The use modular total hip arthroplasty is associated with potentially serious local and systemic complications. Each modular interface introduces a source for wear particle generation. Research suggests the etiology of wear particle generation and subsequent corrosion begins with mechanical fretting and disruption of the protective oxide layer leading to release of metal ions at the taper interface. The purpose of this study was to conduct three dimensional (3D) surface scans of the mating surfaces of the neck-stem taper to identify features that may contribute to the fretting and surface corrosion. Eighteen modular hip implant components (9 stems and 9 necks) received 3D surface scans to examine the neck-stem taper junction. The study analyzed the neck-stem taper in an as assembled condition so relative surface positions and surface features could be studied. The 9 stems and 9 necks were scanned using an optical scanner. The implant image volume was resolved to a point spacing of 0.5 mm. Measurements were made to determine the normal distance between the surfaces of the neck taper as seated in the stem slot. These measurements were used to produce a color map of the contact proximity between the neck and stem surfaces (Figure 1). Circumferential surface points from the neck and stem at corresponding taper axis heights were used to create surface contour plots to identify surface shape variation and contact. The angle measurements and neck seated depth were analyzed by regression.Introduction
Methods
The purpose of this study was to investigate the stability of dual-taper modular hip implants following impaction forces delivered in varying directions as measured by the distraction forces required to disassemble the components. Distraction of the head-neck and neck-stem tapers of dual-taper modular implants with 0°, 8°, and 15° neck angles were measured utilizing a custom-made distraction fixture attached to a servohydraulic materials test machine. Distraction was measured after hand-pressing the components as well as following a simulated firm hammer blow impaction. Impacts to the 0°, 8°, 15° necks were directed axially in-line with the neck, 10° anterior, and 10° proximal to the axis of the neck, respectively.Background
Methods
Modularity in total hip arthroplasty offers many potential benefits, however the consequences of mechanically associated corrosion continue to be concerning. Micromotion and settling of the modular components at the taper interface are thought to contribute to the etiology of this problem. The purpose of this study was to investigate the effect of hammer blows delivered in different directions on the force transmitted to the head-neck and neck-stem interface in modular hip implants. One-hundred and forty-four impact tests were performed in six different directions: one on axis and five 10° off axis. Four different simulations were performed measuring the head-neck only and three different necks: 0°, 8°, and 15°. A constant height delivered on-axis hammer blows at a constant 4,500 Newton (N). Load cells positioned in the hammer and at the neck-stem junction transmitted voltage to an oscilloscope which measured forces.Introduction
Methods
