Surfaces In Total Hip Arthroplasty Research Articles

Zirconia Phase Transformation, Metal Transfer, and Surface Roughness in Retrieved Ceramic Composite Femoral Heads in Total Hip Arthroplasty

Ceramic femoral heads have had promising results as a bearing surface in total hip arthroplasty. Our objective was to evaluate a series of retrieved alumina-zirconia composite ceramic femoral heads for evidence of the tetragonal to monoclinic zirconia phase transformation, metal transfer and articular surface roughness. Raman spectra showed evidence of the zirconia phase transformation in all retrieved specimens, with distinct monoclinic peaks at 183, 335, 383, and 479cm−1. All components displayed metal transfer. An increase in the zirconia phase transformation was seen with increasing time in vivo. No correlation between extent of zirconia phase transformation and the surface roughness was found. These short-term results suggest that the use of an alumina-zirconia composite ceramic is a viable option for femoral heads in THA.

The case for ceramic-on-polyethylene as the preferred bearing for a young adult hip replacement.

The optimum choice of bearing surfaces in total hip arthroplasty, particularly in the younger and more active patient, remains controversial. Despite several studies demonstrating good long-term results for the metal-on-polyethylene articulation, there has been a recent vogue towards the utilisation of hard-on-hard bearings for younger patients due, in part, to concerns regarding polyethylene induced osteolysis. However, well-documented complications concerning metal-on-metal bearings and the risk of fracture in ceramic-on-ceramic bearings have raised concerns regarding the principle of the hard-on-hard bearing in the active patient. With recent technological advancements in the manufacture of both polyethylene and alumina ceramics, the in vitro properties of each material with regards to strength and toughness have been significantly improved. In addition, ceramic femoral heads have consistently been shown to produce less in vivo polyethylene wear than similar sized metal heads. This paper aims to critically review the biomechanical, in vivo and clinical studies related to the use of the ceramic on polyethylene bearing, and highlights its potential use as the preferred bearing for a young adult hip replacement.

Ceramic-on-ceramic total hip arthroplasty: A new standard—Opposes

This article reviews the performance characteristics of ceramic-on-ceramic as a bearing surface in total hip arthroplasty. Ceramic has superior wear properties but has yet to demonstrate decreased rate of revision compared to other bearings. There are no data to support ceramic-on-ceramic as a more cost-effective bearing surface. Conversely, it may be more costly to revise, and fracture of the latest generation ceramic heads may cause taper damage that necessitates stem removal in addition. A well-positioned ceramic-on-ceramic total hip is likely to perform well, but there is no evidence to support its use as a new standard for total hip arthroplasty.

Study of the polycarbonate-urethane/metal contact in different positions during gait cycle.

Nowadays, a growing number of young and more active patients receive hip replacement. More strenuous activities in such patients involve higher friction and wear rates, with friction on the bearing surface being crucial to ensure arthroplasty survival in the long term. Over the last years, the polycarbonate-urethane has offered a feasible alternative to conventional bearings. A finite element model of a healthy hip joint was developed and adjusted to three gait phases (heel strike, mid-stance, and toe-off), serving as a benchmark for the assessment of the results of joint replacement model. Three equivalent models were made with the polycarbonate-urethane Tribofit system implanted, one for each of the three gait phases, after reproducing a virtual surgery over the respective healthy models. Standard body-weight loads were considered: 230% body-weight toe-off, 275% body-weight mid-stance, and 350% body-weight heel strike. Contact pressures were obtained for the different models. When comparing the results corresponding to the healthy model to polycarbonate-urethane joint, contact areas are similar and so contact pressures are within a narrower value range. In conclusion, polycarbonate-urethane characteristics are similar to those of the joint cartilage. So, it is a favorable alternative to traditional bearing surfaces in total hip arthroplasty, especially in young patients.

