Background

Despite the improvements in clinical outcomes achieved by the introduction of proximal femoral nail anti-rotations (PFNAs) for intertrochanteric femoral fractures (IFFs), a small number of elderly individuals will succumb to their disease [1]. Available treatment options involving conversion to total hip arthroplasty (THA) for a failed PFNA have been reported [2, 3], which provide the basis for further treatment strategies. A failed PFNA converted to an uncemented or a cemented THA (UTA or CTA, respectively) device has been considered a recognized option [4]. At present, which device (UTA or CTA) is more beneficial in this conversion is still controversial [4, 5]. For individuals in the 50–70 age range, a previous study [4] involving 72 conversions of failed PFNAs to a CTA device (cement; Stryker, Mahwah, NJ) exhibited that dual-cemented CTA devices had satisfactory functional outcomes, with a total complication rate of 20.8% and periprosthetic fracture rate of 4.2%. For individuals in the 40–80 age range, data from the Norwegian Arthroplasty Register [6] indicated that dual-uncemented UTA devices had an elevated risk of failure (RR 1.4; CI 1.2–1.6), which was primarily attributed to a growing risk of periprosthetic fracture (RR 5.2; CI 3.2–8.5) and dislocation (RR 2.2; CI 1.5–3.0) when compared with dual -cemented CTA devices. For individuals in the 40–50 age range, a retrospective study [7] consisted of 168 CTA devices with a mean follow-up of 10 (2–19) years, and it showed an improved clinical functional outcome, with a revision rate of 17% and a survival of 88% (95% CI: 82–94) after ten years. However, for elderly individuals aged ≥60 years old with a failed PFNA, there is no literature on the failed PFNA converted to a UTA or CTA device following previous IFFs.

Considering the limited literature on this conversion of a failed PFNA to a UTA or CTA device, we used the China Southern Medical Centre (CSMC) database to execute a retrospective review to assess clinical outcomes of this conversion of a failed PFNA to either a dual-uncemented UTA or a dual-cemented CTA device without antibiotics in the elderly population with primary IFFs.

Methods

Study population

Consecutive elderly individuals with IFFs who had experienced a conversion from a failed PFNA to a dual -uncemented UTA device or a dual -cemented CTA device from March 1, 2007 to March 31, 2017 were identified from the CSMC database and retrospectively analysed. The revision procedure was executed by four highly experienced orthopaedists according to previous descriptions [3, 4]. Postoperative functional rehabilitation instructions and medication interventions were based on our published literature [4]. Inclusion criteria were as follows: individuals aged ≥60 years old at the time of the conversion intervention; individuals with a primary IFF (type AO/OTA 31. A) who underwent the conversion of a failed PFNA (Smith & Nephew, Memphis, Tennessee, USA) to either a dual -uncemented UTA device or a dual -cemented CTA device without antibiotics (endoprosthetic components are shown in Table 1) as a result of a cut-out, non-union, or intolerable hip pain. Major exclusion criteria were as follows: incomplete information (i.e., the year of primary PFNA and conversion, age, sex, diagnosis, indication for revision); unidentified type of prosthesis or hybrid prosthesis; polytrauma; bilateral IFFs that may have affected the validity of the results; osteosynthesis or hip dysfunction prior to fractures; a concomitant diagnosis of inflammatory arthropathy (i.e., tuberculous arthritis or rheumatoid arthritis); diseases that affect bone metabolism (i.e., rickets, Fanconi’s syndrome or hyperparathyroidism), organ failure (i.e., chronic renal failure, heart failure), steroid dependence or resistance diseases, serious infectious diseases (i.e., acute respiratory distress syndrome), tumours, and mental disorders. Each individual had to undergo similar standardized rehabilitation instructions after index revision. Related physiotherapy (weigh-bearing and range-of-motion exercises as tolerated) was initiated immediately after revision.

Table 1 Manufacturer details of prostheses employed in the review

Outcomes and variables

Follow-up occurred at 1, 6, and 12 months after revision and annually thereafter. The primary endpoint measure was functional outcome as evaluated using the HHS. Pre- and post-revision HHSs were documented. The functional results of symptomatic and asymptomatic patients prior to revision were compared separately. The secondary endpoint measures included the overall rate of key orthopaedic complications and the rate of revision, aseptic loosening, periprosthetic fracture, dislocation, and unbearable hip pain. We defined PFNA failure as any condition that required replacement with another prosthesis. We defined revision as when any component (involving femoral head and liner) or the whole prosthesis was extracted or exchanged for any reason [8]. Aseptic loosening was defined on the basis of prior report [2]. Symptomatic or asymptomatic were defined as patients having or not having symptoms (i.e., hip pain or dyskinesia) prior to revision, respectively.

