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Elevated Cobalt, Chromium and Molybdenum Levels in Peripheral Blood Have No Effect on the Development of Heterotopic Ossifications after Metal-on-Metal Total Hip Arthroplasty

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DOI: 10.4236/jbise.2016.91004    3,843 Downloads   4,318 Views  


Metal debris from metal-on-metal (MoM) total hip arthroplasties (THA) has been suspected to cause periprosthetic heterotopic ossifications (HO). We determined the influence of disseminated cobalt, chromium and molybdenum on the development of HO. Native blood samples from patients with 86 high-carbon and 16 low-carbon Co28Cr6Mo articulations were analysed by high-resolution inductively coupled plasma mass-spectrometry (HR ICP-MS). The results revealed that high-carbon metal-on-metal articulations showed lower metal blood levels (Co 1.03 to 1.60 μg/l, Cr 0.77 to 0.88 μg/l, Mo 0.45 to 0.56 μg/l) whereas low-carbon articulations achieved higher metal blood levels (Co 2.59 to 6.85 μg/l, Cr 1.25 to 3.55 μg/l, Mo 0.45 to 0.64 μg/l), but no correlation between metal ion blood level or carbon content and the development of HO could be found in these MoM articulations. Hence, metal debris from MoM articulation does not stimulate heterotopic bone formation despite other well-known local reactions.

Received 17 December 2015; accepted 24 January 2016; published 28 January 2016

1. Introduction

Cobalt-based alloys have been proposed and used in high-demanding applications for as long as investment casting has been available as an industrial process. From the introduction of Stellite® in the late 1920s, cobalt alloys have contributed significantly to dental applications. In the late 1970s CoCrMo alloys competed directly with titanium and wrought (drop-forged) CoCrMo alloys for medical implant devices. Cast CoCrMo alloys were basically abandoned in favour of wrought alloys not only because of their higher strength but also because of their hysteresis and thus their superior corrosion characteristics [1] - [3] . Due to their poor long-term survivorship, the early total hip arthroplasties (THA) with large ball metal-on-metal articulations remained of minor importance and fell into general disuse in the 1970s. Nevertheless, analyses of numerous retrievals from the first-gen- eration low-carbon metal-on-metal articulations showed very low linear wear rates and hardly any periprosthetic osteolysis [4] [5] . Inspired by these observations, a second generation of metal-on-metal articulations was developed based on wrought Co28Cr6Mo alloy [6] - [10] in the 1980s. They were implanted in the 1990s and thorough analyses of respective retrievals showed nearly unscratched bearing surfaces and again very low linear wear rates of 2 to 5 µm per year [8] .

Although these newer metal-on-metal articulations showed good longevity and a lower amount of debris, some inevitable problems are persisting. The metal debris contributes to metal ion levels, to the formation of organo-metallic complexes and inorganic metal salts; it is subject to oxidative changes and it is known to be transformed into organic storage forms, such as hemosiderin [11] - [18] . Therefore, possible regional and systemic effects must be considered owing to the possible reactivity and/or toxicity of this metallic debris and interactions with metabolic, bacteriological and immunological processes cannot be ruled out [13] [18] . Furthermore, most constituents of the currently used alloys, as well as some corrosion products are a legitimate cause for concern in terms of toxicity, mutagenicity, neoplastic changes and hypersensitivity reactions [19] - [22] . There is no denying that some rare but severe cases of inflammatory response have been reported recently and heterotopic bone formation may be one of them [23] - [28] .

The formation of ectopic or heterotopic ossifications (HO) was first described as myositis ossificans in 1868. Although ossifications associated with THA are regarded as a type of myositis ossificans circumscripta, this term is not commonly used in orthopedics. Relevant HO are classified into two subtypes according to their etiology in orthopedics: 1) ossifications after trauma and/or surgery and 2) neurogenous ossifications [29] . While sparse formation of ectopic bone occurs in up to 90% of all patients after THA, severe bridging formations of bone or even ankylosis are only seen in a small number of patients [30] - [33] .