Future Bearing Surfaces in Total Hip Arthroplasty

One of the most important issues in the modern total hip arthroplasty (THA) is the bearing surface. Extensive research on bearing surfaces is being conducted to seek an ideal bearing surface for THA. The ideal bearing surface for THA should have superior wear characteristics and should be durable, bio-inert, cost-effective, and easy to implant. However, bearing surfaces that are currently being implemented do not completely fulfill these requirements, especially for young individuals for whom implant longevity is paramount. Even though various new bearing surfaces have been investigated, research is still ongoing, and only short-term results have been reported from clinical trials. Future bearing surfaces can be developed in the following ways: (1) change in design, (2) further improvement of polyethylene, (3) surface modification of the metal, (4) improvement in the ceramic, and (5) use of alternative, new materials. One way to reduce wear and impingement in THA is to make changes in its design by using a large femoral head, a monobloc metal shell with preassembled ceramic liner, dual mobility cups, a combination of different bearing surfaces, etc. Polyethylene has improved over time with the development of highly crosslinked polyethylene. Further improvements can be made by reinforcing it with vitamin E or multiwalled carbon nanotubes and by performing a surface modification with a biomembrane. Surface modifications with titanium nitride or titanium niobium nitride are implemented to try to improve the metal bearings. The advance to the fourth generation ceramics has shown relatively promising results, even in young patients. Nevertheless, further improvement is required to reduce fragility and squeaking. Alternative materials like diamond coatings on surfaces, carbon based composite materials, oxidized zirconium, silicon nitride, and sapphire are being sought. However, long-term studies are necessary to confirm the efficacy of these surfaces after enhancements have been made with regard to fixation technique and implant quality.

The Effect Of Different Bearing Surfaces On Metal Ion Levels In Urine Following 28 Mm Metal-On-Metal And 28 Mm Metal-On-Polyethylene Total Hip Arthroplasty

Recent advancements in manufacturing technology have enabled more precise tolerances and surface finishes using metal-on-metal bearing surfaces in total hip arthroplasty. The aim of this study was to compare the level of metal ions in urine after implantation of a 28-mm metal-on-metal bearing manufactured from high-carbon wrought alloy and a 28-mm metal-on-polyethylene bearing. A total of 92 total hip arthroplasty patients were prospectively randomized into two groups: those receiving metal-on-metal bearings and those receiving metal-on-polyethylene bearings. Chromium, cobalt, and molybdenum ion levels in urine were measured preoperatively and at 1 year and 2 years postoperatively. In the metal-on-polyethylene group, there was a slight increase in mean chromium and cobalt concentrations at 2-year follow-up compared to the preoperative level (p = 0.02 for both chromium and cobalt). In the metal-on-metal group, there was a 15-fold increase in chromium and a 26-fold increase in cobalt at 2-year follow-up compared to the preoperative level (p < 0.001 for both chromium and cobalt). However, the quantity of chromium and cobalt in urine from the metal-on-metal group was not higher at 2-year follow-up than at 1-year follow-up (p = 0.5 and p = 0.6, respectively). The 28-mm metal-on-metal bearings yield chromium and cobalt concentrations in urine that can be higher than those recommended for occupational exposure. However, our results also indicate that a steady state in wear and ion production using metal-on-metal total hip arthroplasty can occur.

Consideration about Bearing Surfaces of Total Hip Arthroplasty

인공고관절 관절면에서 생성되는 마모입자는 초기에 생 물학적 반응에 의해 골용해를 일으키고 결국 인공삽입물의 해리를 일으킨다. 이러한 마모입자를 줄이기 위해 새로운 인공관절면이 개발되었는데 1) 고도교차결합 폴리에틸렌 2) 금속-금속 관절면 3) 세라믹-세라믹 관절면이 널리 사용 되고 있다. 고도 교차결합 폴리에틸렌 제조는 감마선 혹은 electron beam 조사로 교차결합을 강화하여 마모저항성을 높이고, remelting 혹은 annealing을 통하여 산화에 관여하는 free radical을 제거하는 공정으로 이루어진다. Annealing은 remelting 방법에 비해 폴리에틸렌의 최대강도, 연성, 인 성, 피로강도 등의 물성을 덜 손상시키는 장점이 있으나 free radical이 소량 잔존하는 단점이 있다. 이를 보완하기 위해 최근 비타민E를 첨가하여 산화를 방지함으로서 기존 의 폴리에틸렌의 물성을 보존하고 마모율도 줄일 수 있는 비타민E 첨가 폴리에틸렌이 개발 사용되고 있으며 단기 추 시상 우수한 결과를 나타내어 장기 추시를 요한다. 또한 제 기되는 문제점으로 고도 교차결합 폴리에틸렌의 마모입자 는 기존의 폴리에틸렌 마모입자에 비해 크기가 작아 생물 학적 활성도가 높고 골용해를 증가시킬 수 있다는 우려가 있었으나, 전체 마모량이 적으므로 전체적 생물학적 활성 도 및 골용해 발생률이 오히려 감소한다는 긍정적인 결과 가 보고되어 문제가 되지 않을 것으로 생각된다. 사용할 수 있는 인공 골두로는 금속 또는 세라믹 골두를 선택할 수 있 는데 세라믹 골두가 마모면에서 더 우수한 것으로 보고되 어 세라믹-고도교차결합 폴리에틸렌 관절면이 최근 많이 권장되고 있다. 금속-금속 관절면 1세대에서는 금속 마모입자 및 이온에 의해 조기에 심각한 금속 중독 및 골용해가 발생하였고, 삽 입물 해리가 많이 발생하였다. 이러한 문제점 해결을 위해 금속재질, 표면 거칠기, 간극 등을 개량하여 작은 골두의 2 세대 관절면을 개발하였는데 중기 추시 결과 금속이온 농 도, 마모율 감소에 힘입어 결과가 우수한 것으로 나타났다. 그 후 탈구율을 줄일 수 있고 액체막 윤활의 장점을 가진 표면치환술, 큰 골두의 인공고관절 치환술이 사용되었는데 기대했던 것 보다 훨씬 불량한 결과를 나타내었다. 금속이 온 농도가 높아져 금속과민반응, 무균성 림프구성 혈관염 관련 병변(ALVAL), 가성 종양 등의 심각한 후유증이 많이 발생하였다. 이러한 후유증은 금속골두와 대퇴스템 경부 결합부에 부식이 많은 큰골두 인공고관절 치환술에서 더 심하게 발생하여 정기적인 금속이온 농도검사 및 방사선학 Consideration about Bearing Surfaces of Total Hip Arthroplasty

