Cemented Polyethylene Cups in Patients Younger Than 40 Years

We retrospectively reviewed prospectively collected data of all 130 patients (175 hips) who had a primary THA in our department between January 1988 and July 2004 and who were younger than 40 years at the time of index surgery. We used a cemented femoral stem and cemented acetabular polyethylene cup in all patients. In patients with acetabular bone deficiencies, these deficiencies were reconstructed with the impaction grafting technique. The decision to use bone impaction grafting was made based on the preoperative radiographs in combination with intraoperative findings. A trial cup was placed on the transverse ligament; in the case of a protrusion hip or a superolateral rim defect, a reconstruction was performed. Eighty-four hips (48%) had impaction grafting whereas 91 (52%) did not have impaction grafting. Because a cemented THA was our only treatment technique, patients with all diagnoses were included (Table 1). The majority (62%) of the patients had developmental dysplasia of the hips, rheumatoid arthritis, or corticosteroid-induced avascular necrosis. Fifty-five (42%) patients were males and 75 (58%) were females. Eighty-nine (51%) THAs were on the left side and 86 (49%) were on the right. Forty-five (35%) patients had bilateral THAs. The average age of the patients at index surgery was 31.3 years (range, 16–39 years). The mean body mass index was 25.5 (range, 17.9–36.3). According to the classification of Charnley [7], 46 hips were in Category A, 71 in B, and 58 in C. We followed all patients in this prospective cohort on a regular basis and the minimum followup was 2 years (average, 8.1 years; range, 2.0–18.5 years) after surgery. During followup, six patients (eight hips) died of causes not related to the hip or hip surgery. All patients who died were followed on a regular basis and their data included; none had revision surgery. Of the original group of 175 cups, the data of only one patient were incomplete. Based on a telephone interview, the prosthesis of this patient functioned well; however, a recent radiograph was missing.

We categorized acetabular defects in accordance with the classification system of the American Academy of Orthopaedic Surgeons [10]. Eighty-six hips (49%) had an acetabular deficiency. Type I segmental deficiencies occurred in 16 hips, Type II cavitary defects in 39 hips, and Type III combined deficiencies in 29 hips. One patient (two hips) had ankylosis of the hips, a Type V deficiency. Using impaction grafting, we reconstructed all deficiencies, including mild cavitary defects; however most were larger defects.

Differences between the two groups (with and without impaction grafting) were analyzed regarding diagnosis and gender (chi square test, both p = 0.001). In the group with an acetabular reconstruction, a larger proportion was female and was diagnosed with developmental dysplasia of the hips compared with the group without reconstruction. There were no differences regarding age at surgery, side, bilateral THAs, followup, type of cup used, cup inner diameter, and body mass index between the two groups.

Two-thirds of the operations (67%) were performed by or under the supervision of two senior faculty orthopaedic surgeons (BWS, JWMG). A posterolateral approach without trochanteric osteotomy was used in all hips, with the exception of two. Intraoperatively, in one patient, a preplanned Sugioka procedure was converted to a THA; however, a trochanteric osteotomy already had been performed. In the other patient, a trochanteric osteotomy was performed in a technically demanding hip with a short femoral neck. In one patient, an additional anterior approach was needed because of ankylosis of the hip. All acetabular deficiencies were reconstructed (with the exception of one case) with impaction grafting using autografts and/or allografts in 84 hips (48%); this technique has been described in detail [28‐30]. Segmental bone defects first were reconstructed with wire meshes before the morselized bone graft was impacted and a conventional full polyethylene cup was cemented. In one patient, we reconstructed a lateral rim deficiency without impaction grafting using a solid autograft fixed with two screws. In one of the ankylosed hips (Type V deficiency), we did not use impaction grafting. We used allografts only with impaction grafting in four hips (4.8%), autografts only in 72 hips (85.7%), and combined allografts and autografts in eight hips (9.5%). Allografts were used when the original femoral head was not large enough to reconstruct the defect or in cases with pathologic femoral heads (for example, avascular necrosis of the femoral head). In three cases, instead of a solitary metal mesh, a solid fragment was used in combination with impaction grafting. In two of these cases, a minor segmental defect in the medial wall was closed using a cortical-trabecular fragment of a femoral head. A wire mesh was placed medial on top of the fragment and the acetabulum was reconstructed with impaction grafting. In the third case, a cortical head fragment was used to support the anterior rim together with a rim mesh in a reconstruction. The number of femoral heads used as grafts varied from one to four. In 40 hips (48%), metal wire mesh was used for acetabular reconstruction with impaction grafting (10 medial wall meshes, 39 rim meshes). In nine early cases, we placed a mesh on top of the bone graft just before cementation, but this mesh was not part of a segmental defect reconstruction. However, after we realized this mesh did not add any stability to the reconstruction and there were no signs of damaging of the graft or graft healing by direct contact with cement, we abandoned the use of a mesh for this purpose.