Microhistology of HO is equivalent to orthotopic bone except that a directed pattern of the trabecular bone is missing, since no directed load is applied. It should be noted that HO and heterotopic calcifications are not equal. Calcifications are the result of an increased pH-level which gives rise to a subsequent precipitation of calcium carbonate and/or calcium phosphate. Unlike HO microhistology of calcifications does not show any characteristics of bone.

Early radiographic signs of heterotopic bone formation can be observed 3 to 8 weeks postoperatively, while first scintigraphic activity will appear 2 to 4 weeks postoperatively and can be detected for up to 12 months [30] . Scattered or smaller ossifications are either asymptomatic or tend to be painful in different degrees. Functional impairment results from ectopic formations on both sides of the genuine articulation and may lead to a functional ankylosis [33] especially when the ectopic bone is bridging the joint.

Elevated levels of alkaline phosphatase (AP) as well as C-reactive protein (CRP) in patients in the early postoperative phase after THAs are associated with a higher rate of HO [31] [34] .

There is an ongoing controversy whether implant design, fixation technique and/or surgical approach might play a role in the development of HO [35] - [39] . Assured risk factors for the developing HO are: the male gender, post traumatic osteoarthritis, heterotrophic osteoarthritis, Bechterew’s, Paget’s and Parkinson’s disease, diffuse idiopathic skeletal hyperostosis (DISH), previous ankylosis and/or preoperatively limited range of motion (ROM) and excessive osteophytosis [36] [40] - [42] . Another risk factor has been added to this list recently. It has been suspected that elevated metal levels due to the use of metal-on-metal articulations in artificial joints may cause the formation of postoperative periprosthetic HO too [43] [44] .

Therefore, the aim of this retrospective study was to determine whether elevated cobalt, chromium and molybdenum levels in native blood are associated with the development and the expression of periprosthetic HO after THA with metal-on-metal articulations made of wrought low-carbon or high-carbon Co28Cr6Mo alloys meeting ISO 5832-12 and ASTM F-1537 standards.

2. Materials and Methods

This series of consecutive THAs, which were all performed by the same team of orthopedic surgeons under the same technical conditions in an identical operating room environment, was retrospectively evaluated in a cross- sectional study with a follow-up of one to six years.

All patients were given thromboembolic prophylaxis (heparinic acid, coumadine, low molecular weight heparin or combinations thereof overlapping), as well as perioperative antibiotic treatment (3rd generation cephalosporin) and were mobilised the first day after surgery and routinely No standardized prophylaxis against HO was given.

Over a five-year period, in 135 out of 801 (=16.9%) procedures, prosthetic components with a metal-on-metal articulation were routinely used with younger and more active patients. The 135 THAs were performed on 121 patients, 46 (38%) female, 75 (62%) male. Mean age at the time of surgery was 58.6 y (n = 135, range 26 y to 89 y, SD ± 11 y). Surgery was indicated in 124 (91.9%) primary THA, 9 (6.7%) primary revisions and 2 (1.5%) secondary revisions. By the time of follow-up, 39 (32.2%) patients had bilateral THA, whereas 13 (10.7%) received their contralateral prostheses during, and 2 (1.7%) after the follow-up period of this study. The indications for THA are listed in Table 1. The surgical approaches were either anterolateral, modified after Watson- Jones (50.4%) or direct lateral after Hardinge (45.9%), while a transgluteal approach after Bauer was only chosen in a minority (3.0%) of the cases. At the time of follow-up, two patients (1.7%) underwent revision surgery following recurrent dislocation and where thus excluded from this study. Therefore, a total of 133 arthroplasties were taken into consideration for this follow-up study.

Table 1. Indications to total hip replacement with metal-on-metal articulation (n = 135).

aConsolidated values; bEndler cup (n = 5), Tillman cup (n = 1), acetabular component undocumented (n = 1).

