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eMedicine - Immune Response to Implants : Article by

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Introduction
Literature Review
Workup And Diagnosis
Metal Alloy Factors
Course And Treatment
Case Example
Conclusion
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AUTHOR AND EDITOR INFORMATION

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Author: Steven I Rabin, MD, Clinical Associate Professor, Loyola University Medical Center; Chair, Department of Orthopedic Surgery, Dreyer Medical Clinic

Steven I Rabin is a member of the following medical societies: American Academy of Orthopaedic Surgeons, American Fracture Association, AO Foundation, and Orthopaedic Trauma Association

Coauthor(s): Carl N Graf, MD, Staff Physician, Department of Orthopedic Surgery, University of Illinois at Chicago; William J Hopkinson, MD, FACS, FAAOS, Professor and Vice Chair, Department of Orthopedic Surgery and Rehabilitation, Loyola University; Chief of Joint Replacement Service, Department of Orthopedic Surgery, Loyola University Medical Center; Nadim James Hallab, PhD, Assistant Professor, Department of Orthopedic Surgery, Rush-Presbyterian-St Lukes Medical Center

Editors: Jonathan Black, PhD, Professor Emeritus of Bioengineering, Department of Bioengineering, Clemson University; Francisco Talavera, PharmD, PhD, Senior Pharmacy Editor, eMedicine; Robert J Nowinski, DO, Clinical Assistant Professor of Orthopaedic Surgery, Ohio University College of Osteopathic Medicine; Private Practice, Orthopedic Specialists and Sports Medicine, Newark, Ohio; Dinesh Patel, MD, FACS, Associate Clinical Professor of Orthopedic Surgery, Harvard Medical School; Chief of Arthroscopic Surgery, Department of Orthopedic Surgery, Massachusetts General Hospital; Jason H Calhoun, MD, FAAOS, Chairman, J Vernon Luck Distinguished Professor, Department of Orthopedic Surgery, University of Missouri

Author and Editor Disclosure

Synonyms and related keywords: pacemaker, dental implant, orthopedic implant, implanted orthopedic device, allergic reaction, nickel hypersensitivity, chromium sensitivity, cobalt sensitivity, migration inhibition factor, MIF, lymphocyte transformation testing, LTT proliferation testing, metal hypersensitivity implant hypersensitivity

INTRODUCTION

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Metal hypersensitivity is commonly reported in the literature and can include hypersensitivity related to pacemakers, dental implants, and orthopedic hardware (Merritt, 1996). Furthermore, up to 13% of people are sensitive to nickel, cobalt, or chromium (Goh, 1986; Kiec-Swierczynska, 1990; Kimber, 1990; Merritt, 1984; Merritt, 1996; Moller, 1990; Peltonen, 1979; Skinner, 1995). The development of metal sensitivity after implantation of orthopedic hardware is common (Deutman, 1977; Elves, 1975; Merritt, 1996; Waterman, 1985).

Metal sensitivity is also correlated with osteolysis and aseptic loosening of implanted metal hardware (Brown, 1977; Deutman, 1977; Evans, 1974; Goldring, 1993, Merritt, 1984; Merritt, 1981; Waterman, 1985). However, statistical reviews of cases involving adverse reactions after implantation of metal hardware demonstrate that metal sensitivity can be proven causative in less than 0.1% of cases in which sensitivity reactions exist (Merritt, 1985; Merritt, 1996; Panigutti, 1992; Rostoker, 1987; Szliska, 1990). Therefore, the clinical significance of metal sensitization remains a question. Nonetheless, the orthopedic surgeon must be aware of the potential problem, and when other more common causes of implant failure have been excluded, the possibility of allergic reaction to the metal must be considered, evaluated, and treated.

For excellent patient education resources, visit eMedicine's Foot, Ankle, Knee, and Hip Center. Also, see eMedicine's patient education articles Total Hip Replacement and Knee Joint Replacement.


LITERATURE REVIEW

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This issue of the clinical significance of sensitization to implanted metals has long been a matter of debate in the literature. While some studies have shown that sensitization to metal implants is prevalent (Deutman, 1977; Elves, 1975; Merritt, 1996; Waterman, 1985), others refute these data and have concluded that not only does hypersensitivity fail to develop (Carlsson, 1989), but patients with metal hypersensitivity prior to implantation actually become desensitized and anergic after implantation (Rooker, 1980). Some authors have further suggested that metal hypersensitivity may be associated with bone loss and aseptic loosening of implanted devices (Elves, 1975; Evans, 1974; Merritt, 1984), while other authors have concluded that even if a metal allergy exists, no adverse effects occur (Brown, 1977; Carlsson, 1989).