We used 79 (45%) Exeter™ Contemporary™ cups with an inner diameter of 28 mm (n = 75) and 22.225 mm (n = 5) (Stryker Howmedica, Newbury, UK), 71 (41%) Charnley^® Elite™ cups with an inner diameter of 22.225 mm (n = 6) or 28 mm (n = 65) (DePuy, Leeds, UK), and 25 (14%) Müller/AlloPro cups with an inner diameter of 32 mm (n = 19), 28 mm (n = 2), or 22.225 mm (n = 4) (Sulzer, Winterthur, Switzerland). For the femoral component, we used an Exeter™ stem in 111 cases, a Charnley^® Elite™ stem in 48 cases, and a Müller stem in 16 cases. All femoral heads used were made of a cobalt-chrome alloy; no ceramic implants were used.

We cemented acetabular components with a third-generation cementing technique. In the directly cemented cups, after reaming, multiple small drill holes were made with a 2.6-mm drill. After using pulse lavage, vacuum-mixed cement was injected directly from the cement gun and the cement was pressurized by a seal. In cases of reconstruction with bone grafts, we reamed the acetabulum, made multiple drill holes in sclerotic areas, and irrigated the acetabulum. Next the bone graft was impacted. Again, vacuum-mixed cement was injected and pressurized and the cup was inserted. Before 1989, we used Palacos^® bone cement (Merck, Darmstadt, Germany); however, since 1989, we have used Surgical Simplex^® (Stryker Howmedica). In 165 cases (94%), cement loaded with antibiotics was used. All patients received antibiotic prophylaxis consisting of 2 g cefazolin intravenously just before surgery. Other precautionary measures to prevent infections were use of an operating theater with laminar airflow and use of two pairs of sterile gloves.

Postoperatively, all patients received thrombosis prophylaxis with low-molecular-weight heparin for 6 weeks, or before 1999, with acenocoumarol (the individual dosage regimens regulated with regular coagulation tests) for 3 months. To prevent heterotopic ossification, we used nonsteroidal antiinflammatory drugs (NSAIDs) for 7 days. In six patients in whom NSAIDs were contraindicated, we administered one dose (7 Gy) of radiotherapy 1 day postoperatively.

Patients without acetabular reconstruction were mobilized under supervision of a physiotherapist after 1 or 2 days. Full weightbearing was increased in 2 to 6 weeks with the aid of one or two crutches. The patients who underwent impaction grafting were mobilized according to a modified protocol; in the first 6 weeks, only 10% weightbearing was allowed and then 6 to 12 weeks of 50% weightbearing using two crutches was allowed. After 12 weeks, full weightbearing mobilization was allowed. Thirty-one hips had such an extensive reconstruction of major defects that several weeks of bed rest were maintained ranging from 1 to 6 weeks. We used this modified mobilization protocol to ensure graft incorporation before full weightbearing.

Routine followups were scheduled at 6 weeks; 3, 6, and 12 months; and yearly or biannually thereafter. At our outpatient clinic, student researchers not participating in the treatment performed clinical analysis using the Harris hip score [17], the Oxford Hip Questionnaire Score (since 1998) [11], and visual analog scales for pain during rest and physical activity on a scale from 0 (no pain) to 100 (unbearable pain). We report the clinical scores of all patients excluding the 21 patients whose hips were revised during followup.

All anteroposterior pelvis and lateral radiographs of all hips were analyzed on a consensus basis by two of the authors (DCJDK, BWS). Radiographic evaluation included assessment of cup position, loosening of the acetabular component, polyethylene wear, presence of osteolysis, structural quality of the bone graft, application and position of the meshes, migration, heterotopic ossification, and fracture of the cement, mesh, or prosthesis. Radiolucent lines and osteolysis were recorded according to the three acetabular zones as described by DeLee and Charnley [12]. Radiographic loosening was defined as 2 mm or greater demarcation in two or three zones around the acetabular component, progressive demarcation, 3 mm or greater component migration, 5° or greater component tilting, and/or cement or prosthesis fracture. We determined cup migration (> 3-mm shift in any direction or > 5° tilting) in relation to the interteardrop line instead of the Kohler line [16]. Position of the cup of 45° ± 10° was considered normal [26]. We calculated polyethylene wear using the method of Dorr and Wan [13]. All measurements were corrected for magnification. Heterotopic ossification was classified according to the system of Brooker et al. [6]. Graft incorporation was defined as the presence of the crossing of trabecular bone on the bone-graft interface on the radiographs. Clinical failure was defined as the need for revision of the acetabular component for any reason.

We calculated Kaplan-Meier curves to study the survival (time to revision). The end points were (1) cup revision for any reason, (2) cup revision for any reason excluding infections, (3) cup revision for aseptic loosening, and (4) radiographic signs of cup loosening. With an average followup of 8.1 years, 30% of all patients had a followup longer than 10 years. The log-rank test was used to test the differences in survival between cups with and without impaction grafting. Differences in outcomes between the groups were determined with the Student’s t-test (continuous variables after checking for normal distribution) or chi square test (nominal variables).