Catastrophic failure due to massive osteolysis of both acetabular and femoral components in a metal-on-metal hip arthroplasty: a demonstrative case report

Metal-on-metal (MOM) bearing surfaces in total hip arthroplasty have been recently shown to have acceptable survivorship properties, and they have certain advantages and disadvantages when compared to conventional metal-on-polyethylene bearing surfaces. Like traditional metal-on-polyethylene bearings, these metal-on-metal implants may also suffer from catastrophic failure. Patients can develop a local reaction to the metal ions produced by the articulation and present with pain or early loosening due to the local inflammatory reaction. The possible effects of MOM wear debris and its corrosion products are still the subject of debate. This case report represents an unusual situation in a 63-year-old woman in which extensive lysis derived in massive femoral osteolysis and hip arthroplasty catastrophic failure.

Novas superfícies em artroplastia total do quadril

A artroplastia total do quadril tem sido indicada cada vez mais em pacientes mais jovens e ativos, alem de haver uma natural e crescente demanda do procedimento em funcao do aumento da expectativa de vida dos pacientes. Os altos custos da cirurgia e as controversias da performance dos implantes fazem deste assunto objeto de constantes pesquisas na busca de novos materiais com melhores resistencias ao desgaste e biocompatibilidade. O presente artigo abrange um estudo de revisao das novas superficies em artroplastia total do quadril.

NEW BEARING SURFACES IN TOTAL HIP REPLACEMENT

Total hip arthroplasty is being increasingly indicated for younger and more active patients, in addition to a naturally growing demand for the procedure because of increasing life expectancy among patients. The high costs of this surgery and the controversies regarding implant performance have made this topic the subject of constant research, seeking new materials with better resistance to wear and better biocompatibility. The present article provides a review of new surfaces in total hip arthroplasty.

Bearing surfaces for total disc arthroplasty: metal-on-metal versus metal-on-polyethylene and other biomaterials