All total hip prostheses consisted of an uncemented modular acetabular metal socket with an articulating metal inlay moulded into a polyethylene backing liner (sandwich construct) and a modular metal head (Table 2) of 28mm diameter. The vast majority of the implanted 133 modular rectangular shaped titanium stems (93.2%) were uncemented, whereas only 3.8% were cemented. During revision surgery, 3.0% of the stems could be left in situ owing to their modularity.

The prosthetic components used for the 133 arthroplasties resulted in three different types of metal-on-metal sliding pairings all made from Co28Cr6Mo alloys meeting ISO 5832-12 and ASTM F-1537 standards. Though material specifications are exactly identical, the surface properties of the applied alloys were considerably different implicating different wear behaviour. Therefore, we divided our study population into three discrete study groups (see Table 3).

A total of 113 (85.0%) sliding pairings were made of wrought Metasul® high-carbon Co28Cr6Mo alloy Protasul® 21-WF with a carbon content of 0.25 weight-% providing a metal matrix with fine ingot carbides. A minority of 17 (12.8%) sliding pairings were made of wrought low-carbon Co28Cr6Mo alloy with a carbon content of 0.085 weight-% resulting in a metal matrix with no carbides at all. With 3 (2.3%) articulations, only the acetabular liner of the articulation is documented. Therefore, the type of these pairings could not be determined precisely.

In the high-carbon study group 5 patients with 5 (4.4%) arthroplasties were dead at follow-up and 16 (14.2%) arthroplasties were lost to follow-up. Hence, in the high-carbon group, clinical and radiological follow-up of 92 (81.4%) arthroplasties in 89 patients was possible. Mean follow-up was 4.1 y (n = 92, range 0.9 y to 5.9 y, SD ± 1.2 y).

Table 2. Acetabular and femoral components of the metal-on-metal articulations (n = 133).

aConsolidated values.

Table 3. Co28Cr6Mo metal-on-metal sliding pairings with different surface properties.

aConsolidated values; bAs the three types of high-carbon sliding pairings are absolutely identical in terms of geometry, alloy, tribology, and metallurgy they were consolidated to form one high-carbon study group.

In the low-carbon study group one (7.1%) patient was lost to follow-up and clinical and radiological follow- up of 16 (94.1%) arthroplasties in 13 patients was possible. The mean duration of clinical and radiological follow-up of the low-carbon group was 2.9 y (n = 16, range 1.0 y to 4.8 y, SD ± 1.3 y).

With the 3 undocumented metal-on-metal articulations, 2 patients with 2 (66.6%) arthroplasties were lost to follow-up and clinical as well as radiological follow-up of only 1 (33.3%) arthroplasty was thus possible. The duration of clinical and radiological follow-up of the undocumented articulation was 5.4 y.

Within the three groups, a consolidated total of 109 arthroplasties could thus be considered for detailed evaluation. As the carbon-content of the undocumented sliding pairing is unknown, the third study group was not included in statistical comparisons.

Standard antero-posterior pelvic radiographs of all patients were systematically reviewed for development and the expression of postoperative periprosthetic HO. The radiological findings were classified after Brooker et al. (see Table 4) [45] .

Native blood samples for the HR ICP-MS and the evaluation of serum creatinine were taken from the cubital vein of the non-dominant upper extremity. A standardized protocol for the withdrawal of blood was strictly followed and all samples were taken by the same person using a standardized sample kit in order to equally distribute any inevitable heavy metal contamination caused by the needle, syringe or any part of the kit, All samples were frozen immediately and stored at −20˚C until they were analysed in one batch.

According to current knowledge, cobalt, chromium, and molybdenum ions or respective metallic compounds are excreted renally [46] . Hence, renal function was rated with all our patients by evaluating serum creatinine and calculating the estimated creatinine clearance according to Cockroft and Gault [47] .

