Primary total hip arthroplasty using an uncemented Wagner SL stem in elderly patients with Dorr type C femoral bone

As described by Dorr et al. [1], type C femoral bone, characterized by wide, patulous canals with poor bone quality, always presents a challenge for fixation of cementless implants in patients undergoing total hip arthroplasty [2‐6]. Type C bone is relatively common among the elderly population, especially in older postmenopausal females [1, 2]. Patients with Dorr type C bone always exhibit wide, stovepipe-shaped femoral canals, and thin cortices in proximal femur [3]. The combination of abnormal bone shape and a presumed poorer local biologic environment are the reasons that surgeons have been hesitant to use uncemented prosthesis in these femora [4‐6]. Traditionally, femoral fixation in these patients had been obtained with polymethylmethacrylate bone cement [2, 5, 7]. However, the long-term performance of cemented stems may be compromised by fixation loosening, osteolysis, and revision problems [5]. For the past 10 years, more modern techniques have been developed and more advanced formal implant designs have become available [4‐6], which have prompted to look at cementless reconstruction of the femur in presence of unusual proximal femoral anatomy [8‐10]. Nevertheless, a mismatch between the geometry of the most current femoral stems and abnormal morphology of proximal femoral canals is the greatest hindrance to the use of cementless stems in type C bone although some results of conventional large diameter or tapered cementless stems are generally good in those patients [4‐6, 9, 10]. In fact, most cementless primary stems cannot achieve an anatomic fit and fill from the diaphysis to metaphysis in an extremely wide stovepipe-shaped femoral canal [4‐7].

The Wagner SL implant is a long-straight stem femoral prosthesis with tapered geometry and raised ridges that are designed for revision. This prosthesis was originally designed by Wagner in 1987 [11] for treating patients with severe bone loss in their proximal femurs [12]. The clinical efficacy using the Wagner SL prosthesis has been widely publicized in revision surgery [11‐13]. The third generation of Wagner SL femoral stem occupies cylindrical straight tapered shape and long straight shaft which is suitable to be used not only in the extensive metadiaphyseal deficiency and a widened femoral canal in revision but also in the stovepipe endosteal canal in type C bone.

On the basis of these available data, it was our hypothesis that this prosthesis stem would allow for stable biologic fixation in a wide spectrum of femoral geometry, including younger or older patients with wider femoral canals in primary total hip arthroplasty. Furthermore, we also theorized that close geometrical matching between the cementless stem and femoral canal was the key factor obtaining intimate diaphyseal fit, fill, and biologic fixation.

In the present study, we extended the use of cementless Wagner SL stems to primary total hip arthroplasty in patients with type C bone. The aim of the current study was to analyze the possibilities of the cementless Wagner SL stem for primary total hip arthroplasty (THA) in type C bone. Experience with geometric match between the Wagner SL stem and widened stovepipe femoral canal was of special interest.

The mean follow-up period was 125 ± 10.5 months (range 96 to 156 months). Average Harris hip score was 46 ± 9 (range 39 to 62) preoperatively, 88 ± 8 (range 78 to 96) at 12 months after surgery, and 90 ± 9 (range 83 to 98) at last follow-up. Nineteen of the 25 patients (76.0%) achieved excellent HHS scores (> 90), 3 (12.0%) good (80–89), 2 (8.0%) fair, and 1 (4.0%) poor. One patient with a fair score had clinically significant thigh pain.

Femoral stem filling was assessed as percentages at three distinct levels: just below the lesser trochanter, at midstem, and 1 cm above the tip of the component on post-operative X-ray, which was calculated as SW (stem width)/ID (inner diameter of the femur) × 100 in millimeters. The mean proximal stem-to-canal fill percentages were 97% ± 2.1%, 95% ± 3.5%, and 88% ± 2.6%, respectively (anteroposterior view) and 92% ± 2.2%, 86% ± 1.9%, and 83% ± 2.5%, respectively (lateral view). Stem alignment revealed a varus position in 5 femurs (Fig. 1a–e) and a valgus position in 1; the other 19 hips exhibited neutral alignment (Fig. 2a–c).

