected by head assembly method. The purpose of this test was to perform controlled bench top studies to determine the influence of impaction force and compliance of support structure (or damping) on the initial stability of the taper junction.

Materials and Methods


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_5 | Pages 85 - 85
1 Mar 2017
Pierre D Gilbert J Swaminathan V Yanoso-Scholl L TenHuisen K Lee R
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Statement of Purpose

Mechanically assisted crevice corrosion of modular tapers continues to be a concern in total joint replacements as studies have reported increases in local tissue reactions1. Two surgical factors that may effect taper seating mechanics are seating load magnitude and orientation.

In this study 12/14 modular taper junctions were seated over a range of loads and loading orientations. The goals of this study were to assess the effects of load magnitude and orientation on seating load-displacement mechanics and to correlate these to the pull-off load.

Methods

Ti6Al4V 12/14 tapers and CoCrMo heads were tested axially at four seating load levels (n=5): 1-, 2-, 4- and 8- kN. Three orientation groups were tested at 4 kN (n=5), 0°, 10° and 20°. The load-displacement behavior during testing was captured using data acquisition methods and two non-contact eddy current sensors fixed to the neck, targeting head-neck relative motion (Micro-Epsilon).

Loads were ramped (200 N/s) with a servohydraulic system from 0 N to peak load and held for 5s (Instron). Off-axis test samples were oriented in an angled fixture. Displacement and load data were recorded in LabView. Seating displacement was the distance traveled between 50 N and thepeak load.

Axial tensile pull-off loads (5 mm/min) were applied until the locking ability of taper junctions failed.

Statistical analysis was performed using ANOVA test (P<0.05).