Revision total hip arthroplasty using the Zweymuller femoral stem

Recent data from the National Hospital Discharge Survey showed both the total number and rate of primary and revision total hip arthroplasty (THA) procedures are increasing [13]. In addition to the increase in number of procedures, analysis of this data by age groups showed this trend to continue across both young and elderly patients. The annual revision burden remained relatively constant at 17.5% per year over the study period. It is expected that the total number of revision THAs will continue to rise with increasing primary THAs being done, especially in younger and more active patients. Moreover, increases in revision THAs are at least in part due to longer patient life expectancy and more active life style. Improvements in implant design and surgical techniques for revision THAs have led to much better clinical outcome over the past three decades. There are however limitations and suboptimal results of the existing techniques. Efforts in developing and evaluating the efficacy and durability of newer and alternative designs and techniques must be continued.

Cementless fixation has evolved to be the predominant technique in femoral revisions. The commonly used stems include: (1) extensively-coated cylindrical design; (2) proximally-coated cylindrical or anatomically-shaped designs; and (3) modular designs with a variety of combinations of proximal and/or distal fit. Most techniques require rigid fit in the femoral diaphysis. Paprosky et al. [4] reported their experience in 170 extensively porous-coated stems. These THAs were followed for a mean of 13 years. Overall stem survival at 15 years was 95%. Radiographic evaluation demonstrated bony-stable stem fixation in 82%, and fibrous-stable fixation in 14% of the hips. Six femoral stems were re-revised due to loosening. Similar clinical efficacy and fixation durability have also been reported with modular stem designs. Christie et al. [5] reported on 129 revisions using the S-ROM stem (DePuy a Johnson & Johnson Company. Warsaw, IN). The mean follow-up was 6.2 years. Overall stem survival at 10 years was 98%. Radiographic evaluation demonstrated bony-stable fixation of the stems in 92%. Clinical efficacy was reflected in an increase of the Harris hip score from 47 (preoperative) to 87 (final follow-up). One femoral component underwent re-revision for mechanical loosening. Kwong et al. [6] reported on the short-term results of using the Link modular tapered stem (Waldemar Link GmbH & Co, Hamburg, Germany) in 143 revision THAs. The overall stem survival rate was 97% at 5 years. Moreover, the mean Harris hip score at final follow-up was 92. A total of 4 femoral stems underwent re-revision, one for infection, one due to surgical error, and 2 due to mechanical component failure.

The Zweymuller femoral stem is designed with a unique geometry, which provides several advantages when used in revision THAs. The rectangular cross-section and wedge-shaped tapered geometry allows for four-point fixation along the four corners within the femoral canal. The fixation is not dependent upon filling of the diaphysis such as in the case of either cylindrical extensively-coated, or modular straight/tapered stem designs. It does require an intact metaphysic-diaphysis junction. Extensive femoral bone deficiencies such as Paprosky IIIa or IIIb [4] may be challenging, especially without longer length of this particular stem design to gain fixation in the upper diaphysis.

There is the additional advantage of no required diaphyseal reaming in femoral canal preparation. This may avoid inadvertent distal perforations or fractures. Avoidance of reaming also in theory preserves greater femoral canal blood flow to maximize bone healing potential around the stem. We found bony-stable fixation in 100% of our stems. Fixation did not deteriorate between the medium-term (5+ years), and the longer-term (12 years) follow-up groups. Finally, we did not observe any significant qualitative adverse bone remodeling as we compared sequential radiographs for each patient. Stress shielding has been widely reported with the use of extensively-coated stems with stable distal fixation [14, 15, 16].

Care must be taken with preparation and insertion of this stem. Its wedge-shape geometry has the potential to result in proximal femur fractures by a log splitting mechanism. We did not find this to be a limitation in the clinical outcome. There were two (7%) calcar fractures, which required circlage wire fixation in the 28 THAs. This compares well with fracture incidence of using extensively porous-coated and modular stem designs in revision THA. Some have reported fracture rate of 9–30% [4, 5, 17].

We believe the Zweymuller femoral stem provides reliable stable fixation in femoral revision surgery. We have had no case of fixation failure up to 15 years in this relatively small series. This technique is especially useful in those cases where there is no extensive segmental bone deficiency in the proximal femur.