Statistical analysis

We used the Mann-Whitney U test to assess nonparametric data. Parametric data were compared using t-tests (age, BMI [body mass index], BMD [bone mineral density], and follow-up time). Categorical variables (sex, side, symptomatic/asymptomatic prior to revision, mechanism of injury, fracture pattern, comorbidities, reasons for conversion, interval from PFNA to revision, and key orthopaedic complications) were cross-tabulated and assessed per the chi-squared or Fisher’s exact tests. Kaplan-Meier method was used to illustrate the implant survival curves, and the log-rank test was used for comparison. Hazard ratios (HR) with 95% confidence intervals (CI) was calculated using the Cox proportional hazard regression model. Bias initiated by individual skeletal variation was avoided at the time of inclusion through the analysis of the contralateral hip. The level of statistical significance was set at p < 0.05. Statistical analyses were executed per SPSS 25.0 (IBM, Armonk, NY).

Results

In total, 258 patients with a failed PFNA were identified in the current study, 60 of whom did not meet the criteria for inclusion, leaving 198 patients (UTA, n = 98; CTA, n = 100) eligible for the study (Fig. 1). The mean age at the time of the revision was 66 (62–71) years for a UTA device and 66 (61–71) years for a CTA device. There were 45 and 48% males in the UTA and CTA groups, respectively. Both instability and mechanical failure were the most frequent reasons for surgery (54.1% of all revisions for UTA vs. 52.0% of all revisions for CTA). The patient characteristics were presented in Table 2. The median follow-up was 65 (60–69) months for the UTA group and 65 (61–69) months for the CTA group.

Fig. 1
figure 1

Flow diagram showing methods for identification of study population to assess the outcomes of failed PFNAs converted to a UTA or CTA device in elderly individuals with IFFs

Table 2 Baseline data

Primary endpoint

Tables 3 and 4 show the functional results of HHSs for the two groups. Figure 2 represents the change curve of the mean value of the two groups of functional results at each follow-up. At the final follow-up, significant distinctions were observed (87.26 ± 16.62 for UTA vs. 89.32 ± 16.08 for CTA, p = 0.021; 86.61 ± 12.24 for symptomatic UTA vs. 88.68 ± 13.30 for symptomatic CTA, p = 0.026). During the first 3 years after revision, there was no distinct distinction in HHSs between groups. Starting from 3 years after revision, a higher functional score was observed in the CTA group than in the UTA group, and this advantage tend to strengthen over time. For the UTA group, significant differences were observed when comparing symptomatic and asymptomatic patients (87.26 ± 16.62 for symptomatic vs. 89.32 ± 16.08 for asymptomatic, p < 0.05). For the CTA group, significant differences were also noted when comparing symptomatic and asymptomatic patients (88.68 ± 13.30 for symptomatic vs. 90.54 ± 15.02 for asymptomatic, p < 0.05).

Table 3 Mid-term follow-up HHS
Table 4 Comparison of symptomatic patients prior to revision and asymptomatic patients prior to revision
Fig. 2
figure 2

The change curve of the mean value of the two groups of functional results at each follow-up

Secondary endpoint

There were 40 key orthopaedic complications in the UTA group and 19 in the CTA group. A distinct distinction in the overall key orthopaedic complication rate was detected (40.8% [40/98] vs. 19.0% [19/100], p = 0.001). Survival curves for implant revision showed that the 69-month unadjusted cumulative survival rates were 0.632 (95% CI, 0.614–0.657) for UTA and 0.963 (95% CI, 0.952–0.971) for CTA (HR 0.29 [95% CI 0.10–0.62], p = 0.01), as presented in Fig. 3. For the UTA group, 11 (11.2%) individuals underwent conversion surgery, 13 (13.2%) experienced aseptic loosening, and 10 (10.2%) had a periprosthetic fracture. For the CTA group, 3 (3.0%) individuals underwent conversion surgery, 5 (5.0%) experienced aseptic loosening, and 3 (3.0%) had a periprosthetic fracture, as presented in Table 5. During the first 3 years of follow-up, statistically significant differences failed to be detected between groups in terms of revision, aseptic loosening, or periprosthetic fracture. At the final follow-up, the rate of revision was 11.2% for UTA and 3.0% for CTA (p = 0.025); significant differences in the rates of the two orthopaedic complications were detected (aseptic loosening: 13.2% for UTA vs 5.0% for CTA, p = 0.043; periprosthetic fracture: 10.2% for UTA vs 3.0% for CTA, p = 0.041). Aseptic loosening (acetabular loosening and/or femoral loosening) was the most common cause of revision (72.7%[8/11] for UTA vs. 66.7%[2/3]), as presented in Table 6.

Fig. 3
figure 3

Kaplan–Meier Curves for implant revision as endpoint, unadjusted Log rank p = 0.01

Table 5 Mid-term follow-up: prosthesis-related key orthopaedic complication rate
Table 6 Details of reasons for revision

Discussion

This retrospective study showed that for elderly individuals who suffered PFNA failure, compared with a UTA device, a CTA device may have a noteworthy advantage in regard to the revision rate and the rate of key orthopaedic complications. Our findings are in line with those of previous studies [9,10,11] that a CTA device is more effective than a UTA device in primary PFNA revision. In addition, for elderly patients with clear failure of PFNAs, CTA revision should be performed as soon as possible, regardless of whether these individuals have symptoms. With the increasing numbers of failed PFNAs, expanded application of UTA or CTA devices is predictable [12]. Nonetheless, individuals are not eager to suffer from the excessive complications initiated by UTA or CTA revision for treating failed PFNAs. Thus, when a revision procedure is proposed, CTA revision for failed PFNAs could be an enticing option.