Metal analyses on cobalt, chromium, and molybdenum were performed using HR ICP-MS as detection thresholds for most elements are in the sub-parts per billion (ppb) or sub-parts per trillion ranges. In turn and as a consequence of the low detection thresholds, Class 1000 clean room facilities ensured contamination-free sample preparation [27] [48] [49] . A double focusing HR ICP-MS Finnigan MAT® (element analysis package) was used in medium mode (resolution 3400) following a United Kingdom Accreditation Service (UKAS) accredited method (standard operating conditions see Table 5).

For all statistical evaluations, our data were assumed to represent a symmetric random sample from a normal population. The distribution of values and features between the low-carbon and the high-carbon study group were statistically analysed by non-parametric Mann-Whitney tests using SPSS® v10.0. For all analyses, the level of significance was set to p < 0.05.

3. Results

Table 4. Classification of postoperative periprosthetic HOs after Brooker et al.

Table 5. Standard operating conditions of the HR ICP-MS Finnigan MAT® on native blood.

Table 6. Prevalence of postoperative periprosthetic HOs after THA.

A total of 6 patients with n = 6 high-carbon articulations showed estimated creatinine clearances below the commonly accepted age and gender-dependent minimum thresholds (see Figure 1 and Table 7). With the respective patients, the following metal evaluations were considered as wrongly high or at least as inaccurate. The HR ICP-MS results of the respective patients were thus ignored, leaving n = 86 arthroplasties in the high-carbon study group for further evaluations.

The evaluation of cobalt, chromium and molybdenum levels in native blood showed generally higher metal levels with low-carbon articulations (see Figure 2 and Table 8). A comparison of the mean metal levels between low-carbon and high-carbon articulations showed highly significant differences for cobalt (n = 102, p = 0.006) and chromium (n = 102, p = 0.003). Surprisingly, patients with primary THA showed unanimously higher metal levels compared to primary and secondary revisions. With two patients, we detected massively elevated metal levels (cobalt 66.80 µg/l and 15.43 µg/l; chromium 41.6 µg/l and 5.14 µg/l). Both patients had received bilateral high-carbon metal-on-metal articulations. While none of these patients suffers from renal failure, both have a history of unilateral prosthetic dislocation in full internal rotation. The patient showing the highest metal level is a lab technician in the production of colourings and textile dyes (which do contain high levels of metal), therefore, the respective heavy metal levels might not be related solely to THA.

Figure 1. Scatter plot of the creatinine clearance versus the age at follow-up, as well as the res- pective linear regression for male (n = 69) and female patients (n = 40). The results show the age- dependent decrease in renal function, as it was to be expected. Six patients (n = 6 arthroplasties) showed creatinine clearances beyond the reference minimum clearances. Their evaluations of metal levels were thus not considered with this study.

Table 7. Minimum creatinine clearances for the evaluation of renal functioning.

Figure 2. Distribution of cobalt, chromium, and molybdenum levels in native blood within the patients of the three study groups (n = 103) detected by double focusing high-resolution inductively coupled plasma mass spectrometry (HR ICP-MS) at a mean follow-up time of 3.9 y (range 0.9 to 5.9 y, SD ± 1.3 y). The mean cobalt, as well as the mean chromium levels differ significantly between the high-carbon and low-carbon study group (n = 102, p = 0.006, and p = 0.003 respectively). For molybdenum no significant differences were found (n = 102, p = 0.397).

Table 8. HR ICP-MS on cobalt, chromium, and molybdenum in native blood.

aDetection threshold for all evaluations at 0.20 μg/l. bAt the 95% confidence interval, the uncertainty is estimated at ±20% of the reported values, and will increase to ±50% for values close to the detection threshold.

Separate evaluations (see Figure 3 and Figure 4) were carried out according to the carbon-content of the different combinations like metal-on-metal articulations versus contralateral asymptomatic hips, metal-on-metal articulations versus contralateral osteoarthritis, metal-on-metal articulations versus contralateral primary THA with metal-on-metal or metal-on-UHMW-PE or ceramic-on-UHMW-PE articulation, metal-on-metal articulation versus revision surgery with metal-on-metal or metal-on-UHMW-PE or ceramic-on-UHMW-PE articulation [50] . Patients with bilateral THA all show increased metal levels in native blood with the exception of ceramic-on-UHMW-PE articulations. With bilateral high-carbon and low-carbon metal-on-metal articulations the median levels of cobalt and chromium were not just doubled but rather tripled (elevated by a factor 2.7 to 3.2).

