Total hip arthroplasty to treat acetabular protrusions secondary to rheumatoid arthritis

The inclusion criteria were (1) adults diagnosed with RA complicated by hip joint involvement as defined by the Chinese Medical Rheumatology Association (2010) [6], (2) pelvic, anteroposterior radiographic evidence that the acetabular site had moved over Kohler’s line (or Nelaton’s line) in patients with acetabular protrusions, and (3) the availability of complete medical records and follow-up information. The exclusion criteria were (1) RA in combination with any other disease rendering surgery impossible and (2) acetabular protrusion developing secondary to hip joint trauma or another cause.

Between January 2011 and November 2014, 18 patients (20 hips) with protrusio acetabuli secondary to RA were treated via total hip arthroplasty at our institution. There were 6 males (6 hips) and 12 females (14 hips). Patients’ age ranged from 37.0 to 68.5 years (mean = 45.8 ± 8.3 years). Two patients had bilateral lesions and seven left and nine right lesions nine left and right lesions, respectively. The principal clinical manifestations were hip pain during standing and walking and limitation of joint movement. Severe (outreach angle < 25°) and mild (outreach angle > 25°) abduction limitations were evident in 12 cases (14 hips) and 6 cases (6 hips), respectively. In addition, nine cases (11 hips) exhibited muscle strength of grade IV, and nine cases (9 hips) had muscle strength of grade III according to MRC muscle grading. The Trendelenburg sign was always positive. The duration of RA-related hip disease ranged from 8 to 17 years (mean = 9.2 ± 1.3 years).

Total hip arthroplasty was performed under general or spinal anesthesia. In all cases, the posterolateral approach was used, with the patient placed on the contralateral side. Commencing 1 cm posterior to the tip of the greater trochanter, a straight skin incision approximately 12 cm in length was created. The gluteus medius was retracted, and the short extrarotators were isolated and detached. The insertion of the quadratus was spared if possible. Because the femoral head protruded intrapelvically, it was difficult to dislocate the femoral head in surgery. In those with severe protrusions, the femoral head and neck were completely trapped in the acetabulum, and common osteotomy of the femoral neck was difficult to perform. In such patients, part of the edge of the femoral head and part of the neck lying inside the acetabulum were first removed using a drill or a narrow bone knife. Exploiting lower limb traction and abduction, the femoral neck was then partially exposed to facilitate osteotomy. As the femoral head had retracted and adhered inside the protrusion into the acetabulum, it was difficult to remove the head intact; thus, we removed the pieces created by breakage. The acetabular preparation was performed in two stages [8]: that of the periphery and then that of the medial floor. Unlike the common case in standard reaming, we did not start with the smallest reamers with the aim of preparing the floor first. Instead, the peripheral cartilage was reamed down at first, albeit preserving the subchondral bone using larger reamers, to one or two sizes smaller than the final cup size templated. The aim was to achieve firm contact between the peripheries of the cup and as wide as a band of the acetabular rim as possible. The acetabular rim should be reamed shallow circumferentially only inside the rim, with the decided cup abduction angle to obtain a perfect shape of the rim because an acetabular rim in RA tends to become thin. Second, in preparation of the medial floor, we gently resected the synovial tissue and soft tissue in geodes in the acetabulum and then only exposed bleeding subchondral bone with drilling multiple small holes on the acetabular wall using a Kirschner wire wherever the subchondral bone appeared to be very sclerotic. The medial reaming was therefore not performed because it can lead to penetration of the thin medial wall. The cup should be in contact with at least 50% of good quality acetabular bone for adequate stability of the cup to facilitate bone ingrowth into the shell and provide sufficient mechanical support to the underlying graft. With regard to the preparation methods of grafting bone, the resected femoral head was fined using a bone mill with rongeurs not "holes" holes 5 mm in diameter in 20 hips. In the eight cases of severe protrusion or remarkable destruction and resorption of the acetabulum, we added extra bone that is supplied from the pelvic wing. For the methods of impaction bone grafting, the trial head of the hemiarthroplasty prosthesis is used. A trial head with a size smaller than the diameter of the acetabulum is used for the impaction of the grafting bone until rigid compression of the bone is obtained. After the impaction technique is employed, the cementless acetabular component is inserted and fixed with supplemental screws. All patients were allowed to transfer from the bed to the wheelchair on the first postoperative day. If satisfactory cup rim fixation was evident during surgery, full weight bearing was also allowed on the fifth day not first day first day after surgery.