Findings from previous studies [13, 14] have demonstrated the superiority of CTA devices over UTA devices. Although significant differences in functional scores were detected, we did not detect noteworthy distinctions in the incidence of key orthopaedic complications during the first 3 years. For patients with PFNA failure, the mid-term prognosis of UTA or CTA devices remains controversial [15]. A growing body of evidence [16, 17] suggests that the differences in therapeutic efficacy between a UTA device and a CTA device for a failed PFNA were primarily in the revision rate. Nonetheless, a short-term follow-up study [18] involving 112 patients with failed PFNAs showed that there was no noteworthy distinction between a UTA device and a CTA device regarding the revision rate, and the use of UTA device did not lead to an increase in orthopaedic-related complications.

The evidence on which the decision to use a prosthesis to revise a failed PFNA was based was vague and controversial [19]. In addition, the operating specifications for reducing or avoiding mechanical complications were rarely mentioned in the previous literature [7, 20]. Consistent with previous randomized trials [14, 16], we did not observe a remarkable difference in mechanical complications between groups at the end of the 3-year follow-up. In the current study, the incidence of major orthopaedic complications was acceptable. However, there may be some differences in the comparison of quantitative variables, mainly due to the previous studies [5, 12] involving diverse research subjects, such as multi-ethnic groups, different age groups or groups with younger subjects. According to previous experience [21], UTA devices tend to be used in younger, non-osteoporotic patients, while CTA devices are frequently used in older osteoporosis patients. Based on this conclusion, we could conclude that CTA devices tend to be adopted for PFNA failure in elderly individuals. However, for younger groups, the choice of prosthesis is still controversial [13]. Recent studies [19, 22] have shown that CTA devices have noteworthy advantages in terms of revision rate and orthopaedic complications for failed PFNAs in young patients compared to UTA devices.

UTA devices are now infrequently utilised in elderly patients with osteoporosis [4]. This infrequent use is largely attributable to a regrettably high orthopaedic complication rate [2], although improvements in crosslinked polyethylene have increased the biomaterial benefits of UTA devices over CTA devices [5]. Nonetheless, the number of individuals suffering from UTA-related orthopaedic complications continues to increase. No consensus has been reached on the indications and timing of revision for PFNAs, and the rates of the revision of PFNAs differ among studies [4, 14]. Furthermore, a series of studies [23, 24] have reported that conservative management has successfully treated a large number of patients with failed PFNAs. In this situation, it is quite difficult for surgeons to manage such patients with failed PFNAs, and conservative management or revision has become an intractable alternative. However, recent evidence [2, 22] suggests that UTA or CTA revision is generally associated with a significant improvement in functional outcomes. Therefore, such intervention should be performed regardless of the complications initiated by UTA or CTA revision.

For both the UTA and CTA groups, symptomatic patients experienced greater functional improvement after undergoing revision than asymptomatic patients. However, for asymptomatic patients, a CTA device provided a significant functional improvement compared to a UTA device at the final follow-up, as evidenced by the key orthopaedic complications, but for symptomatic patients, no significant differences were detected in the functional outcomes at the final follow-up. This observation may indicate the benefits of patients undergoing CTA revision before symptoms appear. However, despite the high rate of complications, symptomatic patients could obtain more functional benefits from revision than asymptomatic patients. Notably, the functional scores of asymptomatic patients after revision did not show a significant decline, and these patients continued to maintain a high functional level. The delay of revision surgery for asymptomatic patients until after symptoms appear may lead to poor functional outcomes. However, a definitive surgical approach may be tricky to determine for some patients; therefore, we advocate a comprehensive evaluation of patients.

The present review has several limitations. First, this study was retrospective in design and, therefore, susceptible to inherent inclusion and exclusion biases that cannot be adjusted. Second, the conclusions may have been influenced by the relatively small population, inappropriate control of confounding factors, and short-term follow-up. Third, when key orthopaedic complications are used as an endpoint of the study, some complications are inevitably ignored, which may have a certain impact on the judgement of the results. However, several complications included in our study have been frequently reported in previous studies. Fourth, in the baseline data, we did not mention the patient’s occupational type or other potential medical diseases, but these potential risk factors that can lead to UTA or CTA revision may play a critical role in some patients. Finally, simple utilisation of HHSs and major orthopaedic complications as study endpoints to measure patient functional outcomes and orthopaedic complications may have limitations.

Conclusions

The aim of the current review was to offer feasible descriptive evidence that a CTA device may be superior to a UTA device in terms of the revision rate and the rate of key orthopaedic complications in elderly patients with failed PFNAs who underwent UTA or CTA revision. For such patients with clear failure of PFNAs, CTA revision could be the preferred option, regardless of whether these individuals have symptoms prior to revision. The current findings may help resolve the ongoing debate over revision in such individuals.