S. Köbel scite author profile

The probability of in-vivo failure of ceramic hip joint implants is very low (0.05-0.004 per cent). Besides material flaws and overloading, improper handling during implantation may induce fractures of the ceramic ball head in the long term. This study focuses on the influence of contaminants located in the stem-ball interface and on the use of damaged metal tapers on the strength of ceramic ball heads. Mechanical tests on alumina ball heads according to the standard ISO 7206-10 were performed to identify their effect on the static fracture load. A decrease of up to 90 per cent with respect to the reference static fracture load was found when contaminants such as bone chips, soft tissue, or blood were present. Reductions of 57 per cent and 27 per cent were observed for deformed stem cross-sections (from circular to elliptical) and for flattened stems respectively, making deformed stems another influential parameter. Since any alteration of the interface between the metal taper and the ceramic ball head yields a nonuniform load introduction and hence results in stress concentrations, its presence has to be avoided.

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Failure analysis of in vivo fractured ceramic femoral heads

Weisse

Affolter

Terrasi

et al. 2009

Engineering Failure Analysis

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Optimization of the stress distribution in ceramic femoral heads by means of finite element methods

Affolter

Weisse

Stutz

et al. 2008

Proc Inst Mech Eng H

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Ceramic ball heads for total hip replacement are highly loaded in vivo and must meet the sternest requirements concerning strength and safety. High stresses inside the ball head originate from the press fit between the conical stem (made of titanium alloy or steel) and the borehole of the ball. The aim of this study was the development of an optimized contour at the fillet inside the ball head by means of numerical methods, in order to reduce local stress concentrations. The computer-aided optimization method was applied on the customary engineering fillet radius to reduce local stress peaks. The local notch stress of the examined ball head design was reduced by up to 27 per cent for the relevant load cases. Verification by rupture testing of prototypes turned out to be difficult for axisymmetric load cases, since the static fracture load is governed by the hoop stresses in the contact area of the taper (global maximum), thus making it difficult to prove a local improvement. The sensitivity of the design to asymmetric loading was clearly shown (varying the load angle and bearing type). Stress relocation in the ball-stem interface at higher burst loads indicated the necessity of optimizing each ceramic femoral head design individually (i.e. for different borehole depths).

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Sphericity related contact mechanics in ceramic-on-ceramic hip joint replacements

Leyen¹,

Köbel²,

Weber³

2006

Journal of Biomechanics

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S. Köbel

Complications with Computer‐Aided Designed/Computer‐Assisted Manufactured Titanium and Soldered Gold Bars for Mandibular Implant‐Overdentures: Short‐Term Observations

Influence of contaminants in the stem—ball interface on the static fracture load of ceramic hip joint ball heads

Failure analysis of in vivo fractured ceramic femoral heads

Optimization of the stress distribution in ceramic femoral heads by means of finite element methods

Sphericity related contact mechanics in ceramic-on-ceramic hip joint replacements

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