Concerns about the effect of metallic wear debris from metal-on-metal bearing surfaces in total hip arthroplasty have increased. Some spinal arthroplasty devices include metal-on-metal bearing surfaces. To review the literature for clinical reports of complications because of wear debris from metal-on-metal spinal arthroplasty devices. To review the biology of wear debris from metal-on-metal bearing surfaces drawn from the hip arthroplasty literature and place it in the context of global regulatory actions and clinical and laboratory studies. Literature review. To identify clinical reports, the PubMed database from the United States National Library of Medicine was queried using Medical Subject Headings terms and additional keyword terms. In addition, experts from academia and regulatory agencies were questioned regarding their knowledge of reports, including experts who attended the US Food and Drug Administration roundtable in September 2010. Three case reports and one case series including seven total cases were identified in which abnormal inflammatory reactions and soft-tissue masses after metal-on-metal disc replacements were consistent with pseudotumor and metal hypersensitivity. Spinal cases are present as pain and neurologic symptoms. On plain radiography, there is no clear periprosthetic osteolysis or loosening. On magnetic resonance imaging, there is increased magnetic susceptibility artifact because of metallic debris that renders images inadequate. Computed tomography myelography demonstrates a soft-tissue mass, which exhibits epidural extension surgically. Histologically, large areas of necrotic debris and exudates are interspersed with chronic inflammatory cells. Lymphocyte or macrophage predominance is determined by the rate of wear and the presence of gross, microscopic, or submicron metallic wear debris. The metallurgy of the involved devices is cobalt-chromium-molybdenum (CoCrMo) alloy, and the bearing surface is CoCrMo-on-CoCrMo. Metal-on-metal spinal arthroplasty devices are subject to postoperative complications because of metallic wear debris with similar clinical, radiographic, histologic, gross anatomic, and device-related features to those found in metal-on-metal bearing surfaces in total hip arthroplasty.

Commentary on an article by Stephen S. Tower, MD: “Arthroprosthetic Cobaltism: Neurological and Cardiac Manifestations in Two Patients with Metal-on-Metal Arthroplasty. A Case Report”

This issue of The Journal of Bone and Joint Surgery includes a report on two patients with metal-on-metal total hip replacements who developed systemic neurological and cardiac complications associated with an elevation in serum cobalt levels. Causality is suggested by the fact that the systemic symptoms improved in at least one of the two patients following revision surgery. The report is unusual because of the rarity of the occurrence of metal-induced systemic complications in patients with total hip replacement and the fact that the author was one of the patients. As millions of patients worldwide have undergone total hip replacement, these cases represent rare events indeed. Metal-on-metal bearing surfaces in total hip arthroplasty have been in use for over fifty years. The earliest iterations of these devices lost favor in the 1970s and were replaced by metal-on-ultrahigh molecular weight polyethylene implants. As the indications for total hip replacement were extended to younger, more active patient populations with higher activity demands, clinically important problems such as osteolysis and aseptic loosening related to bearing surface performance were reported with increasing frequency. So-called alternative bearing materials were developed with the goal of reducing wear debris and decreasing osteolysis, aseptic loosening, and other wear-related failures. Metal-on-metal bearings generally demonstrated reduced volumetric wear in comparison with metal-on-polyethylene bearings in hip simulator and implant-retrieval studies. Metal-on-metal bearings allow the use of thinner acetabular components and larger femoral heads, which have been associated with a lower rate of postoperative hip dislocation. Thinner acetabular components also facilitate hip resurfacing. As is the case with metal-on-polyethylene bearings, ceramic-on-polyethylene bearings, and ceramic-on-ceramic bearings, there are potential risks associated with metal-on-metal bearings that accompany the potential clinical benefits. One such risk associated with metal-on-metal bearings is the potential for adverse biological responses to elevated levels of cobalt and chromium in local and remote tissues. This risk is not unique to metal-on-metal bearings as other metal devices with accelerated damage due to wear or corrosion can lead to elevated levels of metal in local and remote tissues. In fact, four of the six reported cases to date that have demonstrated chromium and cobalt-associated neurological and/or cardiac complications had bearing couples other than metal-on-metal. In orthopaedic surgery, metal devices are used for joint replacements, fracture fixation, spine fusion, and tumor reconstruction and therefore are essential for the orthopaedic surgeon. However, if metal release is extensive as a result of wear or corrosion, adverse local and systemic biological responses can ensue. At the present time, there is no generally accepted threshold beyond which serum or blood concentrations of cobalt and chromium are known to be toxic in patients with a metal implant. As there are known risks of revision surgery, undertaking such a procedure on the basis of the blood or serum metal level alone and in the absence of symptoms is problematic. The value of these case reports would have been enhanced if there had been additional clinical, histological, and radiographic detail demonstrating implant orientation (particularly in Case 2, in which this information is quite limited) and if there had been additional detail regarding the methodology of the metal measurement in serum. The latter is particularly critical given the known variability in these measurements, which makes comparison of the metal concentrations in different published series difficult. Nonetheless, there are important lessons that can be learned from these two cases: (1) routine periodic surveillance by an orthopaedic surgeon is recommended for patients with total joint replacements to identify and treat, in a timely fashion, any prosthetic-related complications; (2) surveillance should include both an evaluation of the replaced joint and a discussion of the overall health of the patient; (3) determination of concentrations of metal in the blood or serum may be helpful for the evaluation of patients with local pain and/or otherwise unexplained systemic symptoms and should be used in concert with other clinical and radiographic information; (4) the orthopaedic surgeon should be cognizant of these rare systemic complications of metal devices undergoing accelerated wear and corrosion; and (5) expeditious revision surgery should be considered for a symptomatic patient with evidence of accelerated wear or corrosion who demonstrates local and/or systemic complications associated with the device.