Based on Engh classification [17], 23 hips had radiographic evidence of a bone ongrown prosthesis, and there was stable fibrous fixation in 2 hips. At the final follow-up (average, 72 ± 8.5 months), bone resorption and stress shielding were noticeable in 5 hips (grade 1 in 3 hips, grade 2 in 2 hips, as described by Engh [19]. Stem subsidence was present in three stems. Subsidence was measured using bone-prosthetic landmarks on comparison radiographs. The range of stem subsidence was 2 mm in two stem and 3 mm in one stem. No definite clinical or radiographic evidence of implant loosening was observed. None of the implants has been revised. Cortical hypertrophy of the femur was seen in 18 hips. This hypertrophy was observed most commonly in Gruen zones 3 and 5.

There was no intraoperative femur fracture and femoral perforation during the canal rasping or stem implanting. No early infection or wound healing problems occurred. One patient underwent a deep venous thrombosis that was adequately managed on postoperative care and resolved without sequelae. One dislocation occurred within 1 month postoperatively, treated with close reduction and a hip brace, without the need for further surgery, and no recurrence was observed.

The morphology of the proximal femur differs widely according to age, race, sex, and lifestyle [2, 3, 20]. Some pathologic factors may also affect the geometry of the femur, such as rheumatoid arthritis, atrophic osteoarthrosis, osteoporosis, and some metabolic bone diseases [21, 22]. Type C bone is found predominantly in women of older ages and lower body weight, and it has both structural and cellular compromise [1]. Cortices are thin with complete loss of the medial and posterior cortices resulting in a “stovepipe” [3] shape of the intramedullary canal. These alterations increase the difficulty of joint replacement and may also threaten the immediate fixation and long-term survival of the prosthetic implant [1, 3‐6]. The poor bone quality with an enlarged femoral canal had led surgeons to prefer the use of cemented implants in this type of femurs [4, 6, 21] because some mismatches can be accommodated by the void-filling capacity of the cement layer in a cemented hip system [3]. However, fixation loosening of the cemented femoral component has remained the leading revision problem in relative young patients [23]. Meanwhile, fat embolism, pulmonary microemboli, and cardiac arrest associated with cementing are still potential threats to older patients [24, 25], because the large amount of cement is necessary for filling the widened canal in type C bone. With the current advance in prosthetic design, cementless fixation of the femoral stem has proven to be durable and predictable in total hip arthroplasty [4‐6, 8‐10]. More and more cementless prostheses have been successfully used in particular situations, such as elder patients with poor bone stock [10, 12, 26], abnormal shape of proximal femur [8], and also in revision surgery [11, 27‐29]. Although the results of conventional large-diameter or tapered cementless stems ware generally good in the patients with type C bone [12, 27, 30], the degree of stem-to-canal fill and the parameters of cortical index and isthmus width which indicated the extremely wide stovepipe canals have seldom described in these literatures [4‐6, 12, 30, 31], and few considers the Wagner SL stem as a possibility in primary total hip arthroplasty for type C bone.

In cementless total hip arthroplasty, femoral prosthetic design, cross-sectional area of the stem, proximal geometry of the femoral canal, as well as surgical techniques can all affect the degree of the stem fill [32]. Many kinds of cementless prostheses have been developed to improve bone-implant fit and promote biological fixation [3, 8, 11, 16, 18, 22, 26, 31]. However, there is currently no consensus regarding the ideal stem design to enhance various features such as survivorship and implant fit [16]. The optimal femoral cementless stem should occupy a close geometric matching between the femoral stems and proximal femoral canal to achieve accurate endosteal stem fit [3, 8, 16]. The type C bones often present a correspondingly straightened femoral canal profiled with a wide isthmus and thin cortex [3, 22], and the enlarged isthmus loses its metaphyseal hoop stress for the most primary taper stems [2]. Meanwhile, anatomically shaped stem and distally fixed cylindrical stems that designed with curve to fit the antecurvation of the femur [17] are not favorable to a wide, straightened canal in type C bone. In fact, most primary conventional implants cannot provide a close geometric matching to the extremely stovepipe canals [2‐6, 31]. In an effort to avoid this mismatch between conventional cementless stems and compromised endosteal geometry in type C bones, a new short, metaphyseal-fitting anatomic cementless femoral stem was developed recently [33, 34]. However, a potential concern with the use of this type of short femoral component, particularly in elder patients with type C bone, is the loss of stability of the component and failure of osseous ingrowth [33].