These contradicting studies make it difficult for the orthopedic surgeon to make the diagnosis of symptomatic metal allergy with confidence. The confusion could be due to the presence of different metals in the implants, different manufacturing methods, small numbers of patients in the studies, and difficulty in achieving adequate diagnosis. More research is clearly needed. In the meantime, the diagnosis must be made with caution. Infection, nonunion, aseptic loosening, other inflammatory conditions, mechanical failure of the implant, and malalignment issues must be excluded first before assuming the problem is an allergic reaction.


WORKUP AND DIAGNOSIS

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Clinical presentation

The presenting signs and symptoms of a nickel hypersensitivity to an implanted orthopedic device are variable but usually consist of the expected complaints of a patient with hardware failure. Patients with joint replacements have symptoms of loosening, including pain and instability. (For example, with a total hip replacement, the patient often has groin pain radiating to the medial thigh.) Patients with hardware for fractures have symptoms of nonunion including pain and motion at the fracture site. Local inflammatory symptoms similar to the symptoms of infection are also possible, including warmth, erythema, and swelling over the implant, although systemic complaints such as fever are unlikely. A skin rash may develop over the metal device but is not always present.

Osteolysis due to implant loosening is always in the differential diagnosis. The mechanism of osteolysis is primarily a local reaction to particulate debris, which leads to a cascade of cellular reactions (including activation of monocytes/macrophages, phagocytosis, release of cytokines) that eventually lead to increased osteoclastic activity around the prosthesis. Osteolysis is a reaction to local irritation, not an immune hypersensitivity response (Wright, 2001).

Workup

Blood tests

Currently, blood tests are rarely performed in the workup of immune responses to implants. Generally, white blood cell counts and other inflammatory mediators (such as platelet counts, C-reactive protein levels, and sedimentation rates) are not elevated, or are only minimally elevated, and they are not specific or reliable enough to help in the diagnosis.

Radiologic studies

Careful radiographic assessment of the implant is required. Radiolucencies around the hardware, screw migration, and change in position of the implant imply loosening that could be due to hypersensitivity to the metal. Cystic changes as seen in osteolysis may be seen (see Image 1). CT scans and MRIs are not especially helpful. A bone scan may be positive, but the findings are nonspecific.

Skin patch testing

Traditionally, skin patch testing has been the standard screening test for metal hypersensitivity. This method is limited by the fact that a positive result is not indicative of a true hypersensitivity but must be considered in the context of a patient's medical history and physical findings (Demoly, 1998; Korenblat, 1992). A routine skin test reveals a prevalence of metal sensitivity of 0.2% for chromium, 1.3% for nickel, and 1.8% for cobalt. After placement of metal implants, sensitization (change from negative to positive) occurs in 2.7% for chromium, 3.8% for nickel, and 3.8% for cobalt. Desensitization (change from positive to negative) occurs in 0% for chromium, 2.1% for nickel, and 3.8% for cobalt (Swiontkowski, 2001).

Many patients with implanted metal hardware have positive skin test results for those metals but are completely asymptomatic (Brown, 1977; Carlsson, 1989). If the skin patch test finding is positive, the patient can be designated allergic. However, the clinical significance of the allergy is controversial. Most allergy skin patch tests that show skin reactivity have no clinical implications.

The causes of these skin immunologic reactions are unclear (Korenblat, 1992; Merritt, 1996). It is thought that antigen-presenting cells that are localized to the skin (dendrite cells) may handle antigens differently than the antigen-presenting cells that are systemic (macrophages and monocytes). Therefore, many people who have skin reactivity to metals may never develop any reactivity at the site of prosthesis composed of that metal. Skin test results may not return to normal after metal removal (Merritt, 1981). Conclusions based on skin patch testing should therefore be made with caution and only assumed valid if the whole clinical picture supports the finding of symptoms related to metal allergy. Preoperative skin patch testing is not typically recommended unless there is a strong suggestion of established sensitivity by history, due to a slight chance of sensitization and the high cost/low yield results expected.

Lymphocyte transformation test

Tests that may be more specific include the lymphocyte transformation test (LTT) and the lymphokine migration inhibition factor (MIF) test, which have been used to help diagnose metal hypersensitivity.

In vitro LTT proliferation testing is perhaps the most prevalent method after patch testing for assessing hypersensitivities. It involves measuring the proliferative response of lymphocytes following activation. A radioactive marker is added to lymphocytes along with the desired challenge agent. The incorporation of radioactive H3-thymidine marker into cellular DNA on division facilitates the quantification of a proliferation response through the measurement of amassed radioactivity after a time period of 3-6 days. At day 6, H3-thymidine uptake is measured by using liquid scintillation. The proliferation factor or stimulation index is calculated by using measured radiation counts per minute (cpm), as follows:

Proliferation factor = (mean cpm with treatment)/(mean cpm without treatment).