Catastrophic Failure of a Metal-on-Metal Total Hip Arthroplasty Secondary to Metal Inlay Dissociation

Metal-on-metal bearing surfaces in total hip arthroplasty have been recently shown to have acceptable survivorship properties ( J Bone Joint Surg Am. 2006;88:1183; J Bone Joint Surg Am. 2006;88:1173), and they have certain advantages and disadvantages when compared to conventional metal-on-polyethylene bearing surfaces. Like traditional metal-on-polyethylene bearings, these metal-on-metal implants may also suffer from catastrophic failure. This case report represents an unusual situation in a 57-year-old man in which dissociation of a metal inlay in a metal-on-metal total hip arthroplasty resulted in articulation of the inferior aspect of the inlay with the femoral neck, leading to femoral neck notching, extensive periprosthetic soft tissue metallosis, osteolysis, and subsequent prosthetic catastrophic failure.

Biomaterials in Bearing Surface for Total Hip Arthroplasty: State of the Art

In a recent paper published on Lancet, Learmonth defined total hip arthroplasty (THA) “the operation of the century” [1]. Since the first prostheses in 1960s, advances in bioengineering technology have driven development of hip arthroplasty; in fact better materials and designs have increased the range of motion with enhanced stability and very low wear. With these technologies today, hip arthroplasty is safe and effective not only in old patients with an important limitation of life quality but also in younger patients with high demanding activities. The purpose of this patent review is to discuss the recent technologic advances in bearing surfaces and offer an insight into the potential benefits and concerns with the alternative bearing surfaces.

Evolution of bearing surfaces in total hip arthroplasty: a review

Evolution of bearing surfaces in total hip arthroplasty: a review

Alumina-on-Polyethylene Bearing Surfaces in Total Hip Arthroplasty

The long-term durability of polyethylene lining total hip arthroplasty (THA) mainly depends on periprosthetic osteolysis due to wear particles, especially in young active patients. In hip simulator study, reports revealed significant wear reduction of the alumina ceramic-on-polyethylene articulation of THA compared with metal-on-polyethylene bearing surfaces. However, medium to long-term clinical studies of THA using the alumina ceramic-on-polyethylene are few and the reported wear rate of this articulation is variable. We reviewed the advantages and disadvantages of ceramicon- polyethylene articulation in THA, hip simulator study and retrieval study for polyethylene wear, in vivo clinical results of THA using alumina ceramic-on-polyethylene bearing surfaces in the literature, and new trial alumina ceramic-onhighly cross linked polyethylene bearing surfaces.

Macroscopic Third-body Wear Caused by Porous Metal Surface Fragments in Total Hip Arthroplasty

Implants with surfaces of various porosities and pore sizes are in clinical use. This article demonstrates how macroscopic porous metal fragments can detach from the implant surface in total hip arthroplasty (THA) and cause significant third-body damage such as deep scratches and indentations in implants' bearing surfaces. Radiographs prior to revision surgery due to aseptic loosening of the acetabular component revealed the presence of numerous small metal fragments approximately 1 to 2 mm in size in the periarticular area. The size, shape, and material of the metal fragments (cobalt-chromium-molybdenum [CoCrMo]) indicated that they originated from the porous metal surface. In this case, the acetabular liner composite material consisted of two-thirds polyurethane and one-third aluminium oxide ceramic. The femoral head was made of aluminium oxide ceramic. The aluminium oxide femoral head, which had been in situ for 21 years, showed no signs of macroscopic indentations or scratches, suggesting that an aluminium oxide bearing surface, which is significantly harder than the CoCrMo debris, is not significantly affected by metal debris embedment in the counterface material. The polyurethane-aluminium oxide composite material used for the acetabular liner is not comparable to a traditional ceramic bearing surface material. Debris damaged the surface of and became embedded in the liner, causing accelerated wear of the femoral head. In porous metal surface THA, ceramic-on-ceramic bearing couples should, due to their superior hardness, be considered to prevent excessive wear, including debris embedment and scratching of the bearing surfaces, especially in revision cases.