Figure 3. High-carbon articulations (n = 86): distribution of cobalt, chromium, and molybdenum levels in native blood versus the clinical condition of the contralateral hip at a mean duration of follow-up of 4.1 y (range 0.9 y to 5.9 y, SD ± 1.2 y).

Figure 4. High-carbon articulations (n = 16): distribution of cobalt, chromium, and molybdenum levels in native blood versus the clinical condition of the contralateral hip at a mean duration of follow-up of 2.9 y (range 1.0 y to 4.8 y, SD ± 1.3 y).

Large differences were found between the median metal levels of the high-carbon and low-carbon study groups with bilateral metal-on-metal articulation (p = 0.034 for cobalt, p = 0.016 for chromium). In comparison to the high-carbon group, bilateral low-carbon articulations showed median cobalt and chromium levels increased by 3 and molybdenum levels increased by 1.2. However, the molybdenum levels seem to undulate between 0.5 and 0.8 µg/l independent to the carbon content, surgery performed, and the duration of follow-up.

The distribution of metal levels in native blood versus the point prevalence and the severity of postoperative periprosthetic HO revealed a balanced picture (see Figure 5 and Figure 6), although significant differences in metal levels between the high-carbon and the low-carbon study group were found. High-carbon articulations showed lower median metal levels in comparison to low-carbon sliding pairings. Arthroplasties without ossify-

Figure 5. High-carbon articulations (n = 86): cobalt, chromium and molybdenum levels versus periprosthetic HOs classified after Brooker et al. [26] at a mean duration of follow- up of 4.1 y (range 0.9 y to 5.9 y, SD ± 1.2 y).

Figure 6. Low-carbon articulations (n = 16): cobalt, chromium and molybdenum levels versus periprosthetic HOs classified after Brooker et al. [26] at a mean duration of follow- up of 2.9 y (range 1.0 y to 4.8 y, SD ± 1.3 y).

cations (Brooker class O) differed significantly with cobalt and chromium (n = 56, p = 0.033 and p = 0.015, respectively) but not with molybdenum. Arthroplasties with ossifications class I after Brooker revealed no significant differences, though the median levels differ conspicuously. Articulations with Brooker classes II and III were statistically not comparable.

4. Discussion

The reported prevalence of HO after THA varies considerably in the current literature. Formations of postoperative ectopic bone are described in 5% to 90% of all patients, whereas only 10% to 27% are clinically relevant regardless to their etiology. Eulert et al. evaluated a patient collective prospectively which did not receive any non-steroidal anti-inflammatory drugs (NSAIDs) and found a point prevalence of postoperative HO after THA of 63.7% [31] . Severe bridging formations or ankylosis are only seen with 2% to 3% of all patients at risk [32] [40] [51] . Overall, 45.9% of the THA patients included in this study developed postoperative periprosthetic HO, but none of them showed restricted mobility or poor prosthetic performance.

The influence of surgical approaches on the development of postoperative HO is a controversial issue [29] [39] . Our data contribute no distinct patterns to this topic. A study by Schara and Herman came to the same conclusion supporting our results [52] .