The use of proliferation testing in the assessment of metal sensitivity has been well established as a method for testing metal sensitivity in a variety of clinical settings. (Svejgaard, 1976; Secher, 1977; Veien, 1978; Svejgaard, 1978; Veien, 1979; Everness, 1990). The technical sophistication and high expense of LTT testing for implant-related metal sensitivity has limited its use; therefore, few conclusions can be drawn (Carando, 1985; Pizzoferrato, 1994; Granchi, 1995). These few investigations using LTT testing report that increased rates of metal sensitivity can be detected above that determined by dermal patch testing (Carando, 1985; Granchi, 1995; Donati, 1998). Such reports seem to indicate LTT testing may be equally or better suited for the testing of implant-related sensitivity than dermal patch testing (Svejgaard, 1976; Secher, 1977; Veien, 1978; Svejgaard, 1978; Veien, 1979; Carando, 1985; Everness, 1990; Pizzoferrato, 1994; Granchi, 1995).

Lymphokine migration inhibition factor test

Another in vitro test that has shown promise in diagnosing metal hypersensitivity involved the use of MIF. MIF acts to prevent lymphocytes from leaving a site where foreign antigens are present. This test selectively detects lymphokine MIF, which, when present, does indicate an active immune response and metal sensitivity (Brown, 1977).

The test is performed by obtaining a blood sample and isolating the lymphocytes. The lymphocytes are then mixed with solutions of specific metal ions, such as nickel, chromium, cobalt, or titanium. The test result is considered positive if the lymphocytes stay in the metal ion solution, indicating a cellular reaction to the metal dissolved in that solution. (In a positive result, no migration occurs.) The test result is considered negative if the lymphocytes migrate away from the particular metal ion solution, indicating that they are not reacting to the dissolved metal (Merritt, 1996).

Studies reveal that positive MIF test results to metals implanted in an orthopedic patient are well correlated with pain, swelling, and dermatological reactions over that area. Furthermore, after the implanted materials are removed, these signs and symptoms improve and the MIF test result returns to normal (Merritt, 1981). The lymphokine MIF is the most useful clinical test for diagnosis of hypersensitivity reaction to orthopedic implants (Hallab, 2000) (see Image 2). Cement wear particles are immunologically inert and have specifically been found not to cause a lymphocyte response in vitro (Santavirta, 1991), so the lymphokine MIF result should be negative in osteolysis.


METAL ALLOY FACTORS

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Another important factor to consider in the biologic response to orthopedic implants is metal ion exposure and release. Implants from different manufacturers have varying metal compositions. (See Image 3 for a partial list.) For example, the nickel content in stainless steel may vary in the range of 9-15.5%, whereas in cobalt-base alloys, the nickel content is usually specified to be no greater than 1% ( <0.2% in actual practice) and essentially 0% for titanium.

In addition to the percentage of a particular metal contained within an alloy, the nature of the alloy and local exposure of the implant are important. Alloys are graded on a scale that measures their metal ion release rate. For example, implant grade 316L (low carbon) stainless steel releases far less nickel than low-grade stainless steel suture. Local exposure of metallic surfaces also affects ion release and can be a factor in the development of hypersensitivity reactions secondary to an implant. Implant properties may alter the amount of surface area available for metal ion release. Plasma-spray coatings and grouting agents limit exposure and decrease ion release from the implant. Roughened, grit-blasted, or grooved surfaces increase the surface area available for ion release from the implant and thereby increase the local levels of dissolved metal (Skinner, 1995).

Taking these factors into consideration, many of the manufacturers of these alloys and implants are striving to make them as resistant to breakdown as possible in the hope that by limiting the quantity of ions released, the rate of sensitization can be decreased (Gordon, 1994; Merritt, 1996).


COURSE AND TREATMENT

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The usual course of events in patients demonstrating true postimplantation metal hypersensitivity is such that symptoms develop over months to years; this may be long after the device has accomplished the goal of fracture stability (Merritt, 1981). Gradual development of skin changes, pain, tenderness, and swelling over the area of the implanted hardware may be coupled with evidence of loosening of a previously stable implant (Merritt, 1981). Acute symptoms in patients with multipart devices may be associated with periods of increased activity (Cramers, 1977).

No medical treatment is available. Analgesic pain medicines, including nonsteroidal anti-inflammatory medications, may control symptoms but do not alter the underlying pathology. Surgical treatment includes revision (obviously with an implant with a different metal composition) for a joint replacement prosthesis or a fracture implant that is still necessary for fracture stability or removal for an implant that is no longer necessary.


CASE EXAMPLE

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A 71-year-old woman had a right intertrochanteric hip fracture and underwent open reduction and internal fixation (ORIF) by using a standard stainless steel hip fracture implant (Synthes DHS; Paoli, Pa). Postoperatively, the patient did well, with evidence of fracture healing, full weight bearing, and full range of motion by 3 months after surgery.