In 1987, Wagner [11, 35] developed a straight, long-stemmed femoral component that that is designed for revision. The Wagner self-locking stem was the first fluted, tapered stem designed to bypass the areas of proximal bone loss and secure uncemented fixation in the remaining distal, well-preserved femur [28]. In his first reports, Wagner [11] indicated that the self-locking revision stem was used mainly in patients with large defects of the proximal femur in revision surgery. The cylindrical tapered design with raised ridges also increases the initial rotational stability of the prosthesis in revision hip surgery [35, 36]. Similar to some authors [27‐29], we began to use the Wagner SL stem only in revision arthroplasties, and then we found that the revision femoral cavities often present a trumpet shape with the wide diaphyseal canal after the femoral prostheses were removed. It is interesting that the third-generation Wagner SL prosthesis was designed to a long-straight stem with a cylindrical tapered shape which had a close apposition to the stovepipe femoral canal. So we broadened the use of Wagner SL prostheses to the primary total hip arthroplasty in type C bones. In our practice, based on the long-straight cylindrical stem with a taper angle of 2°, the third-generation Wagner SL stem offers a close geometrical matching to the wide stovepipe femoral canal and allow a perfect fit and fill along the endosteal cortex from the metaphysis to diaphysis in type C femoral bone. The eight raised ridges provide rotational stability in the femoral canal and its full grit-blasted rough titanium surface also provides long-term biological fixation [28, 29]. Therefore, the Wagner SL stem is available in lengths of 190 to 305 mm and in diameters of 14 to 25 mm [12], so the Wagner SL implants systems currently provide stems in a wide range of sizes to allow proper sizing with the extremely wide stovepipe femoral canals in type C bone.

We used Wagner SL stem to perform primary total hip arthroplasties and achieved good short-term clinical and imaging results in patients with type C bone. According to HHS score, 89.3% of our group had good and excellent results. Despite the frequent occurrence of dislocations and stem subsidence of Wagner SL stem in revision surgery [27‐29], our radiographic evaluation at 4–8 years follow-up showed good osteointegration and less subsidence of the stem in this series patients. We believe this phenomenon is due to the good endosteal stem fit and fill in type C femoral bone, meanwhile, beside the tapered shape of the new Wagner stem may improve the tendency to self-limit subsidence [36], the eight length-wise raised ridges can achieve stable anchorage in relative good bone stock in type C femoral bone rather than the poor bone stock in former prosthetic stem bed. However, the patients with type C bone always present the weak bone or thin cortices, meticulous surgical technique must be taken to avoid fracture or femoral perforation during reaming and implanting. In our experience, reaming is more exact when using a machine than doing reaming by hand.

This study has certain limitations. First, it was retrospective in nature and it included a relatively small series. Second, the duration of follow-up was short and was thus insufficient to allow conclusions to be drawn, because most prostheses exhibit good results at 5 to 7 years after the operation. However, there is strong evidence that early stability (< 2 years) of a cementless femoral stem is a good predictor of good late clinical results [37, 38]. Third, it represents two surgeon’s experience, and we also have less experience for use of this stem in particular type C bone patients with extremely weak bone or thin-walled cortices (cortical index of ≤ 0.2). However, we believe it provides insight into the performance of this prosthesis in a selected patient population with lesser quality bone in type C bone. Finally, we performed no interobserver variability studies of the radiographic to confirm the measurements by the single observer, and this may lead to bias in interpreting the radiographic in turn leading to errors of either underestimation or overestimation.

In summary, the third generation cementless Wagner SL stem, designed with a long-straight cylindrical tapered geometry, offers a significantly good canal fit in type C femoral bone. We find that the cementless Wagner SL stems can achieve reliable stability by close apposition of the stem and extreme wide stovepipe femoral canal from metaphysis to diaphysis, both in terms of stem-to-canal fill percentage. Further long follow-up is needed to confirm these short-term results.