Systemic release of heavy metal ions, metallic compounds and corrosion products originating from THA with metal-on-metal articulation is well documented and remains as a legitimate cause of concern [19] - [22] . Except from large diameter head articulations there were only a few serious deleterious effects encountered up to now during the last 50 years. The low incidence of local and systemic adverse reactions to elevated metal levels after metal-on-metal THA stands in obvious contradiction to the possible harm that can be triggered by local accumulation and systemic distribution of metal debris. So far, two cases of renal tubular necrosis associated with massively elevated metal levels have been described [53] . Adverse reactions to metal debris tend to occur with less than 1% of the implanted prostheses [27] , at least with small diameter heads. On the contrary, severe cases of inflammatory response have been reported recently [23] - [28] . The only clinical study specifically reporting the incidence of cancer in patients after metal-on-metal THA (of the low-carbon McKee-Farrar type) showed that the overall incidence for neoplasia is not affected by MoM total hip arthroplasties [54] . In contrast to the local accumulation of debris from UHMW-PE and Al2O3 ceramic articulations, the current Co28Cr6Mo 28 mm heads seem to produce only that amount of metal debris that can be absorbed by the body and cleared via a specific however yet unknown renal clearance mechanism [12] [46] [50] [55] [56] .

In the current literature, only few data on metal levels evaluated by the means of ICP-MS have been published yet. So far, only one study on serum metal levels was published by Favard et al. [57] . In general, measurements from native blood show slightly higher metal levels compared to investigations from serum. So it is not surprising that more publications about native blood levels do exist [48] [58] - [62] . Natural cobalt levels are reported to lie between 0.1 and 3.9 µg/l. After MoM-THA they show a time-dependent increase to rather constant levels in the order of 0.1 to 13 µg/l. A similar pattern is found for chromium showing natural chromium levels between 0.1 and 2.1 µg/l and a time-dependent increase after MoM-THA reaching up to 0.1 to 20.7 µg/l.

There are indicators that the additional release of metal ions is related to the implant design and micro- movements within modular implants like in acetabular backings, adapter sleeves and taper junctions. With respect to the amount of metal debris the carbon content is of minor importance [48] .

Hardly any data on molybdenum levels are available. According to our results molybdenum levels are rather constant at 0.1 to 1.9 µg/l over long time periods and are not altered by orthopedic devices, alloys or surgical procedures. This might be due to a highly efficient clearance mechanism for molybdenum.

Our median metal levels for high-carbon articulations compare favourably with median levels in the literature [48] [58] - [62] except for low-carbon articulations where no comparable data were found. We observed significantly higher cobalt and chromium levels in the low-carbon study group compared to the high-carbon group. Reasons for this may be: 1) differences in the duration of the follow-up in the high versus the low-carbon group, 2) the disproportionate number of THAs within both groups, 3) differences due to the carbon content in the surface properties, the wear behaviour and/or the corrosion behaviour and 4) other exogenous and endogenous sources of cobalt and chromium.

1) The mean duration of follow-up of the high-carbon and the low-carbon group differs by ∆ = 1.2 years (high-carbon 4.1 y, range 1.0 to 5.9 y; low-carbon 2.9 y, range 0.9 to 4.8 y). Considering the mean follow-up time, any running-in or bedding-in wear should not interfere with our evaluations as it should not have existed any more at the time when our native blood samples were taken. Running-in wear was found in vitro [7] [63] - [66] and was considered to exist in vivo too [67] . Its relevance on metal ion levels could not be confirmed in a longitudinal five-year in vivo AAS study on cobalt levels [55] .

2) Despite the large difference in the number of evaluated THAs (∆ = 70) between the low- and high-carbon group, the respective difference was taken into account in our statistical evaluations. Our evaluations may be even too conservative (i.e. over-compensated) by applying the Mann-Whitney test. In fact, the significant differences in metal levels between low-carbon and high-carbon articulations may be even more distinct.

3) In 1991 Pilliar concluded that Co28Cr6Mo alloy articulations with higher carbon content might be superior to low-carbon alloy prostheses in terms of wear resistance. Two hip simulator studies on high-carbon versus low-carbon Co28Cr6Mo alloys both meeting the ASTM F-1537 standards showed small but significant differences in the volumetric wear rates in favour of high-carbon articulations [68] . He postulated that the fine ingot M7C3 carbides within the alloy and particularly within the main wear zone of the polished bearing surfaces are responsible for this superior wear behaviour [69] . Hence, it is possible, that the metal levels in the native blood of our patients depend on the carbon content of their hips in the same way as it has been demonstrated in vitro.