Approximately 6 months later, the patient began to complain of right hip pain laterally over the area of the implanted hardware. The fracture was radiologically healed, but, due to the patient's unbearable pain, a technetium bone scan and tomogram of the area were obtained. The results demonstrated increased uptake and lucency around the lag screw, indicative of hardware loosening.

The patient underwent debridement, hardware exchange, and an iliac crest bone graft. Intraoperative cultures were obtained that all proved negative for an infectious cause. Again, 4 months postoperatively, the patient began to complain of similar right hip pain, although images showed good bone graft incorporation and fracture healing (see Image 4). A course of anti-inflammatory medicines and steroid injections to the region relieved pain only briefly. Hardware removal was performed 10 months after hardware exchange (see Image 5). The patient's symptoms resolved shortly thereafter.

Four years later, the patient had an intertrochanteric fracture of the contralateral left hip and again underwent ORIF by using a stainless steel device (Synthes DHS) (see Image 6). She was recovering well with signs of fracture healing until 3 months after surgery, when she began to experience pain over the implanted hardware. Over the ensuing 3 months, the patient's pain increased to an unbearable level.

Radiographs demonstrated loosening and cut out of the hip lag screw, but the fracture was healing (see Image 7). Therefore, the patient underwent hardware removal 6 months after the initial implantation. At the time of the operation, a collection of serous fluid was noted around the implanted hardware, but no other clinical evidence of infection was observed. The hardware was not loose, and the fracture was stable and clinically healed. Irrigation and debridement was performed, and the patient was treated with intravenous antibiotics until intraoperative cultures proved to be negative.

A short time later, the patient had a fracture of the femoral neck during therapy. Total arthroplasty of the left hip was recommended but, after consideration of her past orthopedic history, the patient was first referred to an allergist for metal allergy patch testing. The results were positive for an allergy to nickel sulfate (with >20 mm of erythema noted) but negative for chromium and cobalt. Given the false-positive results of skin patch testing, blood samples were sent for the lymphokine MIF test, which later confirmed nickel hypersensitivity (according to Katharine Merritt, PhD, from the US FDA Office of Science and Technology, personal communication). The patient underwent left total hip arthroplasty by using a cementless titanium implant with a ceramic head (see Image 8). At 4-year follow-up, she has had no further complaints or problems (see Image 9).

This example, in retrospect, presents the strong possibility a true metal hypersensitivity reaction. However, because this is a diagnosis of exclusion, this condition is difficult to definitively prove. This patient received 3 different stainless steel devices at 2 different sites. At the first site, the right hip, complete healing occurred, and the patient remained asymptomatic after the device was removed. At the second site, the left hip, again complete healing occurred and remained asymptomatic since a titanium device was implanted. The patient had positive nickel sensitivity, as shown on both skin patch testing and the lymphokine MIF testing, and negative culture results with no clinical evidence of infection. It is likely that this patient did have a true metal sensitivity reaction causing clinical failure of hardware and disabling pain.


CONCLUSION

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Orthopedic surgeons may find themselves treating patients with possible metal hypersensitivity. Although prescreening all patients for metal hypersensitivity may be costly, with dubious clinical relevance, various specific laboratory tests, including the lymphokine MIF test, appear to be confirmatory. As stated previously, this is a diagnosis of exclusion; therefore, cases are difficult to identify because the signs and symptoms are very similar to other more frequent causes. In the rare case in which a patient displays symptoms such as recurrent pain and aseptic loosening related to implanted hardware, the differential diagnosis of metal hypersensitivity should be considered.


MULTIMEDIA

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Media file 1:  Osteolysis around a total knee implant.
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Media type:  X-RAY

Media file 2:  Lymphokine migration test.
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Media type:  Image

Media file 3:  Composition of common metal alloys used in orthopedic implants.
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Media type:  Graph

Media file 4:  Case example. Second stainless steel implant in the patient's right hip. Image shows a healed fracture but failing hardware.
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Media type:  X-RAY

Media file 5:  Case example. Image shows the right hip after the hardware was removed.
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Media type:  X-RAY

Media file 6:  Case example. First stainless steel implant in the left hip.
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Media type:  X-RAY

Media file 7:  Case example. Image shows the failed stainless steel implant in the patient's left hip.
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Media type:  X-RAY

Media file 8:  Case example. Image shows successful titanium total hip implant in the left hip.
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Media type:  X-RAY

Media file 9:  Case example. Final follow-up image after successful total hip replacement of the left hip.
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Media type:  X-RAY


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Immune Response to Implants excerpt

Article Last Updated: Mar 23, 2005