Given the thin acetabular rim and the fact that bone grafts were placed on the poor quality of acetabular bed, the acetabular components of the total hip arthroplasty that were used in this series were as follows: porous tantalum acetabular cups (TM cups; Zimmer, USA) were placed in 16 patients (16 hips) (Fig. 1), and sintered, three-dimensional, asymmetric, titanium, porous coated cups (R3 cups; Smith & Nephew, USA) were placed in 2 patients (4 hips) (Fig. 2). The weight-bearing interfaces of eight cases (8 hips) received the fourth generation ceramic-ceramic implantations; ten cases (12 hips) received high-level cross-linked polyethylene-lined ceramic implantations.

The Harris scoring system [9] was used to assess hip function before and after surgery. Radiographs of the operated hips were obtained immediately after surgery, and at 6 weeks, 3 months, and 6 months, and annually thereafter. The radiographs were carefully assessed by the senior surgeon and an independent observer. We measured the central, postoperative, hip rotation recovery on anteroposterior radiographs of the pelvis; this was reflected by (1) the vertical distance of the new hip center from the line of the ischial tubercle connection and (2) the horizontal distance of the hip center from Kohler’s line [10].

The immediate postoperative and follow-up radiographs were compared to assess bone regeneration. Bone graft healing was evidenced by the development of continuous trabecular bone throughout the graft and the host bone interface, as revealed by X-rays. Loosening of the acetabular prosthesis was reflected by a shift (horizontal or vertical) of the acetabular cup of > 5 mm or the presence of transparent lines around the prosthesis [11]. Bone absorption within the acetabular bone graft was determined by the Gerber method [12], a transparent line around < 33% of the graft reflected mild reabsorption, while a line around 33–50% of the graft moderate indicated reabsorption and a line around > 50% of the graft severe reabsorption.

SPSS software (ver. 19.0; SPSS Inc., USA) was used for all data analyses. The data are presented as means ± standard deviation (SD). The difference between the Harris hip score and the hip rotational center was evaluated using a paired t test. A P value < 0.05 was considered statistically significant.

The operation time ranged from 55 to 131 min (mean = 89.5 ± 8.1 min). The blood loss ranged from 165 to 480 mL (mean = 295 ± 10.9 mL). No blood vessel or nerve damage occurred, and no acetabular or femoral fracture was noted.

All patients were followed up for 2.5 to 6 years. The mean preoperative Harris hip score was 55.3 ± 9.5, which improved significantly, to 92.2 ± 12.7, at a mean follow-up of 4.5 years (t = 22.81, P < 0.01). Hip flexion and extension increased from a preoperative value of 41.5° ± 6.7° to 102.3° ± 14.5° at the final follow-up. Patients could walk without any aids, including up and down stairs, and could put on shoes and socks independently; subjective patient satisfaction was good (Table 1).

The immediate, postoperative, anteroposterior pelvic radiographs showed that the acetabular cups and femoral stem prostheses were correctly positioned in all cases (20 hips). The mean acetabular inclination angle was 43.5° (range 40°–50°). In all cases, radiographs showed that the impacted morcellized bone grafts became incorporated into the surrounding bone (Fig. 1). Follow-up radiographs showed that the bone grafts united within 4 to 6 months (mean = 5.5 months) after surgery, and continuous trabecular bone that grew through the junction of the host bone and the bone graft was apparent. All acetabular components were stable at the last follow-up (Fig. 2), and no perceptible positional change was noted. At the final follow-up, no radiolucency or sign of bone graft absorption was apparent at the periphery of the cup. No component migrated superiorly or medially, and we found no evidence of recurrence of protrusio acetabuli in any case. The distance from the femoral head center to Kohler’s line increased from 19.87 ± 3.9 mm preoperatively to 21.5 ± 3.5 mm postoperatively (t = 2.312, P < 0.01); the distance between the femoral head center and the ischial tubercle connection decreased significantly from 77.55 ± 12.3 to 72.83 ± 11.1 mm postoperatively (t = 4.221, P < 0.01). Thus, the new hip rotation center migrated from a superior and medial position to a lateral and inferior position, which is normal.