4) Exogenous uptake of chromium, cobalt, and molybdenum, effectively does indeed affect metal levels in native blood, and therefore confound the evaluation of metal levels. For the general population, such uptake could be the result of exposure to spray paints, colourings or textile dyes, various chromates, the excessive consumption of sea salt, the consumption of vegetables cultivated close to facilities of the galvanic industry, as well as the excessive use of cosmetics based on sea salt or heavy metal pigments. Therefore, at least patients with known vocational exposure to heavy metals, such as industrial painters or lab-technicians in the production of textile dyes were identified and respective elevations of metal levels were taken into account. Endogenous sources of chromium, cobalt, and molybdenum may affect metal levels in native blood as well. Such uptake could be the result of dental treatment, and surgical procedures.

The distributions of metal levels versus the prevalence and the development of periprosthetic HO show rather balanced patterns for the median cobalt, chromium, and molybdenum levels in native blood. Hence, the blood levels of these ions do not have a significant impact on the development of postoperative HOs. Moreover, the carbon content does also not contribute to HOs since despite the fact that we observed significantly higher median cobalt and chromium levels in the low-carbon group compared to the high carbon group, this difference was not reflected in the degree of HOs. So, our results do not support any contribution of elevated metal levels to the formation of ectopic bone as suggested by H.G. Willert and K. Bachfischer et al. [43] [44] . Their patients are included in a muti-center study and they received a threaded Hofer-Imhof® titanium cups with a modular 4˚ Co28Cr6Mo full-metal taper inlay. In 66% of their cases postoperative HO was developed. In contrary, our patients all received polyethylene backed modular or monobloc cups with metal articulation liner. It thus can be speculated that the additional metal-metal interface between inlay and cup (titanium against Co28Cr6Mo) of the Hofer-Imhof® cups may account for additional metal debris or corrosion products, though this is far from proven. It is remarkable however that unlike our patients, all Bachfischer patients received a standardized NSAID prophylaxis (50 mg sodium-diclofenac per os tid for 7 days).

Given that approximately half of our patients developed postoperative ectopic bone formation prophylaxis against HO should be advised. Prophylaxis against HOs is performed either by pharmacotherapy or by pre- or postoperative radiation of the surgical site. The administration of prophylactic NSAIDs is widely practiced and accepted, whereas other drugs could not prove efficacy in preventing ectopic bone, though some promising experimental approaches with bone morphogenetic protein (BMP) antagonists have been made [70] . Radiation is considered only in revision cases where NSAID-prophylaxis has proven to be not effective enough.

The etiology of postoperative HOs is still unclear. According to our results elevated metal ion blood levels after MoM-THAs do not contribute significantly to the formation of HOs. In search of factors that may have an impact on the formation of HOs we may consider some parameters of our complete data records like the extent of the surgical trauma. It could be elucidated that a shorter time for the surgery correlates inversely with the development of HOs in our data set. Given that a comparative study on unilateral versus simultaneous bilateral arthroplasty revealed significant differences in the development for ectopic bone [71] , the extent of soft tissue trauma could possibly play a role in heterotopic bone formation. Conversely, in support of this hypothesis, there are current clinical experiences and observations that in minimal invasive THA less or even no heterotopic bone is formed.


Funds were received in support of the single-use material and the HR ICP-MS lab as described in this article from Zimmer, former Centerpulse Orthopedics Ltd., Baar/Winterthur (Switzerland).

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

Pfister, A. , Widmer, K. , Friederich, N. and Majewski, M. (2016) Elevated Cobalt, Chromium and Molybdenum Levels in Peripheral Blood Have No Effect on the Development of Heterotopic Ossifications after Metal-on-Metal Total Hip Arthroplasty. Journal of Biomedical Science and Engineering, 9, 25-40. doi: 10.4236/jbise.2016.91004.


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