Ceramic Materials as Bearing Surfaces for Total Hip Arthroplasty

During the past decade, advances in total hip arthroplasty component design have produced implants with reliable clinical results in regard to fixation. The foremost unresolved challenge has been the development of bearing surfaces that can withstand the higher demands of younger and more active patients. New alternative bearings with superior wear characteristics that minimize debris include ceramic-on-ceramic, metal-on-metal, and highly cross-linked polyethylenes in combination with ceramic or metal. Alumina-on-alumina ceramic bearings are extremely hard and scratch resistant and provide superior lubrication and wear resistance compared with other bearing surfaces in clinical use. Survivorship revision for any reason for the alumina ceramic bearings at 10 years was significantly higher compared with metal-on-polyethylene. Bearings currently being studied because of their encouraging wear performance in the laboratory are an alumina matrix (82% alumina, 17% zirconia, 0.3% chromium oxide), zirconium oxide, and ceramic-on-cobalt-chromium.

Serum ion levels after ceramic‐on‐ceramic and metal‐on‐metal total hip arthroplasty: 8‐year minimum follow‐up

Alternative bearing surfaces for total hip arthroplasty, such as metal-on-metal and ceramic-on-ceramic, offer the potential to reduce mechanical wear and osteolysis. In the short and medium term, the second generation of metal-on-metal bearings demonstrated high systemic metal ion levels, whereas ceramic-on-ceramic bearings showed the lowest ones. We aimed to verify whether the long-term ion release in metal-on-metal subjects was still relevant at a median 10-year follow-up, and whether a fretting process at the modular junctions occurred in ceramic-on-ceramic patients and induced an ion dissemination. Serum levels were measured in 32 patients with alumina-on-alumina implants (group A), in 16 subjects with metal-on-metal implants (group B), and in 47 healthy subjects (group C). Group B results were compared with medium-term findings. Cobalt and chromium levels were significantly higher in metal-on-metal implants than in ceramic-on-ceramic ones and controls. Nevertheless, ion levels showed a tendency to decrease in comparison with medium-term content. In ceramic-on-ceramic implants, ion values were not significantly different from controls. Both in groups A and B, aluminum and titanium release were not significantly different from controls. In conclusion, negligible serum metal ion content was revealed in ceramic-on-ceramic patients. On the contrary, due to the higher ion release, metal-on-metal coupling must be prudently considered, especially in young patients, in order to obtain definitive conclusions.

Alumina-Debris-Induced Osteolysis in Contemporary Alumina-on-Alumina Total Hip Arthroplasty

Aceramic-on-ceramic bearing coupling, because of its qualities of reduced friction and wear, is an attractive alternative bearing surface in total hip arthroplasty. The use of such bearing couplings is likely to reduce problems related to polyethylene wear debris1-6. Osteolysis has only rarely been reported in association with ceramic-on-ceramic bearing couplings, and reports are generally limited to cases involving early generation ceramic bearings or loosened prostheses7,8. Recently, several cases of osteolysis have been reported after total hip arthroplasty with use of a contemporary alumina bearing, but these reports only described the femoral scalloping seen on radiographs and did not present any histological evidence that ceramic particles were the causative factor9. We present the case of a patient who had formation of a large amount of osteolysis about both the acetabulum and the proximal part of the femur, induced by ceramic wear particles from a well-functioning contemporary alumina-on-alumina total hip prosthesis. The patient was informed that data concerning the case would be submitted for publication, and she consented. A sixty-three-year-old woman underwent bilateral total hip arthroplasty in June 1998 for the treatment of corticosteroid-induced osteonecrosis. The arthroplasties included the use of cementless implants (PLASMACUP SC-BiCONTACT; Aesculap, Tuttlingen, Germany) that incorporated 28-mm alumina femoral heads and alumina acetabular inserts (BIOLOX forte; CeramTec, Plochingen, Germany). The PLASMACUP had a roughened titanium plasma-sprayed exterior and a machined interior that accepted an alumina insert with a self-locking press-fit taper. The BiCONTACT stem was a tapered, rectangular, titanium-alloy implant, the proximal one-third of which was surface-treated with titanium plasma spray. The alumina head was secured to the stem by means of a tapered cone. After surgery, the patient did not present for regular follow-up visits and did not revisit our clinic until June 2006. At the time …