This retrieval study documents taper damage at modular interfaces in retrieved MOM THA systems and investigates if increased modularity is associated with increased fretting and corrosion. One hundred thirty-four (134) heads and 60 stems (41 modular necks) of 8 different bearing designs (5 manufacturers) were analyzed. Damage at the shell–liner interface of 18 modular CoCr acetabular liners and the corresponding 11 acetabular shells was also evaluated. The results of this study support the hypothesis that fretting and corrosion damage occurs at a variety of modular component interfaces in contemporary MOM THAs. We also found that modularity of the femoral stem was associated with increased damage at the head. An analysis of component and patient variables revealed that dissimilar alloy pairing, larger head sizes, increased medio-lateral offsets and longer neck moment arms were all associated with increased taper damage at the modular interfaces.
Our research group developed an implant retrieval program to study in vivo degradation of polyethylene. We now have evidence to support our hypothesis that degradation of radiation-sterilized polyethylene occurs in the body for not only historical gamma air sterilized liners, but also for conventional gamma inert sterilized (ArCom) and annealed highly crosslinked polyethylene (Crossfire) liners as well. Our research has also led to the discovery that the most severe manifestations of in vivo oxidation typically occur in regions of the liner experiencing minimal wear, such as the rim of the component, where the body fluids (containing oxidizing species) have access to the polyethylene. Our data from historical, ArCom, and Crossfire retrievals all point to a similar scenario in which the femoral head limits the in vivo oxidation of polyethylene at the bearing surface. Consequently, provided rim impingement does not occur, and the polyethylene locking mechanisms remain relatively isolated from oxidizing fluid, in vivo oxidation does not seem to be clinically important in the first 10 years of implantation for conventional gamma sterilized polyethylene. We conclude that in vivo degradation should be included among the list of potential long-term failure modes for modular polyethylene components for total hip arthroplasty.
We report a prospective study of the liner-metal interfaces of modular uncemented acetabular components as sources of debris. We collected the pseudomembrane from the screw-cup junction and the empty screw holes of the metal backing of 19 acetabula after an average implantation of 22 months. Associated osteolytic lesions were separately collected in two cases. The back surfaces of the liners and the screws were examined for damage, and some liners were scanned by electron microscopy. The tissues were studied histologically and by atomic absorption spectrophotometry to measure titanium content. The pseudomembrane from the screw-cup junction contained polyethylene debris in seven specimens and metal debris in ten. The material from empty screw holes was necrotic tissue or dense fibroconnective tissue with a proliferative histiocytic infiltrate and foreign-body giant-cell reaction. It contained polyethylene debris in 14 cases and metal in five. The two acetabular osteolytic lesions also showed a foreign-body giant-cell reaction to particulate debris. The average titanium levels in pseudomembranes from the screw-cup junction and the empty screw holes were 959 micrograms/g (48 to 11,900) and 74 micrograms/g (0.72 to 331) respectively. The tissue from the two lytic lesions showed average titanium levels of 139 and 147 micrograms/g respectively. The back surfaces of the PE liners showed surface deformation, burnishing, and embedded metal debris. All 30 retrieved screws demonstrated fretting at the base of the head and on the proximal shaft. Non-articular modular junctions create new interfaces for the generation of particulate debris, which may cause granulomatous reaction.
Microscopic tissue damage (microdamage) is an aspect of bone quality associated
with impaired bone mechanical performance. While it is clear that bone tissue submitted to
more severe loading has greater amounts of microdamage (as measured through staining), how
microdamage influences future mechanical performance of bone has not been
well studied, yet is necessary for understanding the mechanical consequences of the
presence of microdamage. Here we determine how stained microdamage generated by a single
compressive overload affects subsequent biomechanical performance of cancellous bone.
Human vertebral cancellous bone specimens (n = 47) from 23 donors (14 male, 9
female, 64–92 years of age) were submitted to a compressive overload, stained for
microdamage, then reloaded in compression to determine the relationship between the amount
of microdamage caused by the initial load and reductions in mechanical performance during
the reload. Damage volume fraction (DV/BV) caused by the initial overload was related to
reductions in Young’s modulus, yield strength, ultimate strength, and yield strain
upon reloading (p < 0.05, R2 = 0.18–0.34). The regression
models suggest that, on average, relatively small amounts of microdamage are associated
with large reductions in reload mechanical properties: a 1.50% DV/BV caused by a
compressive overload was associated with an average reduction in Young’s modulus
of 41.0 ± 3.2 % (mean ± SE), an average reduction in yield
strength of 63.1 ± 4.5% and an average reduction in ultimate strength of
52.7 ± 4.0%. Specimens loaded beyond 1.2%
(1.2–4.0% apparent strain) demonstrated a single relationship between
reload mechanical properties (Young’s modulus, yield strength, and ultimate
strength) and bone volume fraction despite a large range in amounts of microdamage. Hence,
estimates of future mechanical performance of cancellous bone can be achieved using the
bone volume fraction and whether or not a specimen was previously loaded beyond ultimate
strain. The empirical relationships provided in this study make it possible to estimate
the degree of impaired mechanical performance resulting from an observed amount of stained
